System

• Control Mass (Closed System)
• Control Volume (Open System)
• Isolated System

 Conservation of Mass

• Continuity Equation - Differential Form
• Continuity Equation - Vector Form
• Continuity Equation in a Cylindrical Polar Coordinate System
• Strain Rate Components
• Continuity Equation from a Closed System Approach
• Continuity Equation in a Cylindrical Polar Coordinate System
• Continuity Equation: Integral Form

Lecture 10

 Stream Function

• Physical Significance of Stream Function ψ
• Stream Function in Three Dimensional and Compressible Flow

 Conservation of Momentum

• Reynolds Transport Theorem
• Application of the Reynolds Transport Theorem to Conservation of Mass and Momentum
• Angular Momentum

Lecture 11

 Analysis of Finite Control Volumes

• Inertial and Non-Inertial Control Volumes
• Forces due to Flow Through Expanding or Reducing Pipe Bends
• Dynamic Forces on Plane Surfaces due to the Impingement of Liquid Jets
• Force on a moving surface
• Dynamic Forces on Curve Surfaces due to the Impingement of Liquid Jets
• Propulsion of a Ship
• Jet Engine
• Non-inertial Control Volume-Rocket Engine

Lecture 12

 Application of Moment or Momentum Theorem

• Application of Moment or Momentum Theorem
• Euler’s Equation: The Equation Of Motion For An Ideal Flow

 Euler's Equation

• Derivation
• Euler's Equation along a Streamline
• Euler's Equation in Different Conventional Coordinate System
• A Control Volume Approach for the Derivation of Euler’s Equation

Lecture 13

 Conservation Of Energy

• Potential, Kinetic and Intermolecular energy
• Flow Work
• Bernoulli's Equation
• Bernoulli's Equation with Head Loss