This PDF covers
the following topics related to Advanced Fluid Mechanics : Introduction: Survey
of Fluid Mechanics, Structure of Fluid Mechanics Based on Rheological, Temporal
Variation, Fluid Type, Motion Characteristic and spatial Dimensionality
Consideration, Approaches in Solving Fluid Flow Problems, Fundamental
idealizations and Descriptions of Fluid Motion, Quantitative Definition of Fluid
and Flow, Reynolds Transport Theorem, Mass, Momentum and Energy Conservation
Principles for Fluid Flow. Potential Flow: Frictionless Irrotational Motions, 2
- Dimensional Stream Function and Velocity Potential Function in Cartesian and
Cylindrical Polar Coordinate Systems, Standard Patterns of Flow, Source, Sink,
Uniform Flow and irrotational vortex, Combinations of Flow Patterns, method of
Images in Solving Groundwater Flow problems, Method of Conformal
transformations.
Author(s): Dr. Prakash Chandra Swain, Professor in Civil
Engineering, Veer Surendra Sai University of Technology, Burla
This note introduce Quantum Mechanics at an advanced level addressing
students of Physics, Mathematics, Chemistry and Electrical Engineering. Topics
covered includes: Lagrangian Mechanics, Quantum Mechanical Path Integral, The
Schrodinger Equation, Linear Harmonic Oscillator, Theory of Angular Momentum and
Spin, Quantum Mechanical Addition of Angular Momenta and Spin, Motion in
Spherically Symmetric Potentials, Interaction of Charged Particles with
Electromagnetic Radiation, Many–Particle Systems, Relativistic Quantum
Mechanics, Spinor Formulation of Relativistic Quantum Mechanics, Symmetries in
Physics.
This note explains the following topics: Properties Of Fluids
And Fluid Statics, Fluid Kinematics, Fluid Dynamics, Boundary Layer Theory,
Closed Conduit Flow.
This note explains the following topics: Fundamentals of Fluid
Mechanics, Viscosity, Newtonian Fluids, Non-Newtonian Fluids, Flow Analysis
Techniques, Fluid Statics, Differential Analysis Of Fluid Motion.
This
note explains the following topics: Fluid Statics, Kinematics of Fluid,
Conservation Equations and Analysis of Finite Control Volume, Equations of
Motion and Mechanical Energy, Principles of Physical Similarity and Dimensional
Analysis, Flow of Ideal Fluids Viscous Incompressible Flows, Laminar Boundary
Layers, Turbulent Flow, Applications of Viscous Flows through Pipes and
Compressible Flow.
This note covers the following topics:
Differences between fluid and solid, Differences between gas and liquid, Types
of fluids, Physical properties, Fluid statics, Pressure Measurement, Buoyancy -
principles, Units and Dimensions, Similitude and model studies, Fluid flow,
Boundary layer, Flow of incompressible fluid in pipes, Compressible fluid flow,
Closed channel flow measurement, Flow past immersed bodies, Packed Towers,
Fluidization, Transportation of fluids, Rotary pumps, Airlift pump, Jet pump,
Selection of pumps, Fans, blowers, and compressors.
This note will be useful
for students wishing to gain an overview of the vast field of fluid dynamics.
Topics covered includes: The continuum hypothesis, kinematics, conservation
laws: continuity equation, Euler and Navier-Stokes equation, Dimensionless
numbers, dynamic similarity, aerodynamics, Compressible flows, speed of sound,
shocks, Fluid instabilities and turbulence, Applications of fluid dynamics in
Astrophysics.
First few lectures will review the fundamentals of fluid
mechanics, while subsequent lectures will focus on its applications in chemical
engineering. Topics covered includes: microscopic and macroscopic balances,
Navier-Stokes' equations, Introduction to turbulence, concept of boundary layer,
friction factor, pipe flow, pressure loss in fittings, flow past an immersed
body, packed and fluidized beds, pump and compressors.
The objective of
the course note is to provide a survey of a wide variety of topics in fluid
mechanics, including a rigorous derivation of the compressible Navier-Stokes
equations, vorticity dynamics, compressible flow, potential flow, and viscous
laminar flow.
A complete set of lecture notes
for an upper-division undergraduate Fluid Mechanics course. The course
concentrates on those aspects of fluid mechanics that can be studied
analytically. Topics covered include hydrodynamics, surface tension, boundary
layers, potential flow, aerodynamics, viscous flow, and waves.
This note covers the
following topics: Kinematics, Flow Visualization, Material Derivative, Stream
Functions, Dynamics, Applications Of Momentum Integral, Vorticity, Irrotational
Flows, Applications Of Irrotational and Time dependent Bernoulli, Kinetic
Energy, Vortex Motion, Flows With a Free Surface.