Course

ME-280: Fluid mechanics (for GM)

Lectures in this course (23)

Hydrostatics: Understanding Fluid Behavior at Rest

Covers hydrostatics, focusing on fluids at rest and the behavior of pressure within them.

Covers deriving fluid dynamics equations, including mass conservation and stress-strain relationships, through differential analysis and key mathematical concepts.

Fluid Dynamics: Principles and Applications

Provides an overview of fluid dynamics principles, focusing on pressure differences and hydrostatic equilibrium in various fluid systems.

Inviscid Flows: Understanding Fluid Dynamics

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

2D Potential Flows

Explores 2D potential flows in fluid dynamics, focusing on stream function and velocity potential relationships and visualization techniques.

Fluid Mechanics: 2D Potential Flow Analysis

Covers 2D potential flows, lift, drag, and motivation in Fluid Mechanics.

Potential Flows: Basics and Applications

Introduces potential flows, stagnation points, superposition techniques, and flow around a cylinder.

Fluid Mechanics: Fundamentals and Applications

Introduces the fundamentals of fluid mechanics and its practical applications in engineering and physical phenomena.

Understanding Viscosity: Newtonian Fluids

Explores viscosity in Newtonian fluids, discussing shear stress, shear strain rate, and compressibility, with examples of shear thickening and shear thinning behaviors.

Pressure Distribution in Fluids

Explores pressure distribution in fluids, emphasizing assumptions' role in simplifying equations.

Hydrostatics and Archimedes Principle

Explores hydrostatics, Archimedes principle, streamlines, and Newton's second law in fluid dynamics.

Real-World Fluid Mechanics Analysis

Explores applying Bernoulli's equation to real-world fluid mechanics problems, including speed sensors on aircraft and measuring flow rates in pipes.

Fluid Dynamics: Bernoulli Equation

Explores the Bernoulli equation in fluid dynamics, emphasizing assumptions and practical applications in solving fluid mechanics problems.

Diffusion: Macroscopic View

Explores diffusion from a macroscopic perspective, emphasizing the derivation of the diffusion equation through mass conservation and fixed flux law.

Diffusion Equations in Spherical Coordinates

Explores solving diffusion equations in steady state conditions for concentric spheres with fixed concentration and flux, emphasizing the importance of linearity and homogeneity.

Feedback and Fluid Flows

Covers student feedback, infrastructure challenges, course organization, and fluid flow concepts.

Fluid Kinematics: Velocity Field Distinctions

Explores the distinction between Eulerian and Lagrangian descriptions of fluid flow through velocity field concepts and different types of lines visualization.

Fluid Flows: Description and Laws

Explores fluid flow description, field lines, acceleration, and fundamental laws reformulation for control volumes in fluid mechanics.

Fluid Mechanics: Control Volume Approach

Introduces powerful tools for analyzing fluid mechanics problems, emphasizing mass conservation, Newton's second law, and the continuity equation.

Fluid Dynamics: Control Volume Approach

Explores the control volume approach in fluid dynamics, emphasizing mass conservation and Newton's second law for practical flow analysis.