Introduction to Fluid Mechanics
Introduction to Fluid Mechanics
Duration: 1h 59m | .MP4 1280x720, 30 fps(r) | AAC, 44100 Hz, 2ch | 734 MB
Genre: eLearning | Language: English
Duration: 1h 59m | .MP4 1280x720, 30 fps(r) | AAC, 44100 Hz, 2ch | 734 MB
Genre: eLearning | Language: English
Fluid Statics, Kinematics, and Dynamics
What you'll learn
Properties of Fluids, Types of Fluid Flows, Turbulent Boundary Layer, Displacement Momentum Energy Thickness, Pressure Drag and Friction Drag, etc.
Requirements
Engineering Mathematics-I, Engineering Mathematics-II, Engineering Mechanics, Engineering Physics
Description
In this course students learner will be able to determine various properties of fluid viz., Definition of fluid, concept of continuum, density, specific weight, specific gravity, viscosity, viscosity laws, types of fluid and rheology, measurement of viscosity, application based numerical on viscosity-flow through pipe, lubrication, bearing, brake fluids, parallel plates, rotating shafts etc., vapor pressure surface tension, capillarity, compressibility apply the laws of fluid statics and concepts of buoyancy, identify types of fluid flow and terms associated in fluid kinematics, apply principles of fluid dynamics to laminar flow, estimate friction and minor losses in internal flows and determine boundary layer formation over an external surface, construct mathematical correlation considering dimensionless parameters, also able to predict the performance of prototype using model laws, Boundary layer formation over a flat plate, boundary layer thickness, displacement thickness, momentum thickness and energy thickness, boundary layer separation and methods to control separation, drag and lift concepts, types of drag, drag & lift coefficient, aerofoil, bluff body, streamline body, Losses - major & minor losses, hydro dynamically smooth and rough boundaries, Moody’s chart, compounding of pipes & equivalent pipe, siphons, transmission of power, Euler’s equation of motion differential form and Navier Stokes equation, Euler’s equation of motion along streamline, Bernoulli’s theorem and modified Bernoulli’s theorem, stagnation pressure, HGL, TEL, Flow description methods, types of flows, velocity and acceleration fields, continuity equation in 1D & 3D flow, flow visualization (path line, stream line and streak line), stream tube, angularity, vorticity, stream function and velocity potential function, flow net
Who this course is for:
Mechanical and Civil Engineering students
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