Lectures related to Turbulence and Symmetry

Covers the numerical simulation workflow for fluid dynamics, focusing on boundary conditions and their importance for solution convergence.

Explores turbulence characteristics, simulation methods, and modeling challenges, providing guidelines for choosing and validating turbulence models.

Covers the differential approach to fluid dynamics, focusing on conservation laws and the Cauchy stress tensor.

Covers the basics of numerical flow simulation, including boundary conditions and geometry reduction.

Explores physical models for microsystems, ideal fluids, Navier-Stokes equations, incompressible fluids, Reynolds number, and molecular dynamics.

Covers the hydrodynamic and thermal aspects of internal forced convection.

Introduces turbulence and symmetry in fluid dynamics, exploring the effects of Reynolds number on flow patterns.

Explores free convection, laminar flow boundary layer equations, and heat transfer principles.

Covers the analysis of incompressible fluid flow and numerical solutions in fluid dynamics.

Covers the foundations of fluid mechanics, focusing on flow problem descriptions and solutions.

Covers the verification of equilibrium equations and compatibility in tension scenarios, ensuring uniform stress distribution.

Covers symmetries and conservation laws in fluid dynamics, emphasizing the importance of maximizing symmetries in ideal fluid systems.

Explores turbulence characteristics, modeling challenges, and various numerical simulation methods.

Explores numerical flow simulation with moving boundaries and solver selection in Fluent.

Explores using symmetries in Finite Element models to simplify boundary conditions and reduce rigid-body motions.

Covers fluid kinematics, focusing on streamlines, pathlines, and streaklines in fluid flow visualization.

Covers a simplified numerical simulation study of a solid-oxide fuel cell.

Explores the application of Stokes equations to low Reynolds number flow and the dynamics of fluid flow.

Explores equations and solutions for viscous flow, including stress-deformation relationships, Navier-Stokes equations, and simple fluid flow cases.

Explores symmetry and boundary conditions in finite element models, emphasizing the importance of maintaining symmetry for accurate modeling.