Lectures related to Fluid Flows: Description and Laws

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 Mechanics: Bernoulli's Equation and Applications

Discusses Bernoulli's equation and its applications in fluid mechanics, including practical examples like pitot tubes and venturi meters.

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.

Conservation Laws and Bernoulli Equation

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

Fluid Mechanics: Control Volume Approach and Applications

Discusses the control volume approach in fluid mechanics, focusing on mass and momentum conservation principles and their applications in real-world scenarios like jet engine thrust.

Fluid Dynamics: Control Volume and Reynolds Transport Theorem

Covers control volume and system concepts in fluid dynamics, focusing on the Reynolds transport theorem.

Fluid Mechanics: Control Volume Approach

Covers fluid kinematics, mass conservation, momentum, and energy using Laplacian and Eulerian systems.

Fluid Dynamics: Differential Conservation Laws and Equations

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

Fluid Mechanics: Control Volume Approach and Energy Conservation

Discusses the control volume approach in fluid mechanics, focusing on conservation laws and their applications.

Fluid Mechanics: Concepts and Applications

Covers key concepts in fluid mechanics, historical experiments, forces, pressure variation, and practical applications like hydraulic lifts.

Fluid Dynamics: Newton's Second Law and Momentum Conservation

Discusses Newton's Second Law in fluid dynamics, focusing on momentum conservation and its applications in engineering problems.

Fluid Dynamics: Eulerian and Lagrangian Approaches

Covers the Eulerian and Lagrangian approaches in fluid dynamics, emphasizing their applications in analyzing fluid flow.

Geometric Locus and Mechanics

Covers geometric locus, cone sections, Kepler's problem, Newton's laws, and conservation laws.

Fluid Kinematics and Control Volume Analysis

Discusses fluid kinematics and the control volume approach using the Reynolds Transport Theorem.

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

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

Introduction to Fluid Mechanics

Covers the basics of fluid mechanics, including fluid properties, pressure, viscosity, and fluid behavior at rest and in motion.

Introduction to Fluid Mechanics: Basic Principles and Properties

Introduces fluid mechanics, covering definitions, fundamental laws, and properties of fluids.

Energy Conservation: The First Law of Thermodynamics

Covers the first law of thermodynamics, focusing on energy conservation and its implications in fluid dynamics.

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.

Turbulent Caminar Visualization

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