Fluid Mechanics: From Basics To Advanced

Learn Fluid Mechanics: Fundamental Laws, Differential Equations, Streamline Flow, and Advanced Aerodynamic Concepts

What you'll learn

Fundamental Principles of Fluid Mechanics:Understand and apply the basic physical laws governing fluid mechanics.

Analyze fluid flow using differential equations and control volume approaches.

Flow Characteristics and Analysis: Investigate incompressible viscous fluids and solve related problems.

Examine streamline flow, angular velocity, vorticity, and related concepts.

Advanced Fluid Flow Concepts: Explore potential flow solutions and elementary flows and understand the boundary layer equations and their applications.

Aerodynamics and Applied Fluid Mechanics: Study the Laplace and Kutta conditions, thin airfoil theory, and induced drag.

Learn Prandtl's Classical Lifting Line Theory and elliptical lift distribution.

Requirements

Basic Mathematics and Physics Knowledge: Proficiency in algebra, calculus, and general physics concepts.

Analytical Skills: Ability to analyze and solve complex problems.

Tools and Equipment: Access to a computer with internet connectivity and basic scientific calculator.

Description

Unlock the secrets of fluid mechanics with our comprehensive course designed for engineering students, professionals, and enthusiasts alike. Whether you’re a beginner or looking to deepen your understanding, this course covers everything from fundamental principles to advanced concepts, equipping you with the skills needed to excel in your field.What you'll learn:Fundamental Principles of Fluid Mechanics: Grasp the basic physical laws and analyze fluid flow using differential equations and control volume methods.Flow Characteristics and Analysis: Explore incompressible viscous fluids, streamline flow, angular velocity, and vorticity.Advanced Fluid Flow Concepts: Delve into potential flow solutions, boundary layer equations, and elementary flows.Aerodynamics and Applied Fluid Mechanics: Understand the Laplace and Kutta conditions, thin airfoil theory, induced drag, and Prandtl's Classical Lifting Line Theory.Course Content:Section 1: IntroductionSection 2: Basic Physical Laws of Fluid MechanicsSection 3: Differential Relations for Fluid FlowSection 4: Differential Equations for Control VolumeSection 5: Incompressible Viscous FluidsSection 6: Streamline FlowSection 7: Elementary FlowsSection 8: Viscous FlowSection 9: Boundary Layer EquationsSection 10: Laplace and Kutta ConditionsSection 11: Thin Airfoil TheorySection 12: Drag and Biot-Savart's LawsSection 13: Prandtl's Classical Lifting Line TheorySection 14: Elliptical Lift DistributionRequirements:Basic knowledge of mathematics and physicsAnalytical skills for problem-solvingAccess to a computer with internet connectivity and a scientific calculatorWho this course is for:Engineering students and professionals in mechanical, aerospace, civil, or chemical fieldsScience enthusiasts eager to understand fluid mechanicsIndustry practitioners working with fluid dynamics, aerodynamics, and hydrodynamicsLifelong learners passionate about the behavior of fluids in various applicationsJoin us on this journey through the fascinating world of fluid mechanics and enhance your expertise with practical insights and in-depth knowledge. Enroll now to master fluid mechanics from basics to advanced!

Overview

Section 1: Introduction

Lecture 1 Introduction

Section 2: Basic Physical Laws of Fluid Mechanics

Lecture 2 Basic Physical Laws of Fluid Mechanics

Lecture 3 Basic Physical Laws of Fluid Mechanics Part 2

Lecture 4 Basic Physical Laws of Fluid Mechanics Part 3

Section 3: Differential Relations for Fluid Flow

Lecture 5 Differential Relations for Fluid Flow

Section 4: Differential Equations for Control Volume

Lecture 6 Differential Equations for Control Volume

Lecture 7 Differential Equations for Control Volume Part 2

Section 5: Incompressible Viscous Fluids

Lecture 8 Incompressible Viscous Fluids

Lecture 9 Incompressible Viscous Fluids Examples

Lecture 10 Incompressible Viscous Fluids Part 3

Lecture 11 Incompressible Viscous Fluids Part 4

Section 6: Streamline Flow

Lecture 12 Streamline, Angular Velocity, Vorticity

Lecture 13 Strain and Circulation

Lecture 14 Stream Functions

Lecture 15 Velocity Potential

Lecture 16 The Vortex Sheet

Lecture 17 Superposition Of Plane Flow Solutions

Lecture 18 Solving a Potential Flow

Section 7: Elementary Flows

Lecture 19 Elementary Flows

Lecture 20 Elementary Flows Part 2

Lecture 21 Elementary Flows Part 3

Section 8: Viscous Flow

Lecture 22 Viscous Flow

Lecture 23 Viscous Flow Part 2

Section 9: Boundary Layer Equation

Lecture 24 Boundary Layer Equations

Lecture 25 Boundary Layer Equations

Lecture 26 Flat Layer Boundary Layer

Lecture 27 Application Of Flat Layer Boundary Layer

Section 10: Laplace condition and Kutta condition

Lecture 28 Laplace Equation

Lecture 29 The Kutta Condition

Lecture 30 Kelvin's Circulation Theorem

Section 11: Thin Airfoil Theory

Lecture 31 Thin Airfoil Theory

Lecture 32 Thin Airfoil Theory (Symmetric Airfoil)

Lecture 33 Thin Airfoil Theory (Cambered Airfoil)

Section 12: Drag and Biot-Savart's Laws

Lecture 34 Downwash and Induced Drag

Lecture 35 Biot-Savart's Laws

Section 13: Prandtl's Classical Lifting Line Theory

Lecture 36 Prandtl's Classical Lifting Line Theory

Lecture 37 Prandtl's Classical Lifting Line Theory Part 2

Section 14: Elliptical Lift Distribution

Lecture 38 Elliptical Lift Distrubution

Engineering Students and Professionals: Ideal for those studying mechanical, aerospace, civil, or chemical engineering.,Science Enthusiasts: Suitable for individuals interested in gaining a deep understanding of fluid mechanics.,Industry Practitioners: Beneficial for professionals working in fields related to fluid dynamics, aerodynamics, and hydrodynamics.,Lifelong Learners: Great for anyone with a passion for learning about the behavior of fluids in various applications.