ME-344: Incompressible fluid mechanics

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Lectures in this course (79)

Diffusion in Concentration Coordinates

Explores diffusion in concentration coordinates and boundary conditions in different systems.

Navier-Stokes Equations: Approximations and Solutions

Explores solving Navier-Stokes equations through approximations and special cases in fluid dynamics.

Separation of Variables: Spatial Problems

Explores the method of separation of variables for solving spatial problems with second-order ODEs, emphasizing the significance of boundary conditions.

Time-dependent Diffusion: Fourier Trick

Explores the Fourier Trick for time-dependent diffusion problems in a Cartesian system.

Diffusion on an Infinite Domain: Green's Approach

Covers diffusion on an infinite domain using Green's method and emphasizes finding steady-state solutions and conservation of material.

Time-dependent Diffusion: Solutions and Analysis

Explores time-dependent diffusion solutions, Green's function, eigenmodes, and dimensional analysis.

Fluid Kinematics: Velocity Fields and Flow Visualization

Explores velocity fields and flow visualization in fluid kinematics, emphasizing streamlines, path lines, and streak lines.

Incompressible Fluid Mechanics

Covers topics such as differential analysis, potential flow, 2D flows, superpositions, lift, and drag.

Streamlines and Pathlines

Explains streamlines and pathlines in fluid dynamics, highlighting their significance in analyzing fluid motion.

Potential Flow: Equipotential Lines and Streamlines

Covers potential flow around 2D bodies, stagnation points, lift and drag forces, and vortices.

Potential Flow: Forces on Solid Objects

Discusses forces on solid objects in potential flow, including lift and drag calculations and the analysis of flow around 2D bodies.

Control Volume and System

Explains control volume, system, mass conservation laws, and Reynolds transport theorem with practical examples and theoretical derivations.

Control Volume Approach: Mass Conservation and Physical Laws

Explores the control volume approach, emphasizing mass conservation and key physical laws.

Incompressible Fluid Mechanics

Explores incompressible fluid mechanics, focusing on potential flows and flow patterns.

Newton's 2nd Law: Understanding Linear Momentum

Explores Newton's 2nd Law applied to linear momentum and mass flow rate.

Flow Around a Cylinder

Explores the flow around a cylinder, including drag, lift, pressure distribution, and stagnation points.

Flow around a cylinder: Stagnation Points

Discusses stagnation points, pressure distribution, lift generation, and the Magnus effect around a cylinder.

Engine Thrust Analysis

Explores engine thrust analysis using Munson EX 5.15 and the first law of thermodynamics.

Incompressible Fluid Mechanics: Lift and Circulation

Explores lift generation on airfoils and the concept of circulation in incompressible fluid mechanics.

Heat Transfer Fundamentals

Covers the fundamentals of heat transfer, including conduction, convection, and radiation.

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