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
107093_7FLUID_MECHANICS_THEORY.pdf S. K. D. A. V. GOVERNMENT POLYTECHNIC, ROURKELA-12
LESSON PLAN
Semester-4th Subject-Fluid mechanics
Branch-Mechanical Engineering Theory
Name of the Faculty- Duryodhan Das
Academic Session - 2019-20
Period
Unit/Sl.no.
Topics to be covered
1 Module-01 Properties of fluid:- Introduction of Fluid & examples of fluid
2 Fluid properties like Density, specific weight, Relationship between
Density and specific weight, specific volume ,specific gravity
3 Calculations on fluid properties
4 Viscosity, Different types of viscosity
5 Newton͛s law of ǀiscosity
6 surface tension and capillary
7 Calculations based on viscosity
8 Unit Discussion
9 Module-02 Fluid pressure and Its measurements- Introduction to fluid pressure
10 Pressure intensity and pressure head
11 Calculations based on fluid pressure and pressure head
12 Pascal͛s law, Concepts of atmospheric pressure
13 Gauge pressure, Vaccum pressure and Absolute pressure
14 Derivation of relationship between atmospheric pressure, Gauge
pressure and absolute pressure.
15 Simple and differential manometers & Bourdon tube pressure gauge
16 Calculations based on Manometers
17 OMR-1
18 Module-03 Hydrostatics- Introduction to Hydrostatic pressure with its examples
19 Total pressure on immersed bodies and vertical bodies
20 Centre of pressure on horizontal and vertical bodies
21 Calculation based on total pressure and center of pressure
22 Archimedes principle ,Concept of Buoyancy, Metacenter
23 Metacentric Height, Concept of Floatation, Calculations based on
metacentric height
24 OMR-2
25 Module-04 Kinematics of flow- Different types of fluid flows like steady and
unsteady flow, uniform and non-uniform flow
26 Compressible flow and incompressible flow, turbulent flow, Laminar
flow, rotational and irrotational flow
27 Derivation of Continuity equation & Bernoulli theorem, Limitations of
Bernoulli͛s theorem
28 Derivation of Discharge formula of Venturimeter
29 Explain pitot tube and derive velocity through pitot tube
30 Calculations based on Bernoulli͛s theorem
31 Class test
32 Unit Discussion
33 Module-05 Orifices, Notches and weirs-Introduction to orifice and types of orifice
33 Flow through different types of orifice
34 Coefficient orifice and relation between orifice coefficient
35 Notch & Weir ,Classification of Notches and weirs
36 Derivation of discharge over a rectangular Notch and weir
37 Derivation of discharge over a triangular notch and weir
38 Calculation based on orifice and notches
39 OMR-3
40 Module-06 Flow through pipe: Introduction to flow through of pipes
41 Losses of energy in pipes
42 Head loss due to friction Darcy͛s formula
43 Head loss due to friction Chezy͛s formula
44 Calculations based on Darcy͛s formula
45 Calculations based on Chezy͛s formula
46 Hydraulic gradient line ,Total energy line
47 Calculations based on hydraulic gradient line & total energy line
48 Unit Discussion
49 OMR-4
50 Module -07 Impact of jets: Introduction of impact of jet
51 Force exerted by the jet on a stationary vertical plate & moving
vertical plate
52 Derivation of work done on series of vanes
53 Derivation of condition for maximum efficiency
54 Impact of jet on moving curved vanes
55 Illustration using velocity triangles
56 Derivation of work done on impact of jet on moving curved vanes
57 Derivation of efficiency of impact of jet on moving curved vanes
58 Calculations based on impact of jet
59 Unit Discussion
60 OMR-5
Signature of Faculty Member:
Date: 9.12.2019 Counter Signature of H.O.D