COURSE OBJECTIVES
The successful completion of this course (Theory + Practical) would help students in achieving the following objectives:
• To help understanding the nature of fluid statics, in particular dealing with problems related to hydrostatic forces.
• To be able to analyze the problems related to elementary fluid dynamics especially for incompressible flows using Bernoulli equation in particular.
• To learn the basic models for Inviscid and viscous fluid flow using control volume and differential analysis approaches.
• To develop the understanding by applying mathematical models to simple realizable configurations along with practical considerations.
• To apprehend the applications/solutions of models developed in the advanced course in industrial applications using analytical as well as numerical methods.
COURSE LEARNING OUTCOMES (CLO)
CLO-1: Apply the basic models for inviscid and viscous fluid flow using control volume and differential analysis approaches. (C3)
CLO-2: Develop the understanding by applying mathematical models to simple realizable configurations along with practical considerations. (C5)
CLO-3: Apply solutions of models developed in the course for industrial applications. (C3)
CLO-4: Analyze the problems related to elementary fluid dynamics especially for incompressible flows using Bernoulli equation in particular. (C4)
COURSE CONTENTS
1. Introductory Concepts – One Lecture
- Dimensions, units, fluid mass and weight,
- Compressibility, vapor pressure, viscosity, surface tension
2. Fluid Statics – Three Lectures
- Pressure, hydrostatic force on plane and curved surface
- Manometers, Plane and inclined manometers
- Buoyancy and Archimedes Principle
3. Elementary Fluid Dynamics – Six Lectures
- Stream lines
- Bernoulli’s Equation along the streamline and across the streamline
- Application of Bernoulli’s Equation
- Static, stagnation and total Pressure and pitot tube
- Hydraulic grade line and energy grade line
- Assumption of Bernoulli’s equation
4. Fluid Kinematics – Six Lectures
- Velocity field, acceleration field, control volume,
- Material Derivative
- Reynolds’s transport theorem
5. Finite Control Volume Analysis – Seven Lectures
- Conservation of Mass for a Control Volume
- Derivation and application of linear momentum equation
- Derivation and application of momentum of momentum equation
- Derivation and application of energy equation
- Comparison of equations
6. Differential Analysis of Fluid Flow – Seven Lectures
- Overview of types of motion and deformation a fluid element
- Differential form of continuity equation
- The stream function
- Deriving the equations of motion
7. Dimensional Analysis, Similitude, and Modeling – Two Lectures
- Dimensional Analysis
- Buckingham Pi Theorem