Lecture

The Finite Volume Method

Related lectures (25)

Covers the Finite Volume Method for numerical flow simulation, including conservation equations, discretization methods, and boundary conditions.

Turbulence: Numerical Flow Simulation

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

Introduction to Free Convection: Governing Equations

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

Inviscid Flows: Understanding Fluid Dynamics

Explores inviscid flows, Reynolds number importance, linear deformations, and volume change in fluid dynamics.

Fluid Dynamics: Equations and State

Explores fluid dynamics concepts like energy argument, momentum balance, and equation of state for perfect fluids.

Linear Momentum Conservation and Stress in Continuum

Explores the conservation of linear momentum and stress in a continuum, focusing on governing equations and constitutive laws.

Turbulent Caminar Visualization

Explores turbulent caminar visualization, current lines, and the significance of turbulence in classical physics and research.

The Finite Volume Method in 2D/3D

Introduces the finite volume method, conservation equations, and numerical flow simulation for steady diffusion in 2D/3D.

Navier-Stokes Equations: Numerical Flow Simulation

Explores challenges and solutions in numerical flow simulation, emphasizing the importance of physical consistency in computational fluid dynamics.

Conservation Equations in Fluid Dynamics

Covers the derivation of conservation equations in fluid dynamics and their practical applications in engineering problems.

Symmetries and Conservation Laws

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

Understanding Turbulence

By the instructor Tobias Schneider explores the fundamental aspects of turbulence and its significance in various scientific disciplines.

Fluid Dynamics: Ideal Fluids

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

Fundamental Equations: Conservation and Thermodynamics

Covers mass, momentum, energy conservation, and thermodynamics in fluid dynamics.

Numerical Flow Simulation: Fundamentals

Covers the fundamentals of numerical flow simulation, emphasizing the importance of understanding the methodology and practicing simulation techniques to run full simulations autonomously.

Turbulence Modeling

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

Mass Conservation: Lapazian Laws

Covers the principles of mass conservation and Lapazian laws in fluid dynamics.

Numerical Analysis of Incompressible Fluid Flow

Covers the software system Channelflow for numerical analysis of incompressible fluid flow in channel geometries, including spectral methods and invariant solutions.

Fluid Dynamics: Differential Conservation Laws and Equations

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

Magnetic Flux Freezing

Explains magnetic flux freezing and the transition to a 1-fluid model in plasma dynamics.