Lectures related to Viscous flow: Equations and Solutions

Turbulence: Numerical Flow Simulation

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

Inviscid Flows: Understanding Fluid Dynamics

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

Fluid Dynamics: Ideal Fluids

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

Fluid Mechanics: Foundations and Applications

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

Introduction to Free Convection: Governing Equations

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

Fluid Dynamics: Differential Conservation Laws and Equations

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

Internal Forced Convection: Hydrodynamic Aspects

Covers the hydrodynamic and thermal aspects of internal forced convection.

Fluid Mechanics in Biomechanics

Introduces fluid mechanics in biomechanics, covering Eulerian description, momentum conservation, Navier-Stokes equations, and practical simulations.

Viscous Flow in Newtonian Fluids

Explores viscous flow in Newtonian fluids, focusing on no-slip conditions and laminar shear flow equations.

Newton's 2nd Law: Fluid Dynamics

Discusses Newton's 2nd Law in fluid dynamics and incompressible Newtonian fluids.

Fluid Dynamics: Navier-Stokes Equations

Explores fluid dynamics, covering Navier-Stokes equations, momentum conservation, stresses, and dimensional analysis.

Numerical Flow Simulation: Boundary Conditions

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

Incompressible Fluid Mechanics: Differential Analysis

Covers mass and momentum conservation, Navier-Stokes equations, and analytical methods in incompressible fluid mechanics.

Laminar Flow: Shear between Parallel Plates

Explores laminar shear flow between parallel plates for incompressible fluids.

Numerical Methods in Biomechanics: Hip-A

Explores numerical methods in biomechanics for hip implants and emphasizes understanding conditions for improved designs and patient outcomes.

Fluids and Electromagnetism

Explores fluid flow, Bernoulli's theorem violation, viscosity, and necessary force for rotating cylinders with different fluids.

Continuum Mechanics: Forces and Deformation

Covers the basics of continuum mechanics, including forces transmission, energy conservation, and body motion geometry.

Stokes Equations: Low Reynolds Number Flow

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

Fluid Dynamics: Incompressible Flow

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

Velocity Boundary Layer Equations

Focuses on velocity boundary layer equations in laminar flow and covers mass and momentum conservation, Navier-Stokes equations, and the Reynolds number.