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Fluid Mechanics: Topic 1.1 - Definition of a fluid

Fluid Mechanics: Topic 1.2 - Pressure

Fluid Mechanics: Topic 1.3 - Absolute pressure and gage pressure

Fluid Mechanics: Topic 1.4 - Density

Fluid Mechanics: Topic 1.5 - Viscosity

Fluid Mechanics: Topic 1.6 - Continuum approximation

Fluid Mechanics: Topic 1.7 - Vapor pressure

Fluid Mechanics: Topic 2.1 - Pascal's Law

Fluid Mechanics: Topic 2.2 - Hydrostatic pressure gradient

Fluid Mechanics: Topic 2.3 - Hydrostatic pressure distribution

Fluid Mechanics: Topic 3.1 - Introduction to manometers

Fluid Mechanics: Topic 3.2 - Barometers

Fluid Mechanics: Topic 3.3 - Piezometer tube manometers

Fluid Mechanics: Topic 3.4 - U-tube manometers

Fluid Mechanics: Topic 3.5 - Inclined tube manometers

Fluid Mechanics: Topic 4.1 - Hydrostatic force on a plane surface

Fluid Mechanics: Topic 4.2 - Center of pressure on a plane surface

Fluid Mechanics: Topic 4.3 - Hydrostatic force on a curved surface

Fluid Mechanics: Topic 5 - Buoyancy & Archimedes' principle

Fluid Mechanics: Topic 6.1 - Systems vs Control Volumes

Fluid Mechanics: Topic 6.2 - Reynolds transport theorem

Fluid Mechanics: Topic 7.1 - Conservation of mass for a control volume

Fluid Mechanics: Topic 7.2 - Conservation of linear momentum for a control volume

Fluid Mechanics: Topic 7.2.1 - Analyzing pressure forces on a CV

Fluid Mechanics: Topic 7.3 - Conservation of energy for a control volume

Fluid Mechanics: Topic 7.3.1 - Energy grade line (EGL) & Hydraulic grade line (HGL)

Fluid Mechanics: Topic 7.3.2 - The Bernoulli equation

Fluid Mechanics: Topic 7.3.3 - Definition of pump efficiency & turbine efficiency

Fluid Mechanics: Topic 8.1 - General Characteristics of laminar and turbulent flows in pipes

Fluid Mechanics: Topic 8.2 - Developing and fully-developed flow in pipes

Fluid Mechanics: Topic 8.3 - Pressure drop and head loss in pipe flow

Fluid Mechanics: Topic 8.4 - Velocity profile of fully-developed laminar flow in pipes

Fluid Mechanics: Topic 8.5 - Velocity profile for fully-developed turbulent flow in pipes

Fluid Mechanics: Topic 8.6.1 - Major losses in circular pipe systems

Fluid Mechanics: Topic 8.6.2 - The Moody chart

Fluid Mechanics: Topic 8.6.3 - Major losses in non-circular ducts

Fluid Mechanics: Topic 8.7 - Minor losses in pipe systems

Fluid Mechanics: Topic 9.1 - Categories of pipe flow problems

Fluid Mechanics: Topic 9.2 - Example of type I pipe flow problem

Fluid Mechanics: Topic 10.1 - Lagrangian vs Eulerian descriptions of flow

Fluid Mechanics: Topic 10.2 - The material derivative

Fluid Mechanics: Topic 10.3 - Steamlines, streaklines, and pathlines

Fluid Mechanics: Topic 10.4 - Kinematics of fluid elements (translation and linear deformation)

Fluid Mechanics: Topic 10.5 - Kinematics of fluid elements (shear strain, rotation, and vorticity)

Fluid Mechanics: Topic 11.1 - The continuity equation

Description:

Dive into a comprehensive 4.5-hour video lecture series on fluid mechanics from Cal Poly Pomona. Explore fundamental concepts and derivations, covering topics such as fluid properties, pressure, Pascal's Law, manometers, hydrostatic forces, buoyancy, conservation laws, pipe flow, and fluid kinematics. Learn about the Bernoulli equation, energy grade lines, pump efficiency, laminar and turbulent flows, and the Moody chart. Gain a deep understanding of fluid mechanics principles through detailed explanations and derivations of key equations and concepts.

Fluid Mechanics - Concept and Derivation

Cal Poly Pomona

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#Science #Physics #Fluid Mechanics #Viscosity #Hydrostatics #Buoyancy