Fundamentals of Fluid Mechanics

Description

Welcome to our all-encompassing Fluid Mechanics course. In the modern world, understanding the behavior of fluids isn't just academic – it's essential. Fluid Mechanics stands as the backbone of many engineering advancements and solutions that shape our contemporary life, from sustainable water management and advanced transportation systems to energy-efficient designs and beyond. Engineers equipped with this knowledge aren't just advancing their careers; they're crafting the future. With our blend of theoretical insights and practical perspectives, you'll not only grasp the essentials but also appreciate the profound impact of Fluid Mechanics on our world.

Through a combination of theoretical concepts, practical examples, and hands-on exercises, you'll learn about the fundamental principles of fluid mechanics. Beyond the core principles, our course is enriched with numerical challenges, practice problems, and real-world fluid mechanics engineering applications. You'll delve into the myriad applications of fluid mechanics.

Reference books for this course:

1. Fluid Mechanics by Yunus A. Cengel, John M. Cimbala

2. Fundamentals of Fluid Mechanics, 6th Edition By Munson

COURSE OUTLINE

Section 1: Introduction to Fluid Mechanics

• Introduction to Fluid Mechanics

• Application Area of Fluid Mechanics

• Dimensions and Importance of Dimensions and Units

• Dimensional Homogeneity and Unity with example problems

• Calculation of Dimensional Analysis

• Dimensionless Numbers (Reynolds, Bingham & Nusselt Number)

• Measures of Fluid Mass and Weight (Density, Specific Weight, Specific Gravity) and the Relation between Density and Specific Weight

• Classification of Fluid Flow (Internal and External, Compressible and Incompressible, Laminar and Turbulent, Steady and Unsteady)

• Calculation of Reynold, Bingham & Nusselt numbers (Dimensionless Numbers)

Section 2: Nature of Fluids and Viscosity

• Nature of Fluids (The no Slip Condition in Fluid Dynamics)

• Shear Stress in Moving Fluid, (Derivation Shear stress is directly proportional to strain rate)

• Viscosity and Fluid Types (Newtonian and Non-Newtonian Fluid)

• Shear Thickening Fluids and Shear Thinning Fluid

• Numericals Related to Newton's Law of Viscosity (Newtonian Fluid)

• Calculation of Shear Stresses

• Velocity Profiles

Section 3: Pressure and Buoyancy

• Pressure (Fluid Pressure and Hydrostatic Pressure)

• Calculation of Specific Gravity

• Manometry (Piezometer, U tube manometer, Differential Monometer)

• Questions related to Monometer for pressure calculation

• Buoyancy and Steps for Solving Buoyancy Questions

• Numerical related to Buoyancy

Section 4: Fluid Flow Rates and Bernoulli's Equation

• Fluid Flow Rates

• Continuity Equation

• Calculation of Fluid Flow Rate using Continuity Equation

• Commercially Available Pipe and Tubing (Steel Pipe, Steel Tubing, Copper Tubing, Ductile Iron Pipe)

• Pipe Selection Aid

• Question Calculation of Volume Flow Rate by Pipes and Tubes Table

• Determine Pipe Size and Tube Size from Tables

• Conservation of Energy (Bernoulli’s Equation),

• Derivation of Bernoulli’s Equation

• Interpretation of Bernoulli’s Equation

• Restriction on Bernoulli’s Equation

• Numerical related to Bernoulli’s Equation

• Problem related to the calculation of volumetric flow rate through the nozzle using Bernoulli’s Equation

• Application of Bernoulli’s Equation (Tanks, Reservoirs, and Nozzles Exposed to the Atmosphere)

• Calculation of volumetric flow rate in Venturi Meter

• Torricelli’s Theorem

• Questions related to Torricelli’s Theorem

Section 5: General Energy Equation and Pump Efficiency

• General Energy Equation (Pumps, Fluid Motors, Fluid Friction, Valves, and Fittings)

• Mechanical Energy and Efficiency

• Nomenclature of Energy Losses and Addition

• Questions Related to Energy Equation

• Power Required by the Pumps

• Mechanical Efficiency of Pumps

• Numerical related to Pumps

• Calculation of Mechanical Efficiency of the Pump

• Power Delivered to Fluid Systems

• Mechanical Efficiency of Fluid

• Calculation of Power Delivered to Fluid and its Mechanical Efficiency

Section 6: Reynolds Number and Friction Loss

• Critical Reynolds Number

• Reynolds Number for closed non-circular cross-sections

• Hydraulic Radius for non-circular pipes

• Solving Problems using Moody’s Chart

• Calculation of Reynolds Number for non-circular pipes

• Friction Loss in non-circular cross-section

• Calculation of Friction loss using Moody’s Chart

• Energy Loss due to Friction

• Darcy’s Equation

• Friction Loss in Laminar and Turbulent Flow

Section 7:  Energy Losses

• Minor Losses

• Sudden Enlargement and losses due to Sudden Enlargements,

• Calculation of energy loss due to sudden enlargement

• Exit loss and calculation of energy loss due to exit loss

• Gradual Enlargement and calculation of energy loss due to gradual enlargement

• Sudden Contraction and calculation of energy loss due to sudden contraction

• Entrance Loss and calculation of energy loss due to Entrance

• Minor Losses (through Valves and Fittings) with procedure for calculation

• Resistant Coefficient for Valves & Fittings

• Calculation of all the energy loses in moving fluid

Section 8: Flow Measurement

• Flow Measurement

• Flow meters selection factors

• Variable head meters, Venturi, Flow Nozzle, Orifice

• Variable Area Flow Meters

• Rotameter

• Flow Rate and Velocity Measurements

• Velocity Probes

• Open Channel Flow Measurement (Weirs, Rectangle Notch, Contracted Weir, Triangle Weir)

Section 9:  Pumps and Cavitation

• Positive Displacement Pumps

• Reciprocating Pumps

• Rotary Pump

• Kinetic Pump

• Self-Priming Pump

• Centrifugal Pump

• Affinity Law for centrifugal pumps

• Numerical using Affinity Law

• Manufacturer's data for centrifugal pumps

• Effect of Impeller Size

• Power and Efficiency of Pumps

• Cavitation

• Vapor Pressure

• NPSH Margin

Join our Fluid Mechanics course and commence a profound exploration into the essentials of fluid mechanics.

What You Will Learn!

• Understanding the application areas of fluid mechanics, including aerodynamics, hydrodynamics, and industrial fluid flow systems.
• Learning the fundamental principles of dimensional analysis, including units and dimensions, dimensional homogeneity, and dimensional analysis.
• Understanding the nature of fluids, including the no-slip condition, shear stress, and viscosity, as well as the different types of fluids.
• Learning how to calculate shear stresses and velocity profiles, and understanding the behavior of shear thickening and shear thinning fluids.
• Understanding the concept of pressure and hydrostatic pressure, and learning how to calculate specific gravity.
• Learning how to use different types of manometers, such as the piezometer and U-tube manometer, to measure pressure and calculate buoyancy.
• Understanding the concept of fluid flow rates, including continuity equation, commercial pipe and tubing, and pipe selection.
• Learning how to apply the principles of Bernoulli's equation to calculate volumetric flow rates in different applications,such as tanks, reservoirs and venturi.
• Understanding the general energy equation and its applications to pumps, fluid motors, and valves and fittings.
• Learning how to calculate the mechanical efficiency of pumps and the power delivered to fluid systems, and understanding the various types of energy losses.
• Understanding the concept of Reynolds number and its applications to laminar and turbulent flow, as well as the hydraulic radius for non-circular pipes.
• Learning how to use Moody's chart to calculate friction loss, Darcy's equation, and the effect of friction loss on energy loss.
• Understanding the concept of minor losses and their impact on fluid flow, as well as calculating energy losses due to enlargements and contractions.
• Learning how to calculate all energy losses in moving fluid, including losses through valves and fittings, and understanding the resistant coefficient.
• Understanding the different types of flow meters, including variable head meters, variable area flow meters, and velocity probes, and their selection factors.
• Learning how to measure flow rate and velocity in open channel flow, including weirs, rectangle notches, contracted weirs, and triangle weirs.
• Understanding the different types of positive displacement pumps, including reciprocating, rotary, kinetic, self-priming, and centrifugal pumps.
• Learning about cavitation and vapor pressure, and understanding the importance of NPSH margin and impeller size in pump performance.

Who Should Attend!

• Engineering students who are studying mechanical, civil, chemical, or aerospace engineering and need to learn about fluid mechanics as part of their curriculum.
• Professionals who work in industries such as oil and gas, chemical processing, manufacturing, or transportation and need to understand the principles of fluid mechanics to improve their job performance.
• Individuals who are interested in pursuing a career in fluid mechanics or related fields and want to develop their foundational knowledge.
• Hobbyists and enthusiasts who are interested in understanding the science of fluids, such as those who enjoy building model boats, airplanes, or engines.
• Educators and researchers who want to refresh their understanding of fluid mechanics or use the course material as a teaching resource.

TAKE THIS COURSE