Fluid Mechanics Lesson Plan Duration: 15 weeks (from January, 2018 to April, 2018) Fluid Properties and Fluid Statics: Concept of fluid and flow
LESSON PLAN COURSE TITLE: Fluid Mechanics and Hydraulics COURSE CODE: CE227 DESCRIBE the concepts related to fluid statics, kinematics, dynamics
01 1 2 Description of fluid properties like Density, Specific weight, specific gravity, specific volume and solve simple problems
LESSON PLAN Semester-4th Subject-Fluid mechanics Branch-Mechanical Engineering Theory Name of the Faculty- Duryodhan Das Academic Session – 2019-20
23 août 2017 · Instruction Schedule I Semester: 12-06-2017 to 11-10-2017 LESSON PLANS are prepared and Mechanics of Fluids and Hydraulic Machines
LESSON PLAN SUBJECT: INTRODUCTION TO FLUID MECHANICS CODE: CE(ES)401 YEAR: 2nd SEMESTER: 4TH; CONTACT HRS PER WEEK- 2; CREDIT POINTS: 2
LESSON PLAN DEPARTMENT OF Fluid Mechanics BRANCH : CHEMICAL SEMESTER flow measurement, fluid flow through pipe lines, fluidized bed etc
BACKGROUND INFORMATION: Fluid mechanics is the study of how fluids react to forces Can you think of any examples of engineering
Lesson Plan - CE1006 - Fluid Mechanics Academic year 2015-16 (Semester commencing in June 2015) Instructional objectives
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LESSON PLAN
*Name of Faculty: Ms. Rekha Devlal
Discipline: Mechanical Engineering
Semester: 4th
Subject: Fluid Mechanics
Lesson Plan Duration: 15 weeks (from January, 2018 to April, 2018) Work Load (Lecture/Practical) per week in hours: Lecture 03, Practical 02
Week Theory Practical
Lecture Day Topic (including assignment/test) Practical Day
Topic
1st 1st Fluid Properties and Fluid Statics: Concept of fluid and flow 1st To determine the coefficient of impact for vanes.
2nd Ideal and real fluids, Continuum concept
3rd Properties of fluids, Newtonian and non-Newtonian fluids
2nd 4th Pascals law, Hydrostatic equation 2nd To determine coefficient of discharge of an orificemeter.
5th Hydrostatic forces on plane surface
6th Hydrostatic forces on curved surface
3rd 7th Stability of floating and submerged bodies 3rd To determine the coefficient of discharge of Notch (V and Rectangular types).
8th Relative equilibrium
9th Revision
4th 10th Fluid Kinematics : Eulerian and Lagrangian description of fluid flow 4th To determine the friction factor for the pipes.
11th Stream, streak and path lines
12th Types of flows, flow rate and continuity equation
5th 13th Differential equation of continuity in cylindrical and polar coordinates 5th To determine the coefficient of discharge of venturimeter.
14th Rotation, vorticity and circulation, stream function, Potential functions, flow net
15th Fluid Dynamics: Concept of system and control volume, Eulers
equation
6th 16th Class Test 6th To determine the coefficient of discharge, contraction & velocity of an orifice.
17th Bernoullis equation, venturimeter,
orifice
18th Orificemeter, mouthpieces
7th 19th Kinetic and momentum correction factors 7th To verify the Bernoullis Theorem.
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20th Impulse momentum relationship and its applications
21st Compressible fluid flow: Introduction, continuity momentum and energy equation
8th 22nd Sonic velocity, propagation of elastic waves due to compression of fluid 8th Viva-Voce
23rd Propagation of elastic waves due to disturbance in fluid
24th Stagnation properties
9th 25th Isentropic flow 9th To find critical Reynolds number for a pipe flow.
26th Effect of area variation on flow properties
27th Isentropic flow through nozzles, diffusers, injectors
10th 28th Viscous Flow: Flow regimes and Reynoldss number, Relationship
between shear stress and pressure gradient 10th To determine the meta-centric height of a floating body.
29th Uni-directional flow between stationary and moving parallel plates
30th Movement of piston in a dashpot, power absorbed in bearings
11th 31st Class Test 11th To determine the minor losses due to sudden enlargement, sudden contraction and bends.
32nd Flow through pipes: Major and minor losses in pipes, Hagen-Poiseuilli law, hydraulic gradient and total energy lines
33rd Series and parallel connection of pipes
12th 34th Branched pipes; equivalent pipe, power transmission through pipes 12th To show the velocity and pressure variation with radius in a forced vertex flow.
35th Boundary layer flow: Boundary layer concept
36th Displacement, momentum and energy thickness, von-karman momentum integral equation,laminar and turbulent boundary layer flows
13th 37th Drag on a flat plate, Boundary layer separation and control. 13th To verify the momentum equation.
38th Streamlined and bluff bodies lift and drag on a cylinder and an air foil
39th Turbulent flow: Shear stress in turbulent flow
14th 40th Prandtl mixing length hypothesis 14th Viva-Voce
41st Hydraulically smooth and rough pipes, velocity distribution in pipes
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42nd Friction coefficients for smooth pipes
15th 43rd Friction coefficients for rough pipes 15th
44th Revision
45th Class Test