Lectures related to Incompressible Fluid Mechanics

Turbulence: Numerical Flow Simulation

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

Boundary Layer Concepts

Explores boundary layer concepts, viscosity impact, drag and lift forces, and dimensional pipe flow analysis.

Introduction to Free Convection: Governing Equations

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

Instability: optimal perturbations and lift-up mechanisms

Explores the instability of various flow types and lift-up mechanisms in boundary layers.

Laminar and Turbulent Flow

Covers laminar and turbulent flow, pressure losses, Reynolds number, Poiseuille flow, and friction in piping networks.

Conservation Laws and Bernoulli Equation

Covers conservation laws in fluid dynamics, including the Venturi effect and Bernoulli equation.

Internal Forced Convection: Hydrodynamic Aspects

Covers the hydrodynamic and thermal aspects of internal forced convection.

Pressure Drop in Closed-Flow Systems

Explores pressure drop in closed-flow systems, including minor losses and exercises on fluid transfer and pump power.

Boundary Layers: Recap and Effects on Drag and Lift

Covers the importance of boundary layers, viscosity effects on drag and lift.

Fluid Dynamics Basics: Turbomachinery Applications

Provides an overview of fluid dynamics principles crucial for turbomachinery design and analysis.

Turbulence Modeling

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

Turbulence Concepts: Reynolds Decomposition and Closure Problem

Explores Reynolds decomposition, closure problem, and turbulence modeling challenges.

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Continuity Equation, Newton's 2nd Law in Eulerian Concept

Covers the continuity equation for steady laminar flow and Newton's 2nd law.

Free Convection Correlations

Covers the fundamentals of free convection and correlations for heat transfer between a solid and a fluid in motion at different temperatures.

Turbulence: Numerical Flow Simulation

Explores the challenges of turbulence, simple turbulent flows, and numerical simulation methods.

Introduction to Hydrodynamics

Covers fundamental hydrodynamics concepts, including two-phase flows, geophysics, swimming propulsion, irrigation, flow models, types of flows, instabilities, turbulence, and computational tools.

Viscous Fluid Dynamics: Reynolds Number and Flow Characteristics

Explores the impact of Reynolds number on fluid flow characteristics and similitude in experimental setups.

Rheology of Suspensions and Emulsions

Explores the rheology of suspensions, emulsions, and complex fluids, including non-Newtonian flows and viscometric flows.

Fluid Oscillators & Amplifiers

Explores fluid oscillators and amplifiers, covering nonlinear dynamics, frequency corrections, Reynolds stresses, and bifurcation theory.