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UG Syllabus, Mechanical Engineering
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1
BANGALORE UNIVERSITY
Scheme of Study and Syllabus for
Four Year B.E. Degree Course
in
MECHANICAL ENGINEERING
APPROVED BY THE BOARD OF STUDIES IN
MECHANICAL ENGINEERING AT THE MEETING
HELD ON
05 JULY 2006
DEPARTMENT OF MECHANICAL ENGINEERING UNIVERSITY VISVESVARAYA COLLEGE OF ENGINEERING
BANGALORE UNIVERSITY
K.R. CIRCLE, BANGALORE – 560 001
2
2006
BANGALORE UNIVERISTY
Scheme of Curriculum for B.E. Mechanical Engineering
UVCE, Bangalore 560 001
2K6 SEMESTER SCHEME I SEM B.E MECHANICAL ENGINEERING
SL
NO Code No Subjects Lecture
Hrs/
Week
Pract
Hrs
Week
Exam
Hrs Theory
Exam
Hrs Practical
Int.Ass
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6 SM101 Engineering
Mathematics - I
4 -- 3 -- 25 100 125
2 2K6 CH 101/
2K6 P101 Engineering Chemistry
Engineering Physics
4 -- 3 -- 25 100 125
3 2K6 ME101/
2K6 ME102 Mechanical
Engineering Science /
Workshop Practice – I
4 -- 3 -- 25 100 125
4 2K6 EE101 Electrical Science 4 -- 3 -- 25 100 125
5 2K6 CE 101 Engg Mechanics 4 -- 3 -- 25 100 125
6 2K6 CH 102/
2K6 P 102 Chemistry Laboratory
/ Physics Laboratory
-- 3 -- 3 25 100 125
7 2K6 CI 101 Computer
Programming
4 -- 3 -- 25 100 125
8 2K6 CI 103 Computer
Programming
Laboratory
-- 3 -- 3 25 100 125
TOTAL 200 800 1000
II SEM B.E. MECHANICAL ENGINEERING
SL
NO Code No Subjects Lecture
Hrs/
Week
Pract
Hrs
Week
Exam
Hrs
Theory
Exam
Hrs
Practi
cal
Int.Ass
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6 SM201 Engineering Mathematics - II 4 -- 3 -- 25 100 125
2 2K6 CH 101
2K6 P101
Engineering Chemistry /
Engineering Physics
4 -- 3 -- 25 100 125
3 2K6 ME101/
2K6 ME102
Mechanical Engineering
Sciences/
Workshop - I
4 -- 3 -- 25 100 125
3
4 2K6 EC201 Basic Electronics 4 -- 3 -- 25 100 125
5 2K6 EC 202 Strength of Materials 4 -- 3 -- 25 100 125
6 2K6 CH 102/ 2K6 P 102
Chemistry Laboratory
/Physics Laboratory
-- 3 -- 3 25 100 125
7 2K6 ME201 Engineering Drawing -- 4 -- 4 25 100 125
8 2K6 ME 202 Computer Aided Drafting
Laboratory
3 3 25 100 125
TOTAL 200 800 1000
III SEM B.E. MECHANICAL ENGINEERING
SL
NO
Code No Subjects Lecturer
Hrs
Week
Pract
Hrs/
Week
Exam
Hrs/
Theory
Exam
Hrs/
Practical
Int.Ass
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6 SM301 Engineering
Mathematics-III
4 -- 3 -- 25 100 125
2 2K6 ME 302 Material science 4 -- 3 -- 25 100 125
3 2K6 ME 303 Basic Thermodynamics 4 -- 3 -- 25 100 125
4 2K6 ME 304 Fluid Mechanics 4 -- 3 -- 25 100 125
5 2K6 ME 305 Kinematics of Mechanics 4 -- 3 -- 25 100 125
6 2K6 ME 306 Machine Drawing -- 3 -- 4 25 100 125
7 2K6 ME 307 Workshop Practice – II -- 3 -- 3 25 100 125
8 2K6 ME 308 Material Testing Laboratory -- 3 -- 3 25 100 125
TOTAL 200 800 1000
• BRIDGE COURSES FOR BE (PART TIME) AND B.E. (DIPLOMA CANDIDATES) :
1. 6BSM101 Engineering Mathematics –I
2. 6BSM201 Engineering Mathematics –II
3. 6BEC 201 Basic Electronics and C-Programming
IV SEM B.E. MECHANICAL ENGINEERING
SL
NO
Code No Subjects Lecturer
Hrs
Week
Pract
Hrs/
Week
Exam
Hrs/
Theory
Exam
Hrs/
Practical
Int.Ass
Marks
Exam
Marks
Tota
l
1 2 3 4 5 6 7 8 9 10
1 2K6 SM401 Engineering Mathematics - IV 4 -- 3 -- 25 100 125
2 2K6 ME402 Engineering Materials 4 -- 3 -- 25 100 125
3 2K6 ME403 Dynamics of Machines 4 -- 3 -- 25 100 125
4 2K6 ME404 Hydraulic Machinery 4 -- 3 -- 25 100 125
5 2K6 ME 405 Applied Thermo-Dynamics - I 4 -- 3 -- 25 100 125
6 2K6 EE 406 Fluid mechanics & Machines
Laboratory
-- 3 -- 3 25 100 125
7 2K6 ME 407 Machine Shop – I -- 3 -- 3 25 100 125
4
8 2K6 EE 408 Electrical & Electronics
Laboratory
-- 3 -- 3 25 100 125
TOTAL 200 800 1000
V SEM B.E. MECHANICAL ENGINEERING
SL
No
Code No Subjects Lecturer
Hrs
Week
Pract
Hrs/
Week
Exam
Hrs/
Theory
Exam
Hrs/
Practial
Int.As
s
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6 ME501 Control Engineering 4 -- 3 -- 25 100 125
2 2K6 ME502 Mechanical
Measurements
4 -- 3 -- 25 100 125
3 2K6 ME503 Machine Design - I 4 -- 3 -- 25 100 125
4 2K6ME504 Manufacturing
Technology - I
4 -- 3 -- 25 100 125
5 2K6 ME 505 Applied Thermo-
Dynamics - II
4 -- 3 -- 25 100 125
6 2K6 ME 506 CAD Laboratory - I -- 3 -- 3 25 100 125
7 2K6 ME 507 Machine Shop – II -- 3 -- 3 25 100 125
8 2K6 ME 508 Measurement &
Metrology Laboratory
-- 3 -- 3 25 100 125
TOTAL 20 09 200 800 1000
VI SEM B.E. MECHANICAL ENGINEERING
SL
NO
Code No Subjects Lecturer
Hrs
Week
Pract
Hrs/
Week
Exam
Hrs/
Theory
Exam
Hrs/
Practical
Int.Ass
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6ME601 Object
Oriented
programming
4 -- 3 -- 25 100 125
2 2K6 ME602 Industrial
Management
4 -- 3 -- 25 100 125
5
3 2K6 ME603 Machine
Design II
4 -- 3 -- 25 100 125
4 2K6ME604 Manufacturing
Technology -II 4 -- 3 -- 25 100 125
5 2K6 ME 605 Heat & Mass
Transfer
4 -- 3 -- 25 100 125
6 2K6 ME 606 Design
Laboratory - I
-- 3 -- 3 25 100 125
7 2K6 ME 607 Manufacturing
Technology
Laboratory
-- 3 -- 3 25 100 125
8 2K6 ME 608 CAD
Laboratory -II
-- 3 -- 3 25 100 125
TOTAL 20 09 200 800 1000
VII SEM B.E. MECHANICAL ENGINEERING
SL
NO
Code No Subjects Lecturer
Hrs
Week
Pract
Hrs/
Week
Exam
Hrs/
Theory
Exam
Hrs/
Practical
Int.Ass
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6 ME701 Finite Element
Analysis
4 -- 3 -- 25 100 125
2 2K6 ME702 Operation Research 4 -- 3 -- 25 100 125
3 2K6 ME703 Energy Resources &
Utilization
4 -- 3 -- 25 100 125
4 2K6 ME 704 Machine Design-III 4 -- 3 -- 25 100 125
5 2K6 ME 705 Elective - I 4 -- 3 -- 25 100 125
6 2K6 ME 706 Simulation Laboratory -- 3 -- 3 25 100 125
7 2K6 ME 707 Design Laboratory- II -- 3 -- 3 25 100 125
8 2K6 ME 708 Heat Transfer & I.C.
Engines Laboratory
-- 3 -- -- 25 100 25
TOTAL 20 09 200 800 1000
Elective I :
2K6 ME 705.A. Entrepreneurship Development
2K6 ME 705.B. Electronics Manufacturing Process
2K6ME 705.C. Automobile Engineering
2K6ME 705.D. Advanced Trends in Manufacturing
6
2K6ME 705.E. Experimental stress Analysis
2K6 ME 705.F. Foundry Technolgy
2K6ME 705.G.. Environmental Engineering
2K6ME 705.H . Gas Dynamics and Propulsions
2K6 ME 705.I. Smart materials and Structures
2K6 ME 705.J Financial Management & Costing
* Marks for Project Tour will be entered in the VIII Semester
VIII SEM B.E. MECHANICAL ENGINEERING
SL
NO
Code No Subjects Lecturer
Hrs
Week
Pract
Hrs/
Week
Exam
Hrs/
Theory
Exam
Hrs/
Practical
Int.Ass
Marks
Exam
Marks
Total
1 2 3 4 5 6 7 8 9 10
1 2K6 M801 Production Operational
Management
4 -- 3 -- 25 100 125
2 2K6 ME802 Total Quality
Management
4 -- 3 -- 25 100 125
3 2K6 ME803 CAD/CAM &Robotics 4 -- 3 -- 25 100 125
4 2K6 ME804 Modern Methods of
Manufacturing
4 -- -- -- 25 100 125
5 2K6 ME 805 Elective – II 4 -- -- -- 25 100 125
6 2K6 ME 806 CAD/CAM &
Robotics Laboratory
-- 3 -- 3 25 100 125
7 2K6 ME 807 Project Work -- 6 -- -- 75 150 225
8 2K6 ME 808 Project Tour 25 -- --
TOTAL 20 09 250 750 1000
Elective II :
2K6 ME 805.A. Technology for Rural Development
2K6 ME 805.B. Mechanism & Transmission
7
2K6 ME 805.C. Failure Analysis & Design
2K6 ME 805.D. Materials management
2K6 ME 805.E. Turbo Machines
2K6 ME 805.F Computational Fluid Dynamics
2K6 ME 805.G Computer Aided Engineering
2K6 ME 805.H. Enterprise Resources and Planning
2K6 ME 805.I. Value Engineering
2K6 ME 805.J. Mechatronics
III SEMESTER B E MECHANICAL ENGINEERING
2K6 ME SM 301 ENGINEERING MATHEMATICS – III
(Common to CE, ME, EE, EC, CSE, ISE)
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
PART - A
UNIT-I
Fourier Series of periods 2� and 2l- complex from half range Fourier series-since series,
Cosine series
Finite Fourier since / coline transforms – Transforms of derivatives.
UNIT-II
Infinite Fourier transforms and Inverse Fourier transforms – Simple Properties.
Complex Fourier transforms, Fourier since/cosine transforms, Convolution theorem &
Perseval’s Identities (without proofs)
Z transform – definition, Standard forms, linearity property.
UNIT-III
Bessel Functions : Solutions of the Bessel differential equation. The Bessel function,
Recurrence relations, Orthogonality, Generating function.
UNIT-IV
8
Legendre Polynomials : Solution of the legendre differential equation, Legendre
Polynomials, Generating function, Recurrence relations.
PART – B
UNIT-V
Formation of Partial differential equation: Solution by Lagrange’s method for first order
Partial differential equation’s, Solution of standard types of non-linear Partial differentia
equation’s – Charpit’s method.
UNIT-VI
Solution of one dimensional wave equation by the method of separation of variables and
by Fourier series method. Solution of one dimension heat equation by the method of
separation of variables and by Fourier series method.
UNIT-VII
Curve fitting by the method of leart squares Peanson’s coefficient of correlation Rank
correlation, Regression lines – problems.
UNIT-VIII
Conditional probability, Baye’s theorem, Binomial/Poisson probability distribution,
Normal probability distribution.
PATTERN OF QUESTION PAPER :
The question paper contains two Parts namely PART-A and PART-B each
containing 4 questions. Five questions in all out of 8 questions are to be answered
choosing atleast two from each PART.
DISTRIBUTION OF QUESTIONS :
One question each from Unit-I to Unit-VIII
References :
1. B. S. Grewal : Higher Engineering Mathematics, Khanna Publishers
2. Ejvin Kreyzig : Advances Engineering Mathematics, John Wiley & Sons
III SEMESTER B E MECHANICAL ENGINEERING
2K6 ME 302 Material Science.
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT - I
1. Engineering requirements of materials. Mechanical Properties of Materials, Tension
test, Hardness tests and Impact tests. Non–destructive Testing: Dye-Penetrant check,
Magnetic flaw detection, Ultra – sonic flaw detection.
6
2. Crystal Structures: Space lattice classification, SC, BCC, FCC and HCP Structures,
Miller Indices for planes and directions. Crystal imperfections.
3
9
3. Atomic Diffusion: Phenomenon, mechanisms of diffusion. Fick's Law. Activation
energy. Factors affecting diffusion. Practical applications. Related Problems.
3
UNIT -II
4. Mechanical Behaviour of Materials: Elastic and Plastic behaviour. Yield point
phenomenon. True stress-true strain relationships. (Related Problems). Plastic
deformation of single crystals: CRSS (Related Problems,) Slip deformation.
Dislocations and plastic deformation. Twinning deformation.
12
5. Strengthening Mechanisms: Grain boundary effect, strain hardening, soild solution
strengthening, strain aging. Recovery , Recrystallisation and Grain Growth. Frank
Read Source of dislocations.
12
UNIT- III
6. Fracture of Materials: Types of fracture. Effect of temperature, strain rate and
triaxiality on flow stress and ductile to brittle transition. Notch sensitivity.
8
7. Fatigue Behaviour: Types of fatigue loading, Mechanisms of fatigue failure. Fatigue
properties, fatigue test: S-N Diagram, factors affecting fatigue behaviour.
8
8. Creep Behaviour: Creep Phenomenon, Three stages of creep. Transient creep and
Viscous creep. Creep rupture. Creep Properties, Creep Test
8
Books for Reference:
1. William D. Callister: Material Science and Engineering - An Introduction. John
Wiley & sons Inc. 1997.
2. William F Smith: Principles of Materials Science and Engineering. Tata McGraw Hill
Inc 1996.
3. O.P. Khanna : A Textbook of Materials Science and Metallurgy. Dhanpat Rai
Publication 1999.
Scheme of Examination:
2 Questions in unit 1, 3 Questions each in unit 2 and 3 are to be set.
Students are to answer a total of 5 questions choosing any 1 question in unit 1, any 2
questions each in unit 2 and 3.
III SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 303 Basic Thermodynamics
10
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
Basic Concepts:
System, Surroundings, Boundary, property, state, process, cyclic process, path function,
point function, Microscopic and Macroscopic point of view of thermodynamics,
thermodynamic equilibrium, thermodynamic work, heat.
6
Zeroth law of Thermodynamics:
Concept of Temperature statement and explanation of Zeroth law of Thermodynamics.
Measurement of temperature using concept of Zeroth law of thermodynamics.
International scale of Temperatures.
8
First Law of Thermodynamics
Statement of I law of thermodynamics as applied to a closed system – Internal energy a
property – I law applied to an open system with assumptions – concept of perpetual
motion machine kind I (PMMK I) – Numerical Problems.
8
Second law of thermodynamics:
Concept of Heat Energy, efficiency of a heat engine – concept of Heat pump and
Refrigerator coefficient of performance – the two statements of II law of
Thermodynamics as applied to a heat engine and heat pump. Equivalency of the above
two statements – concept of PMMKII – reversible process – concept of irreversibility –
Factors that render a process irreversible – analysis of reversible cannot cycle – Carnot
heat engine and Carnot heat pump.- Numerical Examples.
8
UNIT – II
Corollaries of II law of Thermodynamics:
Cor.1. Comparison between a heat engine and a reversible engine – Cor 2. Comparison
among reversible engines – Cor 3. Absolute thermodynamics temperature scale – Cor 4.
Clasius Inequality – Cor 5. Entropy is a property – Cor 6. Principle of increase of entropy
– Numerical examples
8
11
Analysis of following processes by applying I and II law of Thermodynamics.
1. Isochorec process 2. Iso baric process 3. Isothermal process 4. Isotropic process
5. Polytropic process – Numerical examples.
6
Concept of ideal and real gases vandervalls equation – compressiblity & factor and chart
– critical and reduced co-ordinates – Numerical examples.
6
Mixture of Gases:
Non reactive mixtures – mole fraction – mass fraction – volume fraction – law of partial
pressures – Relatives involving pressure volume, internal energy. Enthalpy - entropy and
specific heats of gaseous mixtures – Numerical examples.
10
Books of Reference:
01. A Course in thermodynamics by kolhandaraman & others
02. Thermal Engineering – Rajput
03. Thermal Engineering – S K Kulshresta
04. Thermodynamics – M.J. Moran & H. Shapiro
05. Thermodynamics an engineering approach – Yunus. A.Cengel & (SI Units)
Mechacl A. Boles (Tata Mc Graw – Hill 4th
Edition 2005 Print)
06. Thermodynamics by Hollman
Scheme of Examination:
Questions to be set: 4 questions from unit 1.
4 questions from unit 2
Students are to answer 5 questions choosing at least 2 question from each unit.
12
III SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 304 Fluid Mechanics
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Fundamental concepts and properties. Fluid-definition, concepts of continuum,
shear stress as applied to fluids, fluid properties viscosity, Newton’s law, surface
tension, Bulk modulus, compressibility, vapour pressure, capillarity, international
standard atmosphere, numerical problems
pressure at a point, gauge and absolute pressures of a fluid. 6
Hours
2. Fluid Statics:
Principle of manometers, simple and differential manometers, Bourdon’s pressure
gauge, Pascal’s law, Numerical problems, Hydrostatic forces on plane and inclined
surfaces, numerical problems.
4 Hours
3. Floatation of bodies -
Archimede’s principle, stability of floating bodies. Determination of Metacentric
height - experimental and analytical methods - numerical problems.
4 Hours
4. Fluid Kinetics
Definitions of path line, steam line, streak line, flow nets, steam tube, steam function,
velocity potential function, numerical problems, continuity equation for one
dimensional fluid flow, types of fluid flow steady flow, uniform, rotational flow,
laminar flow, turbulent flow, Compressible flow. Acceleration of a fluid particle.
10 Hours
UNIT II
5. Fluid Dynamics
Forces acting on fluid mass, Eulers equation of motion, energy possessed by a fluid
particle, Bernoulli’s equation derivation from one dimensional Eulers equation of
motion. Applications of Bernoulli’s principle venturimeter, orifice meter, pitot tube,
notches- rectangular, triangular, trapezoidal notches orifices: vertical, horizontal
13
numerical problems. Vortex motion, Reynolds Number & its significance. Hagen
poiseulles equation for flow through pipes. Turbulent flow: Darcy’s equation for
turbulent flow through pipes, numerical problems.
15 Hours
6. Dimensional analysis:
Principle of dimensional analysis, Buckingham pitheorem, application,
dimensionless numbers and introduction to model studies.
07 Hrs
7. Flow Around Bodies:
Bluf body, streamlined body, Aerofoil, flow past bluff body, streamlined body and
aerofoil with examples, concept of boundary layer, circulation, lift and drag (physical
concepts) 07 Hrs
8. Compressible Flow:
Velocity of sound wave in isothermal and adiabatic conditions, Mach number and its
significance and mach cone, numerical problems. 09 Hrs
Bernoulli’s equation for compressible flow
Books for Reference:
1. Fluid Mechanics – Streter
2. Fluid Mechanics and Hydraulic Machines – Modi and Seth
3. Fluid mechanics and fluid power D.S. Kumar
Scheme of Examination
Students are to answer any Five Full questions choosing at least two questions from each
unit. Four questions are to be set from each unit.
14
III SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 305 Kinematics of Machines
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. MECHANISMS
Introduction to the course: 10
Definitions of element, Kinematic pair, Kinematic chain, Degree of freedom,
Inversion of Mechanism and Machine.
Linkages: 4 bar chain, simple slider crank chain, Double slider Crank chain and their
inversions, Degree of freedom for plane mechanism.
Straight line motion: Peaucellier mechanism, Watt’s Straight line mechanism,
Hookes joint; Double Hookes joint, pantograph
Intermittent motion mechanism: Rachet and Pawl Mechanisms, Intermittent Gearing,
Geneva Wheel, Escapement.
2. VELOCITY AND ACCELERATION IN MECHANISM: 10
Velocity in mechanisms by instantaneous center method. Velocity and acceleration
in simple mechanisms (including coriolis component) by relative, velocity
method, Velocity and acceleration of simple slider mechanisms by analytical method
and by Klein’s Construction.
UNIT II
15
3. BELT, ROPES AND CHAIN DRIVES: 8
Introduction: Belt drive, Effect of slip and Creep in belts, Length of belt, Initial
tension; Ratio of belt Tensions, Power transmitted, Effect of centrifugal tension,
Cantilever Max. power transmission, Rope and V belt drives, Kinematics of chain
drive. 8
4. CAMS
Classification of Cams and followers, Types of motion of follower (Uniform
Velocity, SHM, UARM and Cycloidal) Graphical Cam Layout.
8
5. GEARS:
Friction Wheel, Teeth for positive action:
Classification of gears, Gear Terminology; Law of gearing ; Velocity of sliding;
Forms of teeth (Cylindrical & Involute), Path of contact; Contact ratio.
Interference in gears and methods of avoiding interference; Minimum no.of teeth on
rack, pinion & gear when in mesh to avoid interference.
Introduction to Bevel, Helical, Spiral and worm gears (without involving problems)
6. GEAR TRAINS: 8
Classification; Velocity ratio for epicyclic gear train, Evaluation tooth loads and
torques in epicyclic gear train;
Automobile gear box, Differential gear box. 8
REFERENCE BOOKS:
1. Theory of Machines by G.G. Rattan, Tata Mcgraw Hill Publishing Co., Ltd, New
Delhi.
2. Mechanism and Machine Theory: J.S. Rao and R.V. Dukkipati, Wiley Eastern Ltd,
Bangalore.
3. Theory of Machines by P.L Ballaney, Khanna Publishing
4. Theory of Machines by J.E.Shigley, Vicker, McGraw Hill.
5. Mechanics and Dynamics of Machinery by Hamilton. H. Mabie and Charles. F
Rein holtz… John Wiley Publishers.
6. Theory of Machines by Jagadish Lal, Metropolitan Book Co., Pvt, Ltd, Delhi.
16
Scheme of Examination:
To set four questions from each Unit.
Students are required to answer five full questions choosing at least two from each unit.
III SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 306 Machine Drawing
(In First Angle Projection)
Class : 3 Hours/Week Internal Assessment Marks: 25
Examination: 4 Hrs Max marks for Examination:
100
Non – Examination Unit:
B.I.S. Codes in Machine Drawing, Dimensioning, Indication of Tolerances, fits, surface
Texture symbols, conventional representation of screw threads, construction of nut and
bolt, studs, machine parts not sectioned materials in section, different types of keys,
welding symbols.
6
Examination Unit:
UNIT I
17
(To set 2 questions i.e. One on Developments and ONE on conversion of views and
student to answer any ONE question of 20 marks)
Development of lateral surfaces:
Development of lateral surfaces of right regular prisms, pyramids, cones, cylinders and
when truncated and with through holes. Development of transition pieces.
Conversion of Views:
Drawing orthographic views and sectional views from given isometric view of simple
machine parts 15
UNIT II
(To set 2 questions and student to answer ONE question of 20 Marks)
Drawing only the front view of the assembly in section/half section, when details of
individual parts are given, for the following items:
1. Cotter Joints
2. Pin or Knuckle Joints
3. Split Muff Coupling
4. Flanged couplings
5. Compression Coupling
6. Bush Type Flexible Coupling
7. Universal Coupling 15
UNIT III
(To Set ONE question of 60 marks, to be answered compulsory)
Drawing the 3 principal views of the assembly, of which one or two views in section/half
section, when the details of individuals parts are given, for the following items:
1. Screw Jack
2. Stop Valve
3. Plummer Block
4. Split Sheave Eccentric
5. Gland and Stuffing Box Expansion Joint
6. Feed Check Valve
7. Swivel Bearing
8. Machine Vice
18
9. Rambottom safety Valve.
10. Tailstock of Lathe
11. Tool Head of a Shaper
12. Cross Head of a Vertical Steam Engine 24
TEXT BOOKS:
1. Machine Drawing: K.R.Gopala Krishna
2. Machine Drawing : N.D. Bhatt.
III SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 307 Workshop Practice –II
Class: 3 Hrs / week Internal Assessment Marks:
25
Examination : 3 Hrs Max. Marks Examination:
100
1. Welding processes – 4 models in each process
19
1.1 TIG & MIG Welding
1.2 Gas welding
2. Wood Turning - Three models
3. Forging - Three models
Scheme of Examination:
1. VIVA-VOCE - 20 Marks
2. One model from welding - 40 Marks
3. One model from Wood turning or Forging - 40 Marks
III SEM B.E. MECHANICAL ENGINEERING
2K6 ME 308 Material Testing Laboratory
Class: 3 Hrs/Week Internal Assessment Marks: 25
20
Examination: 3 Hrs Max Marks for Examination: 100
Group Test
1. Testing of materials using UTM
Tension Test
Compression Test
Shear Test
Bending Test
2. Torsion Test
3. Hardness Tests
3.1 Brinell Hardness Test
3.2 Rock Well Hardness Test
4. Impact Tests
4.1 Izod Test
4.2 Charpy Test
5. Wear Test using Different Methods
6. Testing of Welded joints
7. N.D.T. (Any Three)
8. Study of Grain Structure of different metals using Metallurgical Microscope.
9. Demonstration of Fatigue Test.
Scheme of examination:
Viva & voce 20 marks
One experiment in group test 60 marks
One experiment on individual test 20 marks
IV SEM B.E. MECHANICAL ENGINEERING
2K6 SM 401 ENGINEERING MATHEMATICS – IV
21
(Common to CE, ME, EE, EC, CSE, ISE)
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
PART - A
UNIT-I
Sets in the Complex plane-Functions of a complex variable-limit, continuity and
differentiability-Analytic functions-Cauchy-Riemann equations in Cartesian and polar
forms. Harmonic functions
UNIT-II
Complex integration-Line integral, Cauchy theorem (Proof by Green’s theorem), Cauchy
integral formula for complex functions and for derivatives, problems.
UNIT-III
Power series-Convegrence, Radius of convergence, Taylor’s theorem and Laurent’s
theorem (statement only), problems.
UNIT-IV
Singularities, Poles, Classification of singularities, Cauchy residue theorem-Evaluation of
definite integrals of the types � �∞
∞−
π
θθθ
2
0
d ) Cos , F(sin anddx F(x)
PART – B
UNIT-V
Algebraic and transcendental equations – solution by bisection regular-falsi, Secant’s
linear-iteration and Newton-Raphson’s methods, Aitken’s �2 – method.
UNIT-VI
Solution of system of linear equations, Gauss-elimination, Gaus-Jordan methods, LU-
decomposition, Choleky’s methods, Jacobi and Gauss-Seidle iteration methods.
UNIT-VII
Finite differences-Forward, Backward and Central differences – Shift operator (No
derivations of relations between operators)
Interpolation-Newton’s divided difference, Lagrange’s Interpolation formula (problems
only) Numerical differentiation based on Newton’s forward and backward difference
formula.
UNIT-VIII
Numerical Integration-Trapezoidal, Simposon’s 1/3rd
, Simpson’s 3/8th
rule, solution of
ordinary differential equations : Euler’s, Modified Euler’s, Picard’s, Runge-Kutta II and
IV order methods.
PATTERN OF QUESTION PAPER :
The question paper contains two Parts namely PART-A and PART-B each
containing 4 questions. Five questions in all out of 8 questions are to be answered
choosing atleast two from each PART.
References :
22
1. Complex Analysis : Schaum series
2. Numerical methods for Physicus and Engineers, Iyengar, Jain and Iyengar, New Age
Inte.
4th
Edition.
3. Sastry : Introductory methods of Numerical analysis, PHI
IV SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 402 Engineering Materials
Lecture: 4 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for examination:
100
Total No. of Hours: 60
UNIT I
1. Metallography: Optical Microscopy, Metallurgical microscope and specimen
preparation. Scanning Electron Microscope.
05
2. Solidification and Phase diagrams: Homogeneous and heterogeneous
nucleation, grain growth. Solid solutions, Gibbs Phase rule. Types of phase
diagrams, Lever Rule, intermediate phases.
05
3. Ferrous Materials: Iron-Carbon Equilibrium phases diagram and Non-
equilibrium phase diagram. T.T.T. Phases formed in these conditions. Influence
of alloying elements on Non equilibrium diagrams.
08
4. Non-ferrous materials: Alloys of Al, Cu, Ni, Mg and Ti,
06
UNIT II
5. Heat treatment of metallic materials: Annealing. Normalising. Hardening.
Tempering. Surface hardening: Carburising. Cyaniding, Nitriding. Flame and
Induction Hardening. Heat treatment of Non-ferrous materials: Solutionising.
Precipitation hardening. Aging.
12
6. Composite Materials: Types of composite materials. Properties of fibers and
matrix materials. General methods of production, properties and applications of
FRP, PRC, MMC and structural composites. Expressions for density, Young’s
modulus, and strength of continuous fiber reinforced composites in iso – strain
23
and iso – stress conditions.
12
UNIT III
7. Composition, structure and applications of the following materials: (a) Cast
irons (b) Plain Carbon Steels (c) Alloy steels (d) Copper alloys (e) Aluminium
alloys
(f) Titanium Alloys
08
8. Smart Materials: Piezo Electric materials, Electrostrictive, magnetostrictive
materials, shape memory alloys, fiber optic sensors.
04
Books for Reference:
1. William D.Callister: Material Science and Engineering – An Introduction.
John Wiley & sons Inc. 1997.
2. William F Smith: Principles of Materials Science and Engineering. Tata Mc Graw
Hill Inc 1996.
3. O.P.Khanna: A Textbook of Materials Science and Metallurgy. Dhanpat Rai
Publication 1999
Scheme of Examination:
Examiners to set 3 Questions each in unit I and unit II, 2 questions in unit III. Students
to answer a total of 5 questions choosing any 2 question in unit I, & unit II and any 1
question in unit III.
24
B.E IV SEMESTER MECHANICAL ENGINEERING
2K6 ME 403 Dynamics of Machines
Lecture: 4 Hrs / week Internal Assessment Marks: 25
Exam: 3 Hrs Exam Marks: 100
Total No. of Hours: 60
UNIT I
1. Force Analysis of Mechanisms
6
Static force analysis of mechanisms with and without friction, Dynamic force
analysis, D’Alembert’s Principle, Equivalent mass system.
2. Flywheel
6
Dynamics of Engine mechanisms, Turning moment. Diagram for different engines,
fluctuation of speed energy, Size of flywheel.
3. Governers
6 Governor function and classification of governors (Centrifugal and Inertia).
Porter Governor, Hartnell Governer, Effect of friction, Characterization of Governors.
25
4. Gyroscopic Couple & Predessional Angular Motion
12 Principle of gyroscope motion, gyroscopic couple, Direction of spin,
precession and torque vectors, gyroscopic effect on planes, ships, 2 wheelers, 4
wheelers & rotors.
UNIT II
5. Balancing of Rotating And Reciprocating Masses
14
Balancing static and dynamic balancing, Balancing of rotating masses. Balancing of
reciprocating masses, Partial balancing, Balancing of in line engine, V engine, Radial
engines, Primary and Secondary balancing, Direct and Reverse crank balancing
machines.
6. Vibrations
16 Causes and effect of vibration in machines. S.H.M., Degree of freedom.
Free, Damped and Forced vibration (single degree of freedom only). Vibration
isolation and transmissibility. Whirling of shafts. Free torsional vibration of shafts
with one, two and three rotors; Geared System.
Books for Reference:
1. Theory of Machines by G.G. Ratan, TATA Mc Graw Hill publishing co., Ltd.,
New Delhi.
2. Mechanisms and Machine Theory; J.S. Rao and R.V. Dukkipati, wiley Eastern
Publication.
3. Theory of Machines by P.L. Ballaney, Khanna Publication.
4. Theory of Machines by J.E. Shiegley, Vicker, McGraw Publication.
5. Mechanisms and Dyanamics of Machinery by Hamilton, H. Mabie and Charles F.
Rein holtz., John Wiely Publishers.
26
6. Theory of Machines by Dr. R.K. Bansal.
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer a total of five questions choosing at least two questions from each
unit.
IV SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 404 Hydraulic Machinery
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
27
1. Impact of jet on vanes:
Impulse momentum principle, application, impact of jet on flat, inclined
curved, fixed and moving vanes, numerical problems.
6
2. Hydraulic turbines:
Theory of turbines and classification of turbines, study of construction, working,
velocity diagrams and efficiencies of pelton wheel, Francis and Kaplan turbines,
numerical problems.
Performance of turbines, specific speed and unit quantities, characteristic curves,
cavitations, governing of turbines, model testing of turbines, numerical problems.
14
3. Centrifugal pumps:
Construction and working principle classification vector diagram, Work done,
efficiencies, minimum starting speed specific speed performance characteristics,
multistage pumps, numerical problems.
9
UNIT II
4. Reciprocating Pumps:
Construction and working principle, classification, definition of slip, co-efficient of
discharge, indicator diagram effect of friction acceleration and air vessel, maximum
speed of crank, numerical problems
9
5. Hydraulic devices:
Hyd. Ram, Simple Hyd. Accumulator, Hyd. Intensifier Hyd. Press Hyd. Crane Hyd.
Coupling Jet pump, Air Lift Pump Gear Pump
5
6. Hydro-Electric Power Plant:
28
Energy lines- HGL and TEL, hydro meteoric survey, selection of site for a dam,
head race, tail race, gross head, net head, Comparison of Thermal and Hydroelectric
Power Cost. Assessment of Available Power for a proposed Hydel Power station,
Types of Hydropower Power Plant, Run-of-river Plants, Reservoir Plants, Pumped
storage Plants, Base-load Plants, Peak – Load Plants, Primary and Secondary Power,
Layout of Hydro electric Power Plant- Dam, Water way, Penstock, Forebay, Intake
structure, Trash rack, Surge Tank, Power House.
12
Connected Load, Maximum Demand, Demand Factor, Load curve, load factor, Plant-use
Factor, capacity factor, diversity factor, peak load, numerical Problems.
6
Reference Books:
1. Principles of turbo machines by H.G. Sheppard.
2. Fluid mechanics and hydraulic machines by Modi & Seth
3. Fluid mechanics and Hydraulic Machines by D.S. Kumar
4. Power plant engineering by Domkundwar
Scheme of Examination:
Examiner to set four questions from each Unit.
Answer any Five Full questions choosing at least Two questions from each unit.
29
IV SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 405 Applied Thermodynamics - I
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Air Standard Cycles: air standard efficiency & - mep of otto cycle – diesel cycle – dual combustion cycle numerical problems - deviation of real cycle from theoretical air cycle. 6
2. Combustion of Fuels: theoretical air required, excess air actual air required for
complete combustion of solid, liquid and gaseous fuels - numerical problem - analysis
of products of combustion.
6
3. Classification of I.C Engines; Four stoke and two stroke cycle engines - Valve time
diagram for four stoke engine combustion in SI Engines - detonation (KNOCK) in SI
engines - variable affecting knock in SI Engines and their effects - methods to reduce
detonation - combustion in CI engines - Knock in the CI engine – effect of engine
variables on diesel knock and methods to reduce diesel knock rating of SI and CI
engine fuels – carburetion - simple and complex carburetor - fuel pump for S.I engine
- ignition systems for SI engines - fuel injection system for CI engine - Supercharging
of IC engines - Cooling of IC engines - Governing of IC engines - Introduction to
wrinkle engine, Introduction to MPF engine.
12
4. Performance and Testing of IC Engines:
Introduction: Indicated power - Brake power - Various I.C. engine efficiencies -
Specific fuel consumption - Heat balance sheet Measurement of IP of IC engines -
Performance curves for SI engines - Variables effecting engine performance - Power
requirement and power available curve problems.
10
30
UNIT – II
5. Gas Turbines and Jet Propulsion: Introduction - Simple open cycle Gas turbine -
Thermal efficiency of GT - Mechanical efficiency ofof compressor and GT – Over all
efficiency of GT - The cycle work ratio - Optimum pressure ratio for maximum
thermal efficiency and work output – Means of improving the performance of the
simple GT – closed cycle GT - Advantages and Disadvantages over open cycle GT-
Jet propulsions - the turbojet, thrust, thrust power, propulsive efficiency and thermal
efficiency - introduction to ram jet engine and rocket engines.
14
6. Positive Displacement Compressors:- Use of compressed air - Reciprocating
compressors - single stage compressor without clearance and without clearance
volumetric efficiency - Best value for index of compression - Multistage
reciprocating air compressors - minimum work input in multi stage compression -
Heat rejected per Kg of air - Indicators diagram - Mean effective pressure - Indicated
power - shaft power - Optimum intermediate pressure in two stage compressors -
Numerical problems. 12
Book of Reference:
1. Thermal Engineering by Kodandaram & Co
2. Thermal Engineering by Rajput R.K.
3. A Course in I.C. Engines by Mathur &Sharma
4. Thermal Engineering by S.K. Kulshresta.
5. I.C. Engines by V.Ganeshan.vol.1 vol.2.
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any Five Full questions choosing at least Two questions from each
unit.
31
IV SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 406 Fluid Mechanics & Machines Laboratory
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. Determination of flash point and fire point of light, medium and heavy oils
2. Determination of calorific value of solids liquid and gaseous fuels.
3. Determination of viscosity of an oil using red wood saybolt torsion viscometer, U-
tube engler viscometer
4. Use of planimeter.
5. Calibration of pressure gauge
6. Calibration of V- Notch
7. Determination of eo-efficients of vertical and horizontal orifices.
8. Calibration of venturimeter
9. Friction in pipes
10. Impact of jet on vanes
11. Testing of hydraulic Ram
12. Performance Test on centrifugal pump
13. Performance Test on Reciprocating pump
14. Performance Test on Pelton turbine
15. Performance Test on Francis Turbine
16. Performance Test on Kaplan
32
IV SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 407 Machine Shop-I
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
General Instructions: Process sheets and Inspection sheets are to be prepared for
each model.
1. Detailed study of the following machine tools with regard to their construction,
operations and controls:
(i) Lathe (ii) Shaping Machine (iii) Drilling Machine
(iv) Grinding Machine
2. Demonstration of assembly and disassembly of the following lathe parts:
(i) Head Stock (ii) Tail Stock (iii) Carriage (iv) Cross Side (v) Compound Rest
(vi) Bed (vii) Gride Ways (viii) Feed Gear Box (ix) Apron Box.
3. Study of accessories chuck (3 jaw & 4 jaw ), Face plate, Steady rest, Follower
rest, Tool Post & Centers.
33
4. Four Models using lathe involving, Plane involving, Taper Turning, Thread
cutting, groove cutting, Knurling, Drilling, Boring & Eccentric Turning.
5. Two Models using shaping machine involving production of flat surfaces, dove
tails, V and rectangular grooves.
6. Grinding of tool angles using tool and cutter grinder machine.
7. Calculation of machining time for turning, drilling tapping grinding, shaping and
milling.
IV SEMESTER B.E. (MECHANICAL ENGINEERING)
2K6 EE 408 Electrical and Electronics Laboratory
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1.Measurement of Resistance by Wheat stone’s Bridge.
2.Measurement of self inductance by 3 voltmeter and A.V.W method
3. Load characteristic of D.C shunt generator
4. Load test on DC shunt motor
5. Two way and three way control of a lamp.
6. Verification of Kirchoff’s laws for DC circuits
7. Measurement of power and power factor of a fluorescent lamp with and without
capacitor.
8. Transistor characteristics CE, CB, CC mode
34
9. Static characteristic of SCR
10. Output characteristics of MOSFET
General scheme of examination:
1. Viva –voce 20 marks
2. One test in Electrical Engineering - 40 marks
3. One Test in Electronics - 40 marks
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 501: Control Engineering
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
35
1. INTRODUCTION TO CONTROL SYSTEMS:
Introduction - Definition of control system terminology classification of control
systems, open loop and closed loop system.
3
2. MATHEMATICAL MODEL OF PHYSICAL SYSTEMS:
Transfer function derivation of transfer function of Physical systems-Mechanical
systems, Concept of mechanical impedance - Electrical system-Hydraulic system.
Thermal system Block diagrams and signal flow graphs.
8
3. TRANSIENT RESPONSE ANALYSIS:
Standard test signals for time response, response of first and second order systems.
4
4. ERROR ANALYSIS:
Static error coefficients,dynamic error co-efficient-
errors Analysis
3
5. BASIC CONTROL ACTIONS AND CONTROLLERS :
Proportional controllers, derivatives and integral controls proportional plus-derivative
and proportional-plus-integral controllers, PID controllers, velocity feedback control.
3
6. STATE VARIABLE ANALYSIS:
Introduction to modern control theory-comparison of conventional and modern
control theories-state variables and state models, derivation of state models,
deagonalisation, solution of state equation, controllability and observability.
8
UNIT II
36
7. CLOSED LOOP FREQUENCY RESPONSE:
Frequency domain specifications, M circles, N circles, Nichols chart,
experimental determination of transfer function.
3
8. FREQUENCY RESPONSE ANALYSIS:
Polar plots, logarithmic plots, log magnitude vs phase plots.
6
9. STABILITY ANALYSIS:
Introduction-characteristic equation sand stability criterion, Routh Hurwith’s
criterion, Nyquist stability criterion, relative stability analysis, body analysis.
9
10. ROOT LOCUS METHOD:
General procedure for construction of root laci-root locus plots-root locus analysis.
5
11. SYSTEM COMPENSATION:
Introduction, phase lead, phase lag, lag-lead compensation methods-comparison of
compensation methods.
3
12. ELEMENTS OF NON-LINEAR CONTROL SYSTEM:
Introduction, common physical non-linearities-describing function and describing
function analysis, phase -plane analysis, singular points, limit cycle behavior
5
Book for REFERENCES :
1. Automatic Control Systems - Harrrison & Boelinger
2. Modern Control Theory - Ogata
3. Automatic Control Systems - Benjamin C Kuo
4. Automatic Control Engineering – Raven
5. Control Systems – A. Nagoor Karni
6. Control system Engineering – Bakshi
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any Five Full questions choosing at least Two questions from each
unit.
37
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 502 Mechanical Measurements
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Measurement & Measurement Systems:
Introduction, Definition, Basic requirements, Methods of measurement. Generalized
measurement system, fundamental & Derived units, Standards of measurements.
4
2. Statistical treatment of data and static characteristics:
Definition-Accuracy, Precision, sensitivity, Error, Result, True value. Hysterics,
Mean & Standard deviation, Variance, Median, Mode. Calibration & its importance,
Classification of errors. Treatment of Single & Multi sample data by uncertainty
analysis.
9
3. Dynamic Characteristics of Measurement Systems:
Types of input signals, System Response, Measurement [First order control system],
Wave forms, Harmonic Analysis, Relation between sensitivity and period.
6
4. Transducers
Classification of transducers, Transfer efficiency, Variable-resistance, inductance and
Capacitive transducers, LVDT, Piezoelectric transducer, Electronic transducer,
Photo-Voltaic, emissive & conductive transducers. Relative merits & demerits of
Mechanical and Electrical Transducers
6
5. Intermediate Modifying Devices
38
Mechanical devices, Simple current sensitive circuit, Ballast circuit, Voltage dividing
& balancing circuit, Resistance & Impedance bridges.
6
6. Terminating Devices
Different types of meter indicators, VTVM, CRO, Oscillographs, X-Y Plotters,
Vibrometer & Accelerometer.
5
UNIT II
7. Measurement of Count & Frequency:
EPUT Meter, Time interval meter, Mechanical counters, Stroboscope, Measurements
of frequency & Phase by using Lissajous diagrams.
6
8. Measurement of Strain:
Types of strain gauges, Selection and installation, Gauge factor, Temperature
Compensation, Configuration for measuring tensile and bending strains & Stresses.
6
9. Measurement of Force, Torque & Power:
Proving Ring, Load Cell, Absorption & Transmission dynamometers.
4
10. Measurement of Pressure, Flow & Temperature:
MC lead gauge, Pirani gauge, Diaphragm and Bellows, Bourdon pressure gauge. Rota
meter, Magnetic flow meter, Turbine meter, Rotating disc meter. Bimetallic
thermometers, Resistance thermometer, Thermisters, Thermocouples, Thermopiles,
Pyrometers.
4
39
11. Linear Measurements:
Gauge Blocks, Dial gauge, Bevel protractors, Sine bar, Planimeter, Tool room
microscope, Profile projector, use of Auto collimator, Straightness testing. Principle
of Interferometry-otical flats, NPL flatness interferometer, Measurement of surface
roughness.
5
Books for Reference:
1. Mechanical Measurement - Beckwith & Buck, Roy.D.Marangoni, John.H.Lienhard.
2. Experimental methods for engineers - J.P.Hollman
3. Engineering Measurements - Deoblin
4. Engineering Measurements - Collet & Hope.
5. Mechanical Measurements - Sirohi & Radhakrishna.
6. Mechanical Measurements - RK Jain
7. Engineering Metrology - RK Jain
8. Engineering Metrology - IC Guptha
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any Five Full questions choosing at least Two questions from each
unit.
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 503 Machine Design – I
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. The meaning of Mechanical Engineering Design – the phases of design – design
considerations – codes and standards – factor of safety – review of stress analysis. Design
for static loading – stress concentration – Failure theories 10 Hrs
2. Design for variable loading – Fatigue limit and fatigue strength – Fluctuating stress –
combination of loading modes – Cumulative fatigue damage – Design of Impact loading.
15 Hrs
40
3. Design of shafts of circular section – Crankshafts – connecting rods – power screws
15 Hrs
UNIT II
4. Design of Mechanical joints – Couplings – Rigid & Flexible Couplings – Keys –
Splines – cotter joints- Knuckle joints – Bolted joints – Riveted joints – Welded joints –
Interference joints.
10 Hrs
5. Design of disk & cone clutches – centrifugal clutch – brake design – block brake -
internal expanding brake – band brake – simple and different band brakes.
10 Hrs
Books for reference:
1) Mechanical Engineering Design – Joseph Shigley and Charles – Mischke, Mc Graw
Hill international
2) Machine Design – P.C. Sharma, D.K. Kataria & Sons
3) Machine Design Data Hand Book (Dr. Lingaiah)
REFERENCE:
1) Design of Machine elements – M.F. Spots
2) Machine Design – Paul H Black and Adams Jr.
Scheme of Examination:
Note: USE OF DESIGN DATA HAND BOOK IS PERMITTED IN THE
EXAMINATION.
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 504 Manufacturing Technology – I
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
41
UNIT I
1. Introduction to metal cutting and machine tools, mechanics of chip formation,
Types of chips, Determination of shear Angle, Force analysis is metal cutting,
energy considerations in metal cutting, shear angle theories, single point cutting
tool and its designation, Friction in metal cutting problem s.
12
2. Heat generation in metal cutting, temperature distribution in metal cutting,
measurement of temperature in metal cutting, cutting fluids in metal cutting, Tool
wear, Tool life, Tool materials, Machinability, design of cutting tools – single
point cutting tools and milling cutters problems.
10
3. Jigs and fixtures – Introduction, locating and clamping, Design principles of jigs
and fixtures, Drilling Jigs, milling fixtures problems.
08
UNIT II
4. Un-conventional manufacturing methods. Introduction, classification, Process
description, principle of metal removal process parameters, process capabilities,
applications and limitations of the following unconventional manufacturing
methods.
. Electro Chemical Machining
Ultrasonic Machining
Electric Discharge Machining
Super finishing process - honing, lapping,
15
5. Metrology – Principles of engineering metrology fundamental length standards,
Interferometer, Linear measurements, Comparators, Angular measurements,
Measurement of taper and radius, Geometric features, Limits, fits and tolerances,
surface texture, special measuring machines, Co-ordinate measuring machines,
Digital Metrology, problems.
15
42
Books for References:
1. Fundamentals of metal machining and machines
Geoffery Boothroyd pub: McGraw Hill Book company
2. Manufacturing Science – Amitabha Ghosh and A.K. Malik
Pub: Affiliated East west press Pvt Ltd, New Delhi
3. A text book of Production Engineering – P.C. Sharma, Pub S. Chand & Company
4. Engineering Metrology - I.C Gupta Pub: Dhanpat Rai & Sons
5. Tool and Manufacturing Engineering Hand Book - ASTME
6. Dimensional Metrology – Khare and Bajpa
7. Modern Machining Processes – Pandey PC, Pub: Tata Mc Graw Hill. Co.1993.
8. Non Traditional Machining Processes – Wellar, SME, Michigan 1984.
9. New Technology – Bhattacharya, B.E. Publisher, 1984.
10. Automation, Production Systems and Computer Integrated Manufacturing –
Mikell P. Groover, P & I Publishers.
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
43
V SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 505 Applied Thermodynamics – II
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Properties of steam:
Steam generation - Enthalpy, Entropy and internal energy of steam - steam tables and
charts - vapour processes - Determination of dryness fraction problems
6
2. Steam Nozzles:
Expansion of steam through nozzles - optimum pressure ratio for maximum discharge -
determination of cycles area of throat and exit - concepts of super saturation flow of
steam.
8
3.Steam Turbines:
Principle of operation of steam turbines - Types of steam turbines - The simple impulse
steam turbine - Reaction turbine - Velocity diagrams for impulse and reaction turbines -
Power developed in turbines - Diagram efficiency - Stage efficiency - improvement of
steam turbine efficiency - concept of reheat cycle, Regenerative cycle and Binary
vapour cycle - Governing of steam turbines- problem.
8
4. Steam condensers:
The function of a condenser - Types of condensers - Comparison of condensers –
Condenser Vacuum and measurement - mass of cooling water required - Sources of air
leakage, its effect and removal - Vacuum efficiency - Condenser efficiency - Cooling
ponds and towers.
8
UNIT II
44
5. Refrigeration:
Introduction - Application of refrigeration - Performance of a refrigerator (COP) - Units
of refrigeration - The reverse cannot cycle - The reversed Brayton or Bell Coleman air
cycle - Air refrigeration system - Vapour compression refrigeration system - Methods to
improve simple refrigeration system - Properties of a good refrigerant – Vapour
absorption refrigeration System – COP interms of operating temperatures of vapour
absorption refrigeration system - Electrolux refrigeration system - Steam jet
refrigeration system – Non conventional refrigeration systems - Thermoelectric
refrigeration - Pulse tube refrigeration - Vortex tube refrigeration - Concept of low
temperature refrigeration.
12
6. Air Conditioning:
Summer air conditioning & winter air conditioning, equipments used for air conditioning
systems.
8
Introduction to psychrometry, terms involved in air conditioning - Psychrometric chart -
Psyctrometric processes - Concept of comfort air conditioning - Cooling loads affecting
air conditioning- problems
10
Book of Reference:
1. Thermal Engineering by R.K. Rajput
2. Thermal Engineering by A.S. Sarao
3. Engineering Thermodynamics by Kothandanamam & Co
4. Thermodynamics by R Yadav.
5. Thermodynamics an engineering approach – Yunus . A. Cengel & (SI Units) Michacl
A. Boles (Tata Mc Graw – Hill 4th
Edition 2005 Print)
Scheme of Examination:
Use of thermodynamic tables charts permitted in the examination.
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
45
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 506 CAD Laboratory – I
Class: 3 Hrs / week Internal Assessment Marks:
25
Examination: 3 Hrs Max marks for Examination:
100
1 Exercises using AUTOCAD Inventor package to create assembly drawing & 3D
models.
2 Solid modeling and surface modeling using CATIA/Pro- Engineer.
Scheme:
(i) Exercises using AutoCAD inventor = 30 Marks
(ii) Exercises using CATIA/Pro-Engineering = 30 Marks
(iii) Viva-voce Exam = 20 Marks
46
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 507 Machine Shop-II
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
General Instructions: Process sheets and Inspection sheets are to be prepared for each
model.
1. Detailed study of the following machine tools with regard to their construction,
Operation and controls (i)Milling Machine (ii) Electro chemical Machining Setup
(iii) Ultrasonic Machining setup (iv) Electric Discharge Machining setup.
2. Two models using a Milling Machine involving production of flat surfaces &
gears.
47
3. Measurement of Shear angle in orthogonal cutting, cutting forces, power in
milling and drilling operations.
4. ONE model using Electric Discharge Machining setup.
5. ONE model using Ultrasonic Machining setup.
6. ONE model using Electro chemical Machining setup.
Scheme: (i) One model of exercises 2 or 3 = 40 Marks
(ii) One model of exercises 4 or 5 or 6 = 40 Marks
(iii) Viva-voce = 20 Marks
V SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 508 Measurement & Metrology Laboratory
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
PART A
1. MEASUREMENTS:
48
i. Determination of elastic constants using strain gauges from the following
experiment: A constant stress cantilever beam subjected to a concentrated end
load.
ii. Determination of gauge factor and cross sensitivity of a given strain gauge.
iii. Calibration of load cell and pressure gauge with strain gauge.
iv. Calibration of LVDT and study of characteristics of LVDT.
v. To study the amplitude and the frequency of unknown wave forms using CRO.
Study of Lissajous diagrams for studying frequency and phase relations.
vi. Determination of time constant of first order system such as thermocouple.
vii. Calibration of thermocouple using resistance thermometer.
viii. Use of pyrometers Total radiation and optical pyrometers.
ix. Use of stroboscope for measurement of rotational speeds.
x. Vibration of displacement, velocity & acceleration measurement using vibration
pick-ups.
xi. Measurement of sound pressure level using sound level meter, obtaining SPL
spectrum at different frequencies.
PART B
2. METROLOGY:
i. Measurement of Surface Finish.
ii. Measurement of angle (Sine Bar)
iii. Measurement of center distance b/w holes
iv. Measurement of internal and external taper.
v. Measurement of pitch and profile errors of threads and gears.
vi. Use of comparators.
vii. Measurement of radius of components.
Viii Measurement of form
Scheme: (i) One experiment from Part A = 40 Marks
(ii) One experiment from Part B = 40 Marks
(iii) Viva-voce = 20 Marks
VI SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 601 Object Oriented Programming
49
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Basic Introduction of C++ Language: Characteristics of OOPs, Preprocessor
directives, C++ data types, pointer types, string types, reference types, enumerations
types, array types, Const def names, new and delete expressions, type conversion.
6
2. Functions: Defining a function, function arguments, default arguments, constant
arguments, pass by value, pass by reference, inline functions, functions overloading.
6
3. Class and Objects : Specifying class, defining member functions, private member
functions, memory allocation for objects, static data members, static member
functions, array of objects, objects as function arguments, friend functions, returning
objects, pointers to members, constructors, constructor overloading, dynamic
initialization of objects, copy constructors, destructors.
12
4. Inheritance and Polymorphism: Derived Classes and Base Classes, multilevel
inheritance, multiple inheritance, hierarchical inheritance, hybrid inheritance, virtual
base class, abstract classes, pointers to objects, this points, virtual functions.
6
UNIT II
5. Operator overloading and type conversion: Introduction, defining operator
overloading, unary and binary operator, overloading binary operators using friends,
rules of overloading operators.
8
6. Data Structures: Stacks, Queues and Linked Lists
10
7. Algorithms: Notions of algorithms, fundamentals of algorithm problem solving,
important problem types, fundamental data structures, algorithm design strategies:
BRUTE FORCE and DIVIDE and CONQUER
12
Books for References:
1. Object Oriented programs in Turbo C++ Robert Lafore
2. Object Oriented programs in Turbo C++ by Balaguruswamy
50
3. Data Structures using C and C++ by Yeadidyah Langson, Noshe J Augenstein and
M Tanenbaum
4. Computer Algorithms by Horowitz E, Sahani S and Rajashekaran S
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
VI SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 602 Industrial Management
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. INTRODUCTION :
Brief history of management movement-contribution by pioneers Functions of
management. Functions and principles of Management.
6
2.ORGANIZATION:
Principles of organization, types of organization. Developments in organization-system
approach to organization, Management of change-Management of conflict. MBO,
Management by exception.
6
3.INDUSTRIAL OWNERSHIP-
Types of ownership. Methods of raising capital, incorporation of joint stock company.
6
4. PERSONNEL MANAGEMENT:
Function of personnel management recruitment, selection and training wages and
salary administration, incentive wage payment.
6
5.INDUSTRIAL PSYCHOLOGY AND HUMAN RELATION:
Motivation: Theories of human motivation. Mass/ lows hierarchy of needs, group
dynamics, theory x & y , Howthrone Experiments.
6
51
UNIT II
6. INDUSTRIAL RELATIONS:
Trade Union movement in India,. Machinery for settlement of disputes handling of
individual grievances, work of ILO.
6
7. FACTORY LEGISLATION IN INDIA:
Important provision of factories act, Payment of wages Act, Workmen’s
compensation Act, ESI Act, Environmental regulations.
8. INDUSTRIAL SAFETY :
Safety devices, duties of safety engineer, Tracking and prevention of accidents,
occupational diseases.
3
9. WORK STUDY:
Introduction, Work-study procedures Human Considerations In work study concepts
of work content, work study as a tool to improve productivity
4
10. Method Study: objectives steps in method study recording techniques, micro motion
study, and principal of motion economy
4
11. Work measurement, objectives techniques of work measurement time study
equipment, computation of standard time, work sampling predetermined motion time
analysis.
4
12 Value Engineering Definition, value analysis steps in value analysis principal of value
analysis.
4
13 PURCHASING : Functions & Procedure.
2
14 FUNCTION OF SALES MANAGEMENT;
Market research, sales promotion and distribution.
3
Books for Refernce:
1. Principle of Management - Koontz & O’Donnel
2. Modern Production Management - Buffa
3. Personnel Administration - Pogors & Mayers
52
4. Management of Organizational Behaviour - Hersey & Blanchard
5. Industrial Relations in India - K. Subramanaian.
6. Management - Stonel / Freemen / Gilbert
7. Industrial Engineering and production Management of Material Telsang
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
VI SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 603 Machine Design –II
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT - I
1. FLY WHEELS:
Analysis and Design of flywheel for engines and punch press, consideration of
stresses in rims and arms.
6
2. FLEXIBLE MACHINE ELEMENTS:
Design and selection of flexible machine elements.
53
Belt Drives- design of belt drives – calculation of the length of the belt, Number of
piles and width of the belt – standard, flat and V-belt sections, V Belts-cross
section-section procedure of V belts- pulley details for both flat and V belts-Ribbed
V belts.
8
Rope Drives- design and application of rope drives,wire ropes and pulleys-elevator
and hoists-fatigue life of wire ropes.
5
Chain drives- selection procedure of transimission chains and sprockets for various
application-link chains and pulleys-silent chains.
5
3. DESIGN OF SPRINGS:
Springs-Types of springs-leaf,-helical,-disc and concentric torsion springs-Uses of
springs- Belleville springs,-Helical spring of different cross sections- combination
of springs. Design of helical spring-compression and tension,-fatigue surge
elimination-design of leaf springs.
6
UNIT -II
4. DESIGN OF BEARINGS
Types of bearing, lubrication and types of sliding lubrication.
4
Properties of oil and equation of flow: Introduction, viscosity, the Hagen –
poiseuille law, flow between parallel stationery planes, viscosity - temperature
relationship. Influence of pressure on viscosity and density – problems.
Hydrostatic lubrication: Introduction, Hydrostatic step bearings, Hydro static
journal bearings, and pivoted pad thrust bearings, oil lifts – problems.
4
Rolling contact bearings: Types of rolling contact bearings- applications-
selection based on dynamic capacity, equation and different reliabilities, selection
for variable loads and speeds- Radial bearing; Axial bearing-selection of bearing-
Deep groove ball bearing, roller bearings, angular contact bearings.
4
5. DESIGN OF GEARS:
Spur and helical gears:
Introduction to transmission elements-positive drivers and friction drives; gear
drives-standard modules and various proportions-design of spur and helical gears
54
based on contact stress and beam strength – based on Lewis and Buckingham
equation, dynamic effects- check for wear and endurance strength-Gear Materials.
10
Bevel and worm gears:
Bevel gears-Nomenclature-design based on contact strength and beam strength-based
on Lewis and Buckingham. Worm and worm wheel-Nomenclature-design
procedure- efficiency and thermal considerations in worm gears.
Introduction to Multi-speed Gear Box and Speed Reducers.
8
Text Books:
1. Joseph Edward Shigley & Charles, R. Mischke, “Mechanical Engineering Design”.
McGraw Hill International Edition, 2000
2. S.G. Kulakarni, “Machine Design – solved problems “Tata McGraw Hill Publishing
Company Ltd., 1998.
3. William orthein, “Machine Component Design(vol.I & II)”, M/s.Jaico publishing
1998-99.
4. T.V.Sundarajamoorthy and N.Shanmugum, “Machine design”, Khanna
Publishers,Delhi-6.
Books for Refernce:
1. Gitan M. Maitra & L.N. Prasad, “Hand Book of Mechanical Design”, Tata McGraw
Hill 1985.
2. V.B. Bhandari, “Design of Machine Elements”, Tata McGraw Hill Publishing
Company Ltd, 1998.
3. Prabhu T.J., “Fundamentals of Machine Design”, Madras Book House, Chennai.
4. Panday and Shah “Machine Design”.
5. Design Data Books.
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
55
VI SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 604: Manufacturing Technology – II
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Casting patterns:
Types of patterns and their brief description, pattern allowance. Functions of
patterns.
2
2. Sand moulding process and materials:
Essential features of a sand mould. Description of green sand moulding. Dry-sand
moulding core-sand moulding process. Working of moulding machine-Squeezers,
Jolting machines. Jolt-Squeeze machine, slingers, Blowers and their combinations.
Composition and properties of Moulding sands and core sands.
5
3. Melting practice:
Melting Furnaces: Crucible furnaces, lift-out types, stationary and tilting type, oil fired
furnaces, Induction furnaces, Cupola.
5
4. Special molding and casting processes:
Shell molding, investment casting. Permanent mould casting, centrifugal. Pressure
die casting.
4
5. Casting defects:
Causes and remedies.
2
6. Cleaning operation of castings, inspection.
2
UNIT II
7. Powder metallurgy :
Principles of Powder metallurgy techniques, brief description of methods. Production
of metal powders, Conditioning and blending of powders. Compaction and Sintery
methods. Application of Powder metallurgy components.
6
56
8. Welding:
Principles and practice of following welding process. Manual metal arc. TIG, MIG, /
MAJ Submerged arc welding.
4
Friction welding, Gas welding, Resistance welding. Welding.
4
9. Metallurgical aspects:
Structure of welds, Heat Affected Zone, shrinkage and residual stresses in welds,
weldability of cast Iron, Low alloy steels, Copper, Aluminium.
4
Welding defects, inspection and control.
2
UNIT III
10 Classification of metal working processes
Advantages and limitations of wrought products. Effect pf temperature, strain rate and
friction on metal working. Effects of residual stresses.
4
11 Bulk Forming Processes:
(1) Forging: Process description, Types of forging machines, Forging operations., Open
& closed die forging, Forging die design; Defects in forgings
4
(2) Rolling : Process description, Rolling mills, conditions for rolling, max, possible
reduction, effects of Back & Front Tension, Rolling pressure, Deffects in rolled products
(3) Drawing: Drawing process, Die design, die materials, Drawing machine, Effects of
die cone angle on Drawing forces, Defects in drawn products.
2
(4) Extrusion: Types of extrusion, Extrusion products, metal flow in extrusion,
Hydraulic extrusion, Impact extrusion, defects in extended products
2
Sheet metal processes:
(1) Sheet Metal Forming: dies & Tools: Simple, compound, progressive Dies, Types of
presses shearing forces calculation, clearance in shearing.
2
(2) Deep Drawing: Process description , stresses & deformation in deep drawn cup, Deep
drawability, defect in deep draw cup.
2
Books for References:
1. Principles of Metal Casting by Heine and Rosenthal.
57
2. Welding Hand Book.
3. Science and Practice of Welding by Davis.
4. Welding Technology by O.P. Khanna.
5. Foundry Technology by Beely Butterworth.
6. Cupola and its Operations, AFS Publications.
7. Material and Process in Manufacturing ( Eight Edition) E. Paul Degarmo, J. T. Blace,
Ronald A Kohser. PHT.
8. Manufacturing Engineering & Technology, ( Third Edition ) Kalpakjian, Addision
Wesley Publisher.
9. Manufacturing Process & System (Ninth Edition ) Philip F Oswald, Jiaro Munoz
John Willey & Sons.
10. Foundry Engineering; Taylor, Flemings, Wulff
11. Principles of welding Technology; L.M. Gourd
12. Modern Arc welding Technology; S.V Nadakarni
13. Welding Technology by N.K. Srinivasan
14. Mechanical metallurgy – Dieter. Tata Mc Graw Hill Publications
Scheme of Examination:
Examiners to set a total of eight questions as follows:
Three questions each from Units I and II
Two questions from Unit III
Students are to answer a total of five questions, choosing at least one from each
VI SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 605 Heat And Mass Transfer
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. INTRODUCTION: Units, definitions, basic modes of heat transfer, Thermal
conductivity for various types of materials, connective heat transfer co-efficient,
Stefan Boltzmann’s Law of Thermal radiation.
5
2. CONDUCTION: Three dimensional general heat conduction equation in Cartesian
co-ordinates, one dimensional steady state heat conduction without heat generation.
Though plane slabs, cylinders and spheres, concept of Thermal resistance, electrical
analogy, heat transfer through composite slabs, cylinders and spheres, contact
resistance, combined conduction and convection. Overall heat transfer co-efficient
58
variable Thermal conductivity, critical thickness of insulation for cylinder and sphere.
8
3. HEAT TRANSFER FROM EXTENDED SURFACES:
Straight fin of rectangular and circular and insulated end open, effectiveness of pin.
Errores of Measurement of Temperature using Thermometers pockets.
6
4. ONE DIMENSIONAL TRANSIENT CONDUCTION:
Conduction in solids with negligible internal temperature tridents (humped system
analysis) use of transient temperature charts for transient conduction in slabs, long
cylinder and sphere: use of transient temperature charts for transident conduction in
semi infinite solids.
6
5. CONVECTION HEAT TRANSFER:
Dimensional analysis, Buckingham Ti Theorem, application to free and forced
convection, physical significance of Reynolds, prandtl Nusselt and Stanton numbers
numerical problems.
5
UNIT II
6. HEAT EXCHANGERS:
Classification of heat exchangers, Heat changers effectiveness and LMTD for parallel
and counter flows, Falling and falling factor, significance of NTU.
9
7. BOILING AND CONDENSATION:
Regimes of pool boiling, pool boiling correlations, Types of condensation:
NUSSETT’S Theory for laminar condensation on a vertical flat surface, expression
for film thickness and heat transfer co-efficient: Use of correlations for condensation
on horizontal tube and horizontal tube banks: Reynolds number for condensate flow.
4
8. RADIATION HEAT TRANSFER:
Thermal radiation; definitions of various terms used in radiation heat transfer, Stefan-
Boltzmann law, Kirchhoff’s Law, Plank’s Law and Wien’s displacement Law,
Radiation heat exchange between two parallel infinite black surfaces, between two
parallel infinite gray surfaces.
Effect of radiation shield: Intensive of radiation and solid angle: Lumber Law:
Radiation heat exchange between two finite surfaces.
10
59
9. MASS TRANSFER:
Definitions of terms used in mass transfer analysis; Flick’s first law; Steady state
equimolar counter diffusion in gases; Steady state unidirectional in gases; steady state
unidirectional in gases; steady state diffusion in liquids, Schmidt Number, Sherwood
Number.
7
Books for Reference:
1. Heat transfer a practical approaches by YUNUS A CENGEL, Tata MC Graw Hill
2002.
2. Fundamentals of Heat and mass transfer, Frankkrith, Incropera, Wiley and Sons
4th
ed. 1995.
3. Heat transfer – A basic approach, Necats Osisik, MC Graw Hill International ed.
1988.
4. R.K. Hegde & Niranjan Murthy, Heat and Mass transfer, Sapna Publications,
Bangalore.
5. R.K. Hegde & Niranjan Murthy, Heat and Mass Transfer Data Hand Book Sapna
Publications, Bangalore.
6. R.K. Rajput, Heat and Mass transfer.
7. D.S. Kumar, Heat and Mass transfer.
8. Domakundawar, Heat and Mass transfer.
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
VI SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 606 Design Laboratory – I
60
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. To draw the displacement, velocity and acceleration curves for a slider-
crank mechanism
2. To study motion of the follower for the given cam and to determine the
displacement, velocity and acceleration at every point (cam analysis)
3. To study the variation of input torque with respect to the out put torque on
a four bar mechanism and to find the mechanical advantage.
4. To determine the coefficient of friction, slip and creep in belt.
5. Determination of Gyroscopic couple
UNIT II
6. Determination of natural frequency, damping ratio and damping
coefficient in a longitudinal vibrations system.
7. Determination of natural frequency, damping ratio and damping
coefficient in a torsion vibration systems.
8. Determination of critical speed of a rotating shaft (whirling of shaft)
9. Static balancing of masses
10. Balancing of rotating masses
11. Determination of equilibrium speed, sensitiveness power and effort of
porter governor.
Books for References:
1. Theory of Machines – Shigley & Vichel
2. Theory of Machines – Ballany
3. Theory of Machines – Sadhu singh
4. Fundamentals of mechanical vibrations – S. Graham Kelley
5. Theory & practice of Mechanical vibrations – J.S Rao & K. G Gutpta.
Scheme of Examination:
One question from Unit I 40 Marks
One question from Unit II 40 Marks
Viva – voce 20 Marks
61
VI SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 607 Manufacturing Technology Laboratory
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. EXPERIMENTS ON SAND TESTING:
i. Determination of Grain Fineness Number.
ii. Determination of Clay content.
iii. Effect of Moisture content and clay content on Permeability
number.
iv. Compression, shear, strength & their effects with moisture and
clay variation.
v. Effect of binder content on Bending & Tensile strength.
vi. Core gas Analysis.
vii. Friability Index.
UNIT II
2. Molding, Melting and Casting of ferrous and non ferrous metals in Green sand mould,
CO2 Mould & Shell mould. Measurement of fluidity of molten metal.
3. Observing microstructure of cast ferrous and non – ferrous metals
Books for Reference:
1. Principles of Metal Casting by Heine and Rosenthal.
Scheme of Examination:
One question from Unit I 30 marks
One question from Unit II 50 marks
Viva Voce 20 marks
62
VI SEMESTER B.E. (MECHANICAL ENGINEERING)
2K6 ME 608: CAD Laboratory –II
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
I. Programs on
1. Functions
2. Classes and objects
3. Inheritance
4. Operator Overloading
5. Stacks
6. Queues
7. Linked Lists
II. Exercises using Unigraphics Package.
Scheme of Examination
1. Exercises using Programming - 50 Marks
2. Exercises using Unigraphics - 30 Marks
3. Viva-voce - 20 Marks
63
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 701 Finite Element Analysis
Class: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT - I
1. Introduction:
Basic Concepts: Stresses, Strains, Compatibility conditions, Boundary conditions,
Stress–Strain relations, Temperature effects, Potential Energy and Equilibrium,
Rayleigh Ritz Method, Galerkin’s method.
7
Standard Discrete System Finite elements of an elastic continuum.
Flexibility and Stiffness approach of structural analysis. Generation of the finite
element concept. Weighted Residuals and Variation approaches. Element types:
triangular, rectangular, quadrilateral, Sector, curved.
8
2. Element Properties:
Displacement models, relation between the nodal degrees of freedom and generalized co-ordinates, convergence requirements, Natural co-ordinate systems, Shape functions(Interpolation functions).Element Strains and Stresses. Element stiffness matrix, Static Condensation. Isoparametric Elements, Numerical Integration. 10
UNIT - II
3. One Dimensional problems, Plane Truss, Space Truss, Assembly of Global Stiffness
Matrix for the Banded and Skyline solution. Two dimensional problems using
64
Constant Strain Triangle(CST),Linear Strain Triangle(LST).
8
4. Axisymmetric problems:
Axisymmetric Formulation, finite element modeling: Triangular element
6
5. Beams and frames:
Finite element Formulation, Load vector, Boundary Conditions, Shear force and
bending moment, beams on elastic support, plane frames.2D and 3D beam elements.
6
6. Three dimensional problems in stress analysis.
Finite element formulation, stress calculation, Mesh properties, Hexahedral elements
and higher order elements. 7
7. Introduction to the use of FEM in steady state field problems- Heat conduction,
fluid flow and non linear material problems, Plasticity, creep etc. Computer procedure for
finite element analysis. 8
Books for References:
1. Introduction to Finite Elements in Engineering- Tirupathi Chandrupatla,
Ashok D.Belegundi(P H I).
2. Finite Element Methods-Zienckeiwicz
3. Finite Element Methods-Abel and Desai
SCHEME OF EXAMINATION:
Examiner to set three questions from Unit – I and 5 questions from Unit – II.
Students should answer 2 full questions from Unit – I and 3 full questions from Unit – II.
65
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 702 Operation Research
Lecture : 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT - I
1. Managerial Decisions, decisions under Certainty and Decisions Under Uncertainty,
Development of O.R. Definitions and essential characteristics of O.R Phases of O.R
scope of O.R. Advantages and limitation of O.R.
5
2. Linear programming problems, Formulation, and application, concepts of solution
space, convex regions, basic feasible solution, by Graphical method, simplex method,
Big M method Degeneracy in L.P.P.
10
3. Theory of Duality, Dual simplex method.
5
66
4. Transportation problems-Finding initial BFS using NW corner method, Matrix
Minima method and VAM.Opstimal Solution by Modi method. Degenerate and
unbalanced Transportation problems. Assignment problem-solution by Hungarian
method, Traveling Salesman problems.
10
UNIT - II
5. Sequencing problems-Johnson’s algorithm, n jobs 2 machines, n jobs 3 machines, 2
jobs n machines.
5
6. Replacement Analysis: Causes for replacement and types of replacement problems,
Items deteriorating with Time, Items with sudden Failure.
5
7. PERT/CPM: Introduction to Network planning, construction of activity on arrow
diagrams. Determination critical path computation of slack/float. Differences between
PERT AND CPM. Determination of probability of completion of a project crashing
of networks and Determination of lowest cost schedule and minimum length
schedule. 10
8. Queuing Theory: Queuing system, Terminology and characteristic Analysis of
(m/m/1): (/FIFO) and (m/m/k): (/FIFO) queues. Applications of queuing theory.
5
9. Introduction to game theory, 2 persons Zero sum games, game with saddle point and
games with mixed strategies. Graphical Solutions to Games. Solution of Games using
Dominance rules.
5
Books for References:
1. Introduction to Operations Research - Hiller.F.S & Lieberman.G.S
2. Operations Research - Kanti Swarup, Gupta & Manmohan
3. Operations Research - S.D. Sharma
4. Operations Research - Hira & Gupta
Scheme of examination :
Examiners to set four questions from each of the units.
67
Students to answer five full questions taking at least two questions from each
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 703: Energy Resources and Utilization
68
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT-I
1. Introduction to Energy sources: Energy sources and their availability, Conventional
and non-conventional energy source, prospects of non-conventional energy sources.
2
2. Solar energy: Solar radiation and its measurements: Solar radiation geometry, Solar
radiation, measurements, solar radiation data, average solar radiation, solar radiation
on a tilted surface.
2
3. Solar collectors: Principle f conversion of solar energy to heat. Flat plate
collectors- Configuration, basic energy balance equation, general characteristics,
overall heat transfer coefficient, collector performance, absorbers, selective coating.
4
4. Concentrating collectors: Types comparison between flat plate and concentrating
collectors, general characteristics.
4
5. Solar energy storage: Storage systems, thermal, electrical, chemical, mechanical,
electromagnetic, solar pond.
2
6. Solar energy applications: Solar water heating, space heating, space cooling, solar
thermal electric conversion, solar electric power generation, agriculture and industrial
process heat, distillation, pumping, solar furnace, solar green houses, hydrogen
generation. Numerical problems.
6
7. Wind energy: Introduction. Principles of energy conversion, wind data and energy
estimation, site selection, basic components of the system, classification, advantages
and disadvantages of wind energy conversion system.
5
Design consideration of horizontal axis machines, vertical axis machines,
performance of wind machines using basic power expression, wind energy storage,
application of wind energy system. Numerical problems.
5
69
UNIT-II
8. Energy from bio-mass: Bio-mass conversion, bio-gas generation, factors affecting
the gas generation, classification of bio-gas plants, relative, advantages and
disadvantages.
4
9. Constructional details of KVIC and Janata model, community bio gas plants, raw
materials used, digester design, fuel properties of bio gas, utilization of bio gas,
energy plantation, bio mass gasification, classification of gasifiers, application of the
gasifiers . Numerical problems.
4
10. Nuclear Energy: Fission and Fusion reaction, salient features of a nuclear reactor,
types of reactors, boiling water reactors, pressurized water reactor, liquid metal
cooled, gas cooled. CANDU reactors, nuclear power plants.
6
11. Environmental impact of energy conversion: Pollution from thermal, chemical,
nuclear energy conversion devices.
8
12. Concepts of energy conversion from geothermal, OTEC, ideal fuel cells and
batteries, thermoelectric power, thermionic generation, MHD generation.
8
Books for Reference:
Principles of Energy Conversion- Archie W Culp
Non conventional Energy sources – G.D. Rai
Solar energy –S.P. Sukhatme
Non Conventional Energy source- G.D. Rai
Power plant engineering- E.L Wakil
Non Conventional Energy sources – G.D. Rai
Power plant engineering – E.L Wakil
Non Conventional Energy sources- G.D. Rai
Scheme of Examination:
Examiner to set four questions from each Unit.
Students are to answer any five full questions choosing at least two questions from each
unit.
70
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 704: Machine Design – III
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT – I
1. COMPUTER AIDED DESIGN
Introduction-procedures in CAD, creating the manufacturing database, hardware in
Cad, Functions of graphic package, surface and solid modeling, methods of
construction, Commercial cad packages, graphic software.
5
2. OPTIMUM DESIGN OF MECHANCIAL ELEMENTS
Introduction to optimum design, methods of optimization, Johnson method of
optimum design, normal specification, redundant specification, optimum design with
lagrngian Multipliers method, Differential calculus method, secant method, genetic
algorithm, multi variable method, linear programming method problems.
12
3. MECHANICS OF COMPOSITE MATERIALS
71
Introduction to composites and types, mechanical beheaviour of composite materials,
Orthotropic materials, strength of a laminate, calculation of ABD matrix, strength
theories, classical lamination theory, strain and stress variation in laminae, design of a
laminate, laminate joints, reinforcement at an arbitrary angle, interlaminar stresses,
Environmental effects, problems.
13
UNIT – II
4. INTRODUCTION TO SYSTEM DESIGN
Introduction to system and visual design, principles of system design, factors
affecting system design, procedure in system design, element of visual design,
Principles of visual design, case studies, safety in design, risk factor and
Management. 5
5. FRACTURE MECHANICS
Modes of fracture, grifth’s analysis, energy release rate(Gi), stress intensity
factor(Ki). Relation between Gi and Ki, crack resistance, stable and unstable crack
growth, stress in cracks, thin and thick plates, fracture toughness, application of
fracture mechanics to Composite material, application of principle of superposition,
internal pressure on cracked faces, types of cracks, J. integral, introduction to test
methods, initial stress intensity factor test, load-displacement technique, measuring
crack length, determination of critical crack tip opening displacement problems.
13
6. Design of pressure vessels, thick and thin cylinders, two and four speed gear box.
12
Books for Reference:
1. Robert M Jones, Mechanics of composite material, McGraw-Hill Ltd., 1995.
2. Prashant Kumar, Element of fracture mechanics, wheeler publishing-1999.
3. K. Lingaiah, Machine design data hand book, Suma publisher – 1984.
4. Robert Norton, Machine design and integrated approach, Prentice Hall, 2nd
Edition.
Scheme of examination :
Examiners to set four questions from each unit.
Students are to answer five full questions choosing at least two questions from each unit.
72
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 706: Simulation Laboratory
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. Simulation of tool path for producing components using CNC lathe.
2. Simulation of tool path for producing components using CNC milling machine.
3. Computer Simulation and experiments of electro pneumatic circuits involving
PLC.
4. Computer Simulation and experiments of electro hydraulic circuits involving
PLC.
5. Computer Simulation of CNC machines (2 axes, 3 axes, 4 axes, 5 axes) and
kinetic mechanisms using suitable packages.
73
6. Use of FEM packages for analysis of engineering components.
Note: The details of the relevant theory for conducting above experiments are to be
covered during laboratory hours.
Scheme of examination:
Two experiments of 40 marks each and viva-voce is for 20 marks.
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 707: Design Laboratory – II
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT- I
I. Photo Elasticity Experiments:
Calibration of photoelastic model material by using circular disc under diametrical
compression.
74
Calibration of photoelastic model material by using a beam subjected to pure
bending.
Determination of stress concentration factor in a plate with circular hole under
tension.
Determination of contact stress and sub surface shear stress in a circular cutout
subjected to uniaxial tensile load.
Determination of stress concentration factor in plate with circular cutout under
transverse bending.
II. Strain Gauge Experiments:
Determination of stress concentration factors in a plate with a circular cut out under
uniaxial tensile load using strain gauges.
Determination of magnitudes and directions of a principal stress, principal strain,
maximum shear stress and maximum shear strain using strain rosettes.
Study of Pressure distribution and coefficient of friction in journal bearing.
Study of pressure distribution and coefficient of friction in slider bearing.
Study of wear resistance of engineering materials using pin on disc apparatus.
experiments on four ball tester for testing lubricating oil.
UNIT- II
III. Study of Finite Element Analysis package (ANSYS)
Static Finite Element Analysis of:
i) Bars, Trusses and Beams.
ii) Plane Stress and Plain Strain problems.
iii) Axis – Symmetric Problems.
iv) Solids (3 – Dimensional)
v) Simple problems on one-dimensional heat transfer.
Books for Reference:
1. Experimental stress Analysis – L.S. Srinath, M.R. Raghavan, K. Lingaiah,
i. G. Ganesha, K. Ramachandra and B. Pant.
2. Experimental stress Analysis – Dally and Riley.
3. Lubrication of Bearings by Radzimovsky.
4. Principles and applications of Tribology by Moore.
5. Strain Gauge by primer.
6. Introduction to FEM – T. Chandrupatla. And Belagundu
Scheme for Examination:
One experiment in Unit I 40
One experiment in Unit II 40
Viva-voce 20
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 708 Heat Transfer And IC Engines Laboratory
75
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Valve timing diagram for IC Engines and analysis of flue gases by Orsat apparatus
Performance test (using Rope Brake Dynmometer, Hydraulic Dynmometer, electrical
loading) on the following IC Engines:
1) 4 – Stroke petrol engine
2) 2- Stroke petrol engine
3) 4- stroke diesel engine
4) 2 – stroke Diesel engine
2. Performance test on variable compression engine.
Study of combustion in SI & CI engines using pressure-crank Angle diagram
Effect of Air-fuel Ratio on the performance of SI & CI engines.
Effect of Back pressure on the performance of IC Engines.
Morse test on a multicylinder IC engine
Performance test on single & two stage Air compressors
Performance test on Air blower.
Determination of
i) Carbon Residue
ii) Moisture content in a fuel
iii) Cloud & pour point
iv) Grease penetration test
3. Performance test on Refrigerator and Air conditioner
UNIT II
1. Determination of thermal conductivity of metal rod, insulating material and liquid
2. Determination thermal conductivity of composite walls.
3. Determination of heat transfer coefficient for free convection from a cylinder
4. Determination of heat transfer coefficient for forced flow through tubes.
5. Determination of heat transfer and effectiveness of a fin.
6. Determination of emissivity of a surface.
7. Determination of LMTD & effectiveness of parallel and counter flow heat
exchangers.
8. To study the boiling & condensation phenomenon
9. Verification of Stefan – Boltzman constant.
Scheme for Examination:
The examination should comprise ONE Experiment on Unit I and ONE
Experiment on Unit II together for 80 marks, followed by viva –voce for 20
marks.
76
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 705.A Entrepreneurship Development
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. SCOPE AND CHARACTERISTICS OF ENTERPRNEURSHIP: Special schemes
for Entrepreneurs, exposure to demand based, service based, import substitute and export
promotion industries. Identification of opportunities.
8
2. TUTIONS, FINANCING PROCEDURE AND FINANCIAL INCENTIVES:
Financial ratios and their significance, books of accounts, statements and fund flow
analysis. 8
3. ENERGY REQUIREMENT & UTILISATION: Resource management, persons,
machine and materials, critical path method (CPM)- projection review techniques
(PERT) as planning tools for establishing SSI.
10.
4.TECHNO-ECONOMIC FEASIBILITY OF THE PROJECT: Plant layout and
process planning for the product, quality control/quality enhance and testing the product,
costing and pricing.
8
5.ELEMENTS OF MARKETING & SALES MANAGEMENT: Nature of product
and market strategy, packing and advertising, after sales social responsibility and
business ethics.
8 6.IMPORTANT PROVISIONS OF FACTORY ACT: Sales of good
act, partnership act, Income Tax, Sales Tax and Excise rules, Licensing, tration, Muncipal
bye laws and insurance coverage.
8 7.POLLUTION CONTROL, CREATIVITY AND
INNOVATION: Problem solving approach, strength weakness opportunity and threat
(SWOT) techniques, management of self and understanding human behaviour, coping
with uncertainties, stress management and positive reinforcement.
10
Text Book:
77
Prasanna Chandra, “Project – Preparation, Appraisal and Implementation”, Tata McGraw
Hill, New Delhi, 1990.
Books for Reference:
1.Philip Kotler, “Marketing Management”, Prentice Hall, 1990.
2. Prasanna Chandra, “Fundamentals of Financial Management”,TataMcGrawHill,
Publication, 1995.
Scheme of Examination:
Number of questions to be set =8
Number of questions to be answered =5
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 705.B Electronics Manufacturing Processes
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. Introduction: Important components of Electronic products. Types of Semiconductor
materials and their properties.
6
2. Manufacturing ICs: The functions of ICs manufacturing of diodes. Production of a
singal I component classification of Ic Architecture.
6
3. Manufacturing of Silicon Wafer: Fabrication of IC on Silicon wafers.
Fabrication of IC on Silicon wafers. Diffusion doping, Ion implantation, Rapid
thermal processing- Thermal oxidation Monolithic processing.
Lithography, Photolithography,Etching processes
10
4. Thin film Deposition: Physical Vapour Deposition, chemical vapor deposition,
Epitoxial growth, IC component interconnection, IC yield and economics
6
5. IC packaging. Types of packaging: Packaging process
6
6. Printed Circuit Boards: Typical substrate (base) Materials and selection o substrate
materials. Types of PCBs. Methods of manufacturing of PCBs.
8
7. Electronic Assembly
78
General Description of Electronic Assembly detailed study of sequences of operation
for through-hole and surface mount process
6
8. Micro Electro-Mechanical systems
(a) Introduction to micro electronics, Micro sensors MEMS, micro machines
fundamentals of Silicon micro machining – Bulk & surface micromachining. Micro
stereo lithography.
4
(b) Micro sensors: Types & brief description and applications of Thermal, Radiation,
Mechanical, Magnetic, Bio-chemical sensors
4
( c) Smart sensors & MEMS Devices
4
Books for Reference:
1. E. Paul Degarmo, JT Black and Ronald A Kohser: Materials and processes in
manufacturing. Wiley student Edition 2004
2. Minger ML: Electronics materials handbook Vol 1. Packaging ASM
3. Jarger RC: introduction to micro electronic Fabrication. Addision-Wesley 1990
4. Cambell A: The science and Engineering of micro electronics Oxford University press
2001.
5. Pierset RF: Semiconductor fundamentals Addisor-Wisley, Reading mass.1988
6. CA Harper & RM Sampson: Electronic materials & processes Handbook 2nd
Edition
Mc Graw Hill 1994.
Scheme of Examination:
Number of questions to be set =8
Number of questions to be answered =5
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME705.C Automobile Engineering
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT – I
1. Automotive Engines:
Introduction to Engine, Engine classification, SI & CI engines, cylinder-arrangements
and their relative merits, liners, piston- materials and design features, connecting rod,
crankshaft, camshaft, cylinder heads, valves, valve actuating mechanisms, valve and
port timing diagrams, types of combustion chambers for S.I Engine and C.I Engines,
compression ratio, intake and exhaust system, choice of materials for different engine
79
components, engine positioning, engine diagnostics, evaluating the engine’s
condition.
10
2. Engine Lubrication and cooling system:
Lubrication, oil types, lubricating systems, oil pump. Cooling systems, cooling
requirements , liquid – cooled system-coolant, water pump, radiator, thermostat,
water jackets, oil cooler, Air – cooled system.
5
3. Fuels, fuel supply systems:
Conventional fuels, alternative fuels, fuel performance, basic fuel additives, fuel
mixture requirements for SI Engines, Carburetors – basic carburetor design, types of
carburetors, Fuel injection systems – multipoint and single point, EFI, TBI, CPI, GDI,
CIS, Fuel delivery system- fuel transfer pumps, fuel filters, fuel injection pumps and
injectors.
10
4. Ignition systems:
Purpose of the ignition system, Ignition timing, Ignition components, Battery Ignition
systems, Magneto Ignition system, Electronic Ignition system, spark timing,
Automatic Ignition advance systems.
5
UNIT – II
5. Transmission:
Clutches- Single plate, multi-plate and centrifugal clutches, Gear box- Necessity in
transmission, gear shift mechanisms, sliding mesh, constant mesh, synchromesh gear
boxes – 3,4 & 5 speed, Planetry gear system, over drives, fluid coupling, torque
convertors, Epicyclic gear box, principle of automatic transmission.
Drive to wheels- propeller shaft and universal joints, Hotchkiss and Torque tube
drives, differential rear axle, different arrangements of fixing the wheels to rear axle.
10
6. Suspension and Steering systems:
Tyres – Types of tyres, cornering, properties of tyre, causes and types of tyre wear,
slip angle and cornering force, tyre dynamics, tyre repair.
Suspension systems – requirements, suspension system components, torsion bar
suspension systems, leaf spring, coil springs, shock absorbers, Semi-independent,
80
Independent suspension systems, Air suspension system, Electronically controlled
suspension systems, Active suspension system.
Steering systems- Theory of steering mechanism, general arrangements of steering
system, steering geometry, camber, King pin inclination, included angle, castor, toein
and toeout, Manual-steering systems, Power–steering systems, Electronically
controlled power- steering systems, general arrangements of links and stub axle, over
steer under steer and neutral steer. Wheel alignment – Alignment geometry, wheel
alignment equipment, four – wheel drive vehicle alignment.
10
7. Brakes:
Friction, types of brakes, Mechanical, Air, Vacuum and Hydraulic braking systems.
Construction and working of master and wheel cylinder, Hydraulic tubes and hoses,
Drum brakes, Disc brakes, Brake shoes and lining, Antilock Brake systems (ABS) –
components types, operation, Automatic traction control, Automatic stability control
6
8. Modern development in Automotives:
Alternative fuels for Automotive traction, electric cars, Hybrid cars, Automotive
exhaust emissions, control measures, Euro norms, Safety and Comfort features-
Restraint systems, Air bags, Automotive heating systems, Air-condition systems,
security and Antitheft devices. On-Board Diagnostic (OBD).
4
9. General maintenance of an automobile – fault tracing – repairs.
Books for Reference:
1. Automotive mechanics – Crouse
2. Automotive Mechanisms – Srigham
3. Motor vehicle – Newton and steeds
4. Automotive Mechanisms – S. Srinivasan
5. Automobile Engineers – K.K. Jain and R.B. Arshana
6. Automotive Technology –Jack Erjavec
7. Automotive Engineer’s Reference book – Melloj and Lenehestor.
8. Automobile Engineering – R.B. Gupta
9. Automobile Engineering – Narang.
10. Automotive mechanics- Joseph Heithner
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
81
VII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 705D Advanced Trends in Manufacturing
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Rapid response manufacturing:
Rapid proto typing-Introduction, subtractive process, additive process, virtual
prototyping, Rapid Tooling, Basic concepts in free form fabrication. Photopolymer
based FF process, Deposition based FF processes, powder based FF processes,
Lamination based FF process, Economic consideration.
15
2. Quality Aspects & Quality Engineering:
Introduction – Determining process capability- Inspection & Quality control –
Determining causes for problems in quality - QC Tool, & techniques – Automated
Inspection. 10
3. Machine vision & its application:
Machine vision – Senior classification – Tactile service visual sensing, sensor fusion –
flexible fixturing.
5
UNIT II
4. Trends in automation:
Just in time, Advantages of I I T, Application of I I T KANBAN system, single minute
exchange of Dies ((SMED) - POKA- YOKE ( Fool proofing), Group Technology,
Advantages of GT, classification & coding of parts, coding system
10
5. Optimisation in manufacturing
Integrated manufacturing system design: Production - Methodology for
implementation manufacturing cell design – programming of manufacturing cell
design – elements of Artificial Intelligence – structure of expert system- Natural
language processing Artificial Neural Networks fusses logic .
10
6. Design for assembly, Dis assembly & service:
Stages in the design for any analysis- Automated assembly, selective any –
synchronous systems, non synchronous systems & continuous system- Guidelines for
design for any diss any service.
10
82
Books for References:
1 .E. Paul Degarmo, J.J. Black and Ronald A. Kosher – “ Materials and Processes in
manufacturing” John Wisely & sons.
2. Mikell P. Groover – Automation, Production Systems and Computer Integrated
Manufacturing”, PHE Pulbishers.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer 5 full questions choosing at least 2 from each Unit.
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 705E: Experimental Stress Analysis
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT –I
1. Introduction: Mechanical, Optical, Pneumatic, Acoustic methods of Strain
Measurement
6
2. Electrical Resistance Strain Gauges-Gauge factor types, properties of an ideal
gauge material, backing material, Adhesive material, protective coatings;
Methods of bonding strain gauges, strain gauges lead wire and connections,
semiconductor strain gauges, Problems
6
3. Strain Gauge Circuits Wheatstone Bridge, error due to input impedance of
measuring instrument, temperature compensation, multiple gauge circuits,
calibration of strain measuring system, load cells, problems
6
4. Strain Gauge Rosette- Necessity analysis, problems
6
5. Photoelasticity – Nature of light- Harmonic wave, Phase amplitude polarization
6
UNIT-II
83
6. Crystal optics-Passage-Passage of light through crystalline media, Absolute and
relative phase difference, Quarter wave plate, half wave plate, production plane
polarized light.
6
7. Two dimensional photo elasticity- Stress optical law , plane Polariscope,
isochromatics, isoclinics and isochromatics fringe order at a point, methods of
compensation separation techniques, Problems.
6
8. Practice- Calibration of photo elastic model, material, properties of ideal
photoelastic model material, casting of photo elastic models, machining, stress
relieving, scaling model prototype relation, two dimensional application,
problems.
6
9. Birefringent coating, theory, reflection polariscope.
6
10. More Techniques, Phenomenon, Moire fringe analysis, Geometric approach
displacement approach, Moire techniques for inplane problems, Sign and order of
fringes problems of Moire gratings, Moire fringe photography
6
Books for Reference:
1. Experimental Stress Analysis – L.S Srinath M.R Raghavan, K.Lingaiah. G.
Gargesha, K. Ramachandra and B. Pant.
2. Experimental stress Analysis- Dally and Riley
3. Photo Mechanics-A.J Durelli
4. Theoretical and applied Stress Analysis- Durelli Philips and Tsno
5. Moire Analysis of strain- Durrelli and Parks
6. Photo Elasticity Volume 1 & 2 – Max M Frocht
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
84
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 705F: Foundry Technology
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT-I
1. Synthetic sands- Role of addition on properties –testing of sands
6
2. Patterns-different types-pattern allowances.
6
3. Sand Moulding-Machine Moulding-CO2 sands-Resin based no bake sand.
6
85
4. Die casting-centrifugal casting-Investment casting solidification of pure metal and
alloy.
6
5. Melting Practice of cast iron, steel, Aluminium, Magnesium.
6
UNIT-II
6. Gating and risering of cast metals- method of calculating risers –Method of
improving
Yield
10
7. Common casting defects and remedial measures.
5
8. NDT Methods
10
9. Foundry Mechanisation- Layouts of modern foundries.
5
Books for Reference:
Principles of Metal casting – Heine, Looper & Rosenthal
Foundry Engineering-Taylor, Flemmings & Wulff
Fundamentals in the Production & Design of Casting –C.T. Merck
Foundry Technology – Mukherjee.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
86
VII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 705G Environmental Engineering
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT-I
1. Air Pollution:
Sources Pollutants, global implications, classification of pollutants, particulates,
Hydrocarbons Oxides of sulphur & Nitrogen, Photochemical Oxidants, Indoor air
pollution.
8
2. Metrology and Natural purification processes:
Elemental properties of the atmosphere scales of motion, Heat pressure, Wind,
Moisture and relative humidity.
Influence of Meteorological phenomena on air quality.
Laps rate and dispersion pressure systems and air dispersion, winds and
dispersion.Moisture and dispersion, Modeling.
12
3. Engineering systems for Air Pollution control Atmospheric cleaning
processes, Approaches to contaminant control. Gravitational Settling chambers,
centrifugal collectors. Wet collectors falanic filters, Electrostatic precipitators.
Control devices for gaseous contaminates. Absorption, condensation,
combustion, Automotive Emission control.
10
UNIT-II
4. Noise Pollution:
Sources, Causes, limits of sound control
6
5. Solid Waste Pollution:
Sources and types – municipal, Industrial and hazardous Wastes. Properties,
Physical, Chemical of the above waste. Reuse of solid waste materials, materials
recovery energy recovery.
Collection-Types, determination of vehicle, and labour requirements, collection
routes, mechanical Volume reduction, Thermal volume reduction, Manual
Component separation.
87
Ultimate disposal-Land filling, deep – well injections.
12
6. Thermal Waste Pollution:
Sources and types – Solids (Ash et.) and liquid properties effects on atmosphere
property and human health remedial measures. Effect on steams.
6
7. Nuclear Waste Pollution:
Types and sources – Abatement procedures, controlling measures.
6
Books for Reference:
a. Environmental Engineering by Howard S. Peavy, Donald R. Rowe &
George
Techbobongolons. Mc. Graw Hill International Editions (1987)
b. Air Pollution Hand Book by Magill PL, F.R. Holder & C. Ackley, Mc
Graw Hill.
c. Solid Wastes: Engineering Principles and Management issues.
d. Air Pollution, h.C. Perkins, Mc Graw Hill, New York,
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit
88
VII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 705H Gas Dynamics and Propulsion
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Concepts from thermodynamics – System State Variables, process- reversible and
irreversible, perfect gases. Continuity, momentum and energy equations
Stagnation conditions. Speed of sound and Mach number.
10
2. One dimensional gas dynamics. Isentropic flow with variation of area. Mass flow
and Mach number- Area relation. Nozzles and diffusers. Constant area flow with
friction- Fanno line. Constant area with heating or cooling –Rayleigh line.
Reference states.
10
3. Shocks-normal and oblique. Occurrence of shocks. Relations for normal shocks.
Shock strength, Rankine-Hugoniot relations. Oblique shock deflection angle,
shock separation. Pandit-Mayer expansion.
10
89
UNIT II
4. Propulsion systems. Newton’s laws of motion and momentum theorem.
Classifications of propulsion engines for different speed ranges. Power and
efficiency.
10
5. Jet engines- Turbojet and Ramjet engines. Thrust equation, specific thrust,
thermal and overall efficiencies. Static performance and flight performance. Fuel
(Numerical problems in all the above sections)
10
6. Rocket engines. General principles, thrust equation. Criterion for performance.
Design parameters- Combustion Chambers and nozzles. Solid and liquid
propellants and combustion theory. Electric and ion propulsion.
10
Books for Reference:
1. Fundamentals of Compressible Flows-S.M. Yahya
2. Gas Dynamics and Jet Propulsion-S.L. Somasundaram
3. Gas Turbenies and Jet Propulsion- Khafuria and Dubey
4. Elements of Gas Dynamics- Liepmann and Roshko
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit
B.E VII SEMESTER MECHANICAL ENGINEERING
2K6ME 705.I Smart Materials and Structures
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Overview of smart materials, structures and product technologies.
1
2. Smart materials: Piezoelectric materials, electro- and magnetic – strictive materials,
magneto electric materials, magnetosheological fluids, electrisheological fluids, shape
90
memory materials, fiber optic sensors.
10
3. Smart sensor, Actuator and transducers smart sensors: Accelerometers, force sensors,
load cells, Torque sensors, pressure sensors etc smart actuators: Displacement
actuators, force actuators, power actuators, vibration dampers
Smart Transducers: Ultrosonic transducers, Sonic transducers, air transducers.
15
UNIT II
4. Beam modeling with induced strain actuation simple model, Dual actuators, uniform
strain beam model, Bernoounts- Euler Beam model (Symmetric and asymmetric
induced strain actuation) Embedded actuators. Extension-bending – torsion model.
12
5. Plate modeling without induced strain actuation and with induced strain actuation
Single layer composite plates
Multi layer composite plates
Antisymmetric laminates
12
6. Shape memory alloys for actuation of structural elements
10
References: (i) Smart Materials & Structures by Srinivasan
(ii) Smart Structures by Bran Culshaw
(iii) Piezoelectricity by Cady
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit
VII SEMESTER B.E.(MECHANICAL ENGINEERING)
91
2K6 ME 705J Financial Management and Costing
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT - I
1. Preview of Organization: Organizational Goals, types of decisions, benefits and costs
relevant to operating and capacity decisions.
11
2. Financial Accounting
Book keeping: Double entry accounting, journal and ledger posting
4
3. Financial statements and analysis
Trial balance, preparation of trading account and profit and loss account, balance
sheet, funds flow statement and ratio analysis
15
4. Product costing
Production costs, non production costs, Product costing with absorption and variable
costing.
5
5. Variable job order and process costing system
Element of cost, job costing, process costing.
5
UNIT - II
6. Variable standard costing for efficiency : Types of standard costs, setting of standards,
variable standard cost system, standard cost variance, selection of standard cost
system.
10
7. Cost and Production decisions : Contribution margin and Production decisions -
adding a new product, sell or process further - make or buy decision , dropping the
product line, optimum product mix.
5
92
8. Budgeting: Planning and control process, master budget - Profit plan, cash budget,
capital expenditure budget, development of a master budget - sales forecast, cost
behavior patterns. product cost, company objectives, sales budgets, production
budget, raw materials, purchasing budget, factory cost budget, selling and
administrative expense budget, profit plan , projected cash budget.
10
9. Responsibility Accounting and Budgetary Control : Responsibility accounting - cost
centers profit or contributions centers. Responsibility planning , accounting and
control process.
5
Books for Reference:
1. Management accounting - Wiley international, Don T December, Elton L Schafer,
Marie T Ziegler, IV edition , 1988
2. Managerial Accounting - Garrison, BPI
3. Management accounting - Horn Gren PHI
4. Advanced Accounting - J.R. Batliboi, The standard accountance publications Pvt.
LTD
5. Financial Management & Costing - Khan and Jain, TMH
6. Management Accounting and costing books SYN.Ltd
Scheme of examination :
Examiners to set four questions from each unit.
Students are to answer five full questions choosing at least two questions from each unit.
93
VIII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 801: Production and Operation Management
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Introduction to POM : Historical evolution of POM, The system concept, system
efficiencies and effectiveness, Decision making for POM systems, Role of models,
The internal & External environment of POM. Concepts of production and the
measurement.
5
2. Designing of the POM systems ; Output design, Materials & Processing
considerations, design specifications and tolerances, standardization &
interchangeability, Human engineering.
5
3. Facility design : Layout types, Functional & product types layouts, Fixed position
layout, Cellar layouts, Line balancing, New manufacturing methods, Problems.
5
94
4. Operation standards and work measurements : Job design, production and operations
standards, work measurement techniques.
5
5. Capacity planning : Capacity planning decisions, capacity planning models, Decision
tree analysis and Break-even analysis, Problems.
5
6. Location analysis : Location factors, Industrial plant locations, Models for single
facility and multifacility locations, Transportation model, simple median model
problems.
5
UNIT II
7. Forecasting : Requirements of forecasting for operations, categories of forecasting
methods, moving averaging method, Exponential smoothing with trend and
seasonality, forecasting errors, Regression analysis, Delphi method, Problems
6
8. Aggregate planning : Aggregate planning costs, the goals of aggregate planning,
stratergies for developing aggregate planning, mathematical models, aggregate
planning by Linear programming approach (Transportation model) problems.
6
9. Inventory control : Inventory types, Inventory costs, ABC’s of Inventory, EOQ
models with and without shortage, Production Inventory model, Inventory model with
price break, problems.
6
10. Operation Scheduling : Job shop scheduling, scheduling for batches, high volume
continuos systems, scheduling for service systems.
6
11. Materials requirement planning: Planning for material needs, capacity planning,
Limitations and advantages of MRP, Manufacturing Resource Planning (MRP-II),
Just-In-Time (J I T) manufacturing.
6
Books for Reference:
1. Production and operation management by Ever etc E Adam& RJEBERT
2. Modern Production Operation Management By ES BUFFA
95
3. Operation Management Joseph G.Marks
4. Production & Operation Management by S.N.Chary.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit
VIII SEMESTER B.E. MECHANICAL ENGINEERING
2K6 ME 802 Total Quality Management
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
96
1. Introduction - TQM - The TQ Maxioms - Consequences of total Quality - Costs of
total Quality - Tools for quality.
2
2. The Deeming approach to management - Historical background - Deming’s 14
principles - Implementing Deming’s Philosophy.
2
3. Juran’s approach to Quality - Developing quality - Quality triology - universal
breakthrough sequence
2
4. Crosby’s approach to Quality - Diagnosis of a troubles company- Quality vaccine -
Absolutes for quality management - Fourteen steps for quality improvement
management.
2
5. The concept of kaizen - kaizen & innovation - Kaizen Management practices.
2
6. Technical tools for quality - Techniques for general use - Bar chart - Brain storming -
Cause and effect analysis - control charts - cost benefit analysis-customer supplier
relationship checklist - pareto analysis - quality costing - quality function deployment
( QFD)
10
7. Technical tools for quality - Techniques for only quality control - Introduction - Data
collection plan - variable control chart ( X & R) Process capability studies -
Attributes control chart ( t & P, C & U charts) - interpreting the control charts and
their applications - case studies and problems
10
UNIT II
8. Aspects of. Specification and tolerance statistical tolerancing, precision
predictability and accuracy. Probability distributions problems
10
9. Acceptance sampling fundamental concepts distribution discret continuous
distribution terms OC curves - AQL, LTPD, AOQL Sampling plans, - Single, &
Double Sampling plans, & Sampling multiple plans.
10
97
10. Reliability – Definition – MTBF Failure rate and reliability, calculation - reliability
improvement, redundancy, element, unit and stand by redundancy.
5
ISO 9000 - “Brief introduction.”
5
Books for Reference:
1. Managing for total quality - from Deeming to taguchi’s & SPC -N. Logothetis, PHI-
EEE.
2. Statistical Quality Control - Eugene L, Grant and Richard S. Leaven worth Mc. Graw
Hill.
TQM and ISO 14000 - Dr. K.C. Arora, S.K. Kataria & Sons
3. Total Quality Management - Hohn S. Oakland, Heinmann Professional Publishing.
4.
Scheme of examination:
Examiners to set Four questions from each unit.
Students are to answer five questions choosing at least two questions from each unit.
98
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 803 CAD/CAM and Robotics
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Introduction to CAD/CAM, Manufacturing data base, Application of CAD/CAM,
Types of automation, reasons for automation, Types of Production & functions in
Manufacturing, Organization and Information Processing in manufacturing CIM,
plant layout, Production concepts & Mathematical models, Automation strategies,
Problems.
7
2. NC, CNC and DNC – working of NC/CNC machines, classification, Design features
of CNC machine tool, Machining centre, training centre, Axes definition of NC
systems, Part Programming – C & M codes, APT language, DNC – configuration,
types, advantages, Adaptive control, problems.
8
3. Group Technology, Cellular Manufacturing and Computer Aided Process Planning –
approaches, parts classification and cooling. Production floor cellular manufacturing,
quantitative analysis in cellular manufacturing. Approaches for computer aided
process planning.
7
4. Discrete control using programmable logic controllers, PLC components, operating
cycle, ladder logic diagrams, timers and controls, problems.
4
99
5. Auto mated material handling systems – functions, types, analysis, design,
conveyance and AGV systems, Automated storage systems performances
components, analysis problems
8
UNIT II
6. Robotics Technology – Definition, Anatomy, Robot Control Systems, Resolution
Accuracy & Repeatability, Specification, Problems.
4
7. Classification and Structure of Robotic systems, Point to Point and continuous path
systems, Control loops of Robotic systems, The manufacturers – cartison, cylindrical,
spherical, Articultured or jointed, and SCARA. Drives and Control Systems
Problems.
6
8. Kinematic Analysis and coordinate Transformation – Direct & Indirect Kinematics
Problems. Geometry based direct Kinematic Analysis coordinate & vecor
transformations using materials, Denavit – Hartenberg convention, problems.
6
9. Robot end effectors – Grippers & Tools, Mechanical & Other types of grippers.
Robot Programming, Sensors in Robotics, Robot applications, problems.
2
Books for Reference:
1. Automation, Production Systems and Computer Intergrated Manufacturing – Mikell
P. Groover pub: PMI, New Delhi (1997).
2. CAD/CAM : Computer Aided Design and Manufacturing – Groover MP AND EW
ZIMMERS Jr., Pub: Prentice Hall, Inc. NJ.(1984).
3. Industrial Robotics: Technology, Programming & Applications – Mikell P.Groover,
Mitchell Weiss, etal. Pub: Mc Grow Hill International Ed. (1988).
4. Robotics for Engineers – Yoran Koren. Pub: McGrow Hill International
Editions(1987).
5. Numercial Control Machines and Computer Aided Manufacturing.
- Kunder, Tewari, Rao. Pub: Tata McGraw Hill.
6. Systems Approach to Computer Integrated Manufacturing – Nanna Singh Pub: John
Weley & Sons.
7. Robots and Manufacturing Automation – C Ray Aped Pub: john wesly & sons.
Scheme of Examination:
Examiners to set four questions in each Unit.
100
Students are to answer five full questions choosing at least two full questions from each
unit.
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 804 Modern Methods of Manufacturing
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Rapid Prototyping- Introduction, Basic concepts in free form fabrication, photo
polyner based free form process – Solid ground curing, Deposition based FF
process – Fused deposition modeling powder based FF process – S selctive laser
101
sintering soligen & inkjet binder lamination based FF process, Rapid tooling;
economic consideration.
10
2. Non Traditional Machining process – Principle of operation, Process description,
process parameters, process capabilities, limitations, applications of Ion Beam
Machining, Abrasive jet machining, Abrasive flow machining, water jet
machinery. Special machiningg process- Polygonal turning, deep hole drilling and
trepanning, shaped tube electrolytic machining, electro discharge wire cutting,
orbital grinding, high speed machining.
10
3. Micro electronic Manufacturing & Electronic assembly Introduction,
Semiconductors manufacture of Integrated circuit Boards, Silicon wafer, I.C. on
silicon wafer, Thin film deposition – Chemical vapor deposition, Epitaxial
deposition, I.C. component interconnection, I.C. yield and economics, I.C.
packaging types, packaging processes, printed circuit boards, Electronic
assembly. 10
UNIT II
4. Surface treatment, finishing & integrity – mechanical clearing and finishing,
chemical cleaning, coating, vaporized metal coating, clad materials, Texturised
surfaces, coil coated surfaces, coil coated sheets, edge finishing & burns, fatigue
failures associated with surface integrity.
8
5. Advanced forming techniques – HERF, Fine edge blanking, Hydro forming,
Powder metallurgy – Preparation of metal powder, powder testing & evaluation,
Powder mixing & blending, compaction, sintering, hot isostatic pressing,
proportion of p/m products, design of P.M. parts.
8
6. Advanced welding techniques – Electron beam welding, laser beam welding &
cutting, flash welding, welding of plastics, welding related process – surfacing
metallizing.
6
7. Lean manufacturing, Agile manufacturing, flexible manufacturing,
simultaneous/concurrent engineering – basic philosophy & other related issues. 4
8. Use of artificial intelligence/expert system in manufacturing
4
102
Books for Reference:
1. E. Paul Degarmo, J.J. Black and Ronald A. Kosher – “ Materials and Processes in
Manufacturing” John Wisely & sons.
2. Bhattacharya – “New Technology” B.S. publishers
3. Phillip F. Ostwald & Jaiso Munoz, “Manufacturing Processes and systems, John
Wiley & sons.
4. Pandey P.C. – “Non Traditional Machining Processes”, Tata Mc GrawHill
Publishers.
5. Mikell P. Groover – Automation, Production Systems and Computer Integrated
Manufacturing”, PHE Pulbishers.
6. Nanna Singh – System approach to Computer Integrated Design & Manufacturing,
John Wiley & Sons.
7. Andrew Kusaik – Intelligent Manufacturing Systems.
8. Kelpakjian – Manufacturing Engineering & Technology, Addison Wesley
Publsihers.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit
103
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805A Technology for Rural Development
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Necessity for harnessing Science & Technology to wards rural India. An account
of the efforts of some important institutions in this direction. Challenges for
application of S & T in rural areas.
10
2. Technologies to meet the energy needs. Use of locally available materials. Use of
Unconventional (Non Conventional) or sources other than fossil fuels. Case
studies.
10
3. Alternate building technologies and materials. Construction and maintenance of
efficient sanitation systems.
10
UNIT II
4. Efficient management of water. Rain water harvesting, low cost water treatment
plants. Prevention of water pollution in water bodies in rural areas.
10
5. Use of locally available materials and fuels. Case studies.
10
6. Small and medium scale hydroelectric power generation case, studies.
10
Books for Reference:
104
There is no single book in this subject. Teaching material is prepared using technical
papers published in journals.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6ME 805B Mechanisms and Transmission
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Introduction: Review of fundamentals of kinematics, planar, spherical and spatial
mechanisms, analysis, kinematics inversion, Grashof’s law, Mechanical
advantage, coupler curves.
8
2. Kinematic Analysis: Position – Definition, Loop closer equation. The chance
solutions, Algebraic position analysis.
8
3. Velocity –Definition, Instantaneous center of velocity, The Arnold-Kennedy
theorem of three centres, locating instantaneous center of velocity analysis using
instant centres. The angular velocity ration theorem, Freudenstein’s theorem,
Index of merit, centroids.
8
4. Acceleration – Definition Analytical method of acceleration fixed and moving
centroids, inflection points an circle. Euler savary equation. The bubblier
construction, the cubic of stationary curvature.
6
UNIT II
105
5. Synthesis of Mechanisms : Type, number and dimensional synthesis, function
generation, path generation and body guidance, graphical method. Three-position
synthesis, point position reduction,four precision points, overlay method, Cognate
lingages- coupler curve synthesis, Robert-Chebychev theorem Freudensteins
equation and analytical synthesis, Design of six bar mechanisms.
15
6. Transmission: Clutches-purpose-operation- of friction clutches, gear box –
purpose- requirement, ideal transmission, mechanical gear box, sliding, mesh,
constant mesh, and synchromesh. Fluid coupling and torque converter, epicycle
gearing, principles of automatic transmission. Propeller shafts and universal
joints, differentials, rear axle, different arrangements.
15
Books for Reference
1. Theroy of Machines and Mechanics by J E Shigley and J J Vicker, International
student edition Mc Graw Hill.
2. Design of Machinary Mc Graw Hill by Norton R L.
3. Mechanisms and Dynamics of Machinary by Mobic and Reinholtz.
4. Advanced Mechanism Design Analysis and Synthesis, Prentice Hall by Sandor G N
and Erdman A G
5. Automotive Mechanism by Sirgham
6. Autocar handbook by Heitner’
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805 C Failure Analysis and Design
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Fundamental understanding of failures in materials
1. Modes of Mechanical Failure: Definition of Failure Mode – Failure modes
observed in practice – Different Failure modes and their importance in
maintenance.
2. Functions of Failure: Functions and Performance Standards – Functional Failures
– Failure Modes – Failure Effects.
106
3. Failure Consequences: Hidden Failure Consequences – Safety and
Environmental consequences – Operational Consequences – Non-Operational
Consequences. 10
2. Classifications of failure:
Instantaneous Damage and cumulative damage, failure patterns and distributions, failure
data analysis, objective of failure analysis, step by step procedure for metallurgical failure
analysis.
4
3. Ductile and brittle fracture, micro mechanism of fractures, fatigue fracture,
fundamental of crack propagation.
4
4. Corrosion failure, Environment induced fractures.
6
5. Wear failures, fretting failure.High temperature failures.
6
UNIT II
6. Creep and stress ruptures.
6
7. Bearing failures, rolling bearing failure. Gear failures. Failure of friction surfaces.
Seal failures. Shaft failure. Failure of pressure vessels.
6
8. Failure detection methods.
6
9. Failure prevention methods.
4
10. Case studies.
8
Books for Reference:
107
1. K.H.B. Krdonsity, “Models of failure, Springer Vertag -1969.
2. L.F. Pau “Failure Diagnosis and Performance Monitoring”, Marcel Dekker Inc.
3. “Lubrication and wear”, The institution of Mechanical Engineering.
4. H.P. Garg “Industrial Maintenance”.
5. Catagelo and Heiser Wiley “Analyis of Metallurgical Failuress”.
6. L. Engel and H. Klingale Wolfe “An atlas of metal damage”.
7. Failure Analysis & prevention American Society of Metal Hand Book V 10.11 and 17.
Scheme of Examination:
Examiners to set 3 questions in Unit I and five questions in Unit II.
Students are to answer five questions selecting at least one question from Unit I and three
questions from Unit II.
108
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805D Materials Management
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
Unit I
1. Integrated Materials Management
Integrated Materials Management (IMM): Introduction & its need – Purchasing
Management & its importance – Vendor Development & Vendor Management.
10
2. Purchasing Management
Goals of Purchasing – Negotiation – Purchase system price forecasting – Purchasing
under uncertainty – Purchasing of capital equipment - International Purchasing.
10
3. Warehousing & Stores Management
Stores Management – Stores Systems & Procedures - Incoming Materials Control –
Stores accounting & Stock Verification – Obsolete, Surplus & Scrap Management.
10
Unit II
4. Inventory Management
Introduction – Economic Order Quantity – Practical Inventory Systems – Computers
in
IMM.
10
5. Materials Planning & Budgeting
Importance & Definition – Techniques & Guidelines - Budgeting.
10
6. Logistics Management
Importance – Choice of Mode of Transport – Route selection, Rate verification &
Auditing – Lost shipments & Claims.
10
109
Books for References:
1. Materials Management by P. Goplakrishnan and M. Sundaresan, Prentice Hall of India
Pvt. Ltd., New Delhi.
2. Industrial Engineering & Management by O.P. Khanna, Dhanpat Rai Publications.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 805E Turbo Machines
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Introduction: Definition, comparison between turbo machines and positive
displacement machines. Applications displacement machines. Applications of I and
II law of Thermodynamics to turbo machines. Efficiency of turbo machines,
dimensional analysis as applied to turbo machines, performance characteristics the
flow co-efficient and speed ratio co-efficient, power co-efficient and the specific
speed. 6
2. Energy Transfer In Turbomachines: The Euler equation, fluid energy changes,
impulse and reaction, utilization factor for different types of reaction turbines,
condition for maximum utilization factor for impulse and reaction stages. Velocity
triangles for centrifugal and axial compressor stages.
8
3. Steam And Gas Turbines: Impulse staging velocity and pressure compounding
effects of blade and nozzle losses, reaction staging, reheat factor in turbines, radial
equilibrium. General vortex of flow, flow with constant nozzle angle design and fue
vortex flow design for axial flow gas turbines, Estimation of stage performance, lifting
factors in turbine design, cooling of turbine blades.
8
110
4. Hydraulic Turbines: Hydraulic power utilization, classification of hydraulic turbines:
The pelton wheel turbine efficiency and volumetric efficiency, working proportion of
pelton wheel: Francis and deria turbines, velocity triangles and efficiencies, design of
franciss turbine for slow speed, The draft tube, propeller and Kaplan turbine.
8
UNIT II
5. Rotary Fans, Blowers And Compressors: Introduction, centrifugal type vane shape
size and speed of blowers, vane speed and its effects on efficiency and performance
characteristics, actual performance characteristics, surging in blowers and
compressors. The slip co-efficient FAN laws and characteristic centrifugal
compressors and different design. The axial flow compressor, compressor cascade
performance, axial flow compressor performance, preheat in compressor
8
6. Centrifugal And Axial Flow Pumps: The centrifugal pump, some definitions like
suction head, manometric head, power output and efficiencies multi stage centrifugal
pumps axial flow pump.
12
7. Characteristics Of Hydraulic Turbo Machines: Introduction the main characteristics
of pelton wheel, reaction turbines, operating characteristics, efficiency curves,
cavitation in hydraulic machines, cavitation in pumps.
10
Books for Reference:
Shepard, principles of Turbo machinery Cc Millan publishers
Kadambi and Prasad, an introduction to energy conversion, Vol – III Wiley eastern,
1977.
O.E Baije, Turbo machines; Guide design, selection and theory, John Wsiley and sons.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
111
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805F Computational Fluid Dynamics
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. Philosophy of C.F.D.
Computational Fluid Dynamics: Introduction, C.F.D. As a Research Tool, C.F.D.
As a Design Tool, Automobile and Engine Applications, Naval Architecture
Applications, Civil Engineering Applications, Environmental Engineering
112
Applications, Industrial Manufacturing Applications.
12
2. The Governing Equations of Fluid Dyanamics:
Their derivations, a discussion of their Physical meaning and a presentation of forms
particularly suitable to CFD.
12
Models of flow, Finite Control Volume, Infinitesimal Fluid Element, The substantial
Derivative, The Divergence of Velocity: Its Physical meaning, The Continuity
Equation, Four Models and its Comparison, Manipulations, The momentum
equation, The Energy Equation, Equations for Viscous Flow (Navier Stokes
Equation), Equations for Inviscid Flow (Euler Equation Problems).
3. Mathematical Behaviour of P.D.E : The impact on C.F.D. classifications of Quasi-
linaer P.D.E.s, General Method of Determining the classification of (P.D.E), The
partial Differential Equation: The Eigen value Method, General behaviour of
different classes of P.D.E.: Impact on physical and C.F.D., Hyperbolic, Parabolic
and Elliptic Equations.
10
4. Basics of the Numeric.
Introduction to Finite Differences, Difference Equations, Explicit and Implicit
approaches; Definitions and Contrasts.
10
5. Grids with Appropriate Transformations
General Transformation of the equations, Matrices and Jacobians, Forms of the
governing equations particularly suited for C.F.D.
08
6. Simple C.F.D. Techniques: The LAX-WENDROFF Technique, MACCDRMACK’S
Technique.
08
References:
1. Computational Fluid Dynamics by John D Anderson J R
2. Numerical Heat Transfer and Fluid Flow
3. Computational Fluid Mechanics and Heat Transfer by ANDERSON, D A TANNEHIL
J C
Scheme of Examination:
Number of questions to be set =8
Number of questions to be answered =5
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805G Computer Aided Engineering
113
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. AN OVERVIEW OF COMPUTER AIDED ENGINEERING: Application of
computers to design, case studies of application of CAD and benefits of
Computers Aided Design. Computer hardware, computer fundamentals,
classification of computers used for design, hardware of PENTIUM and RISC
based graphic workstations. Serial and parallel interfacing, display devices,
graphic input devices, output devices and operating systems, windows 95 and
windows NT. 10
2. PRINCIPLES OF COMPUTER GRAPHICS: Creation of graphic primitives,
graphical input techniques, display transformation in 2-D and 3-D, viewing
transformation, scan conversion, clipping, hidden line elimination, rendering,
shading and animation.
10
3. DESIGN DATA BASE: Concept, objectives, data structures, creation of data
files and accessing data files in application programs and relational database
management systems.
09
4. AUTOMATED DRAFTING: Configuration of a typical drafting package,
layers, enitities, editing, display commands, hatching, dimensioning, text
plotting, script files, DXF and IGES files, blocks, parametric programming,
customization of drafting packages and graphic standards.
09
5. MODELLING: Schemes for representing solid objectives, construction solid
geometry and boundary representation, features of solid modeling packages,
modeling of curves and surfaces, techniques of splining, cubic splines, Bezier
splines, B-splines, non-uniform rational B-splines, sculptured surfaces. Examples
of creation of solid models, interface to drafting, design analysis and NC
programming. 09
6. FINITE ELEMENT ANALYSIS: Introduction, types of analysis, procedure for
finite element analysis – stiffness matrix, solution procedure, details of a finite
element analysis package, model building, post processing and optimization.
08
7. MECHANISMS MODELLING: Inertial data specification, constraints, forces,
generic system, modeling, kinematic and dynamic analysis, post processing and
114
simulation.
05
REFERENCES:
1. CAD/CAM & Practice by IBRAHIM ZEID TMH
2. Mathematical Elements of Computer Graphics, by Roger & Adams
3. Computer Graphics by Hearn & Beker.
4. Introduction to Finite Elements in Engineering- Tirupathi Chandrupatla, Ashok
Belegundi(P H I).
5. Finite Element Methods-Abel and Desai
6 Numerical Control Machines and Computer Aided Manufacturing.Kunder, Tewari,
Rao.
Pub: Tata McGraw Hill.
115
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805H Enterprise Resource Planning
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT – I
1. MANUFACTURING INDUSTRY MANAGEMENT CHARACTERISTICS
AND INFORMATION REQUIREMENTS: Industry classification, product /
market / process characteristics, manufacturing planning cycle, information
planning and control techniques. ERP concept & evolution history: MRP – I,
MRP-II, ERP. Client server technology. RDBMS.
8
2. SALES, PURCHASE AND INVENTORY CONTROL CONCEPTS:
Classification / coding of materials & finished goods, sales enquiry, quotation,
order, invoicing, delivery, finished food valuation, purchase requisition, enquiry,
supplier quotation, purchase order, material receipts. Material issues, methods of
issue valuation (FIFI/LIFO/ Weighted Average cost/ Std. Cost), returns from
operations, returns to suppliers, stock adjustments, physical stock verification,
ABC analysis. Lot and location control, replenishment order control (safety
stocks, reorder point, economic order quantity).
10
3. MANUFACTURING: Aggregate planning-master production scheduling –
capacity requirement planning, bill of material, material requirement planning,
loading and scheduling.
6
UNIT – II
116
4. FINANCIAL AND COST ACCOUNTING: Basic accounting principles day
book-cast book, journal, purchase and sales. Ledgers- general, supplier,
customer, advances etc., trail balance, profit & loss / income & expenditure
account and balance sheet. Fixed assets and depreciation, Budgeting – revenue,
capital, cash, cost elements-direct material, direct labour, direct expenses and
overheads Marginal costing and break even analysis, standard costing, activity
based costing. 10
5. MANUFACTURING MODULE OF Baan: Module architecture – overview
capacity requirement, planning, engineering change control, engineering data
management, master production scheduling, materials requirement planning,
product classification / configuration. Production planning / control.
10
6. DISTRIBUTION MODULE OF BaaN: Module architecture – overview, item
data, purchase ordering / control, sales ordering / control, replenishment order
control, electronic data interchange.
10
Books for Reference:
1. Vollmann T.E. etal. “Manufacturing Planning and Control”, Galgotia Publishers 1998
2. Dilworth J.B. “Operations Management”, McGraw Hill International Edition. 1992
3. Buffa E S., “Modern Production / Operations Management” John Wiley & Sons 1994
4. Prasanna-Chandra, “Fundamentals of Financial Management” Tata McGraw Hill
1994
5. Gopalakrishnan, “Materials Management”. Prentice Hall of India 1994.
6. BaaN Student Manuals, BaaN Education Centre, Hydradab 1996.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
117
VIII SEMESTER B.E. (MECHANICAL ENGINEERING)
2K6 ME 805J Value Engineering
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. An Overview:Definitions, construction management contracts, value engineering
case studies. Definition, value engineering recommendations, programmes,
advantages.
8
2. APPROACH OF FUNCTION: Evaluation of function, determining function,
classifying function, evaluation of costs, evaluation of worth determining worth,
evaluation of value.
8
118
3. VE JOB PLAN: Introduction, orientation,information phase,speculation phase,
analysis phase, development phase – implementation follow up phase.
6
4. SELECTION OF EVALUATION OF VE PROJECTS: Projects selection,
methods selection, value standards, application of ve methodology .
8
UNIT II
5. VERSATILITY A VE PROGRAMME: Introduction training plan, career
development for VE specialists.
8
6. INITIATING A VE PROGRAMME: Introduction, training plan, career
development for VE specialists.
8
7. FAST DIGRAMMING: Cost models, life cycle costs.
6
8. VE LEVEL OF EFFORT: VE team, co-ordinator, designer, different services,
definition, construction management contracts, value engineering case studies.
8
TEXT BOOK:
1. Tufy Herald, G. “Compendium on value Engineering”, The Indo American
society, First Edition 1983.
Books for Reference:
1. Miles, L.D., “ Techniques of Value Engineering and Analysis”, MC Graw Hill,
Second Edition, 1972.
2. Khanna, O.P., “Industrial Engineering and Management” Dhanpat Rai & Sons,
1993.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 805 K Mechatronics
119
Lecture: 4 Hrs / week
Total No. of Hours: 60 Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
UNIT I
1. Introduction - Definition of Mechatronics - Scope of mechatronics
5
2. Sensors and transducers - signal conditioning - Measurement systems.
5
3. Pneumatic, Hydraulic, Mechanical and Electrical actuation systems.
5
4. Basic system models - Engineering systems Rotation / Translational system,
Electromechanical and Hydro mechanical systems.
5
5. Microprocessors - Basic structure - Languages - Instruction sets - problems with basic
mathematical operations.
5
6. Input / Output systems - interfacing - memory mapped system peripheral interface
adapters - poling and interrupts - speed control of motors.
5
UNIT II
7. Programmable logic controllers (PLC’s) - Basic structure - I/O processing - Examples
of PLC’s – Timers, markers and counters - selections of PLC’s for mechanical
engineering applications - Problems using Laddet logic diagram.
10
8. Fault detection techniques - common faults in PLC systems.
5
9. Design and mechatronics - Mechanisms - Examples of design.
5
10. Electronics for mechanical engineers - passive components and active components
used in electronics - Transformers - Silicon controlled rectifiers (SCR) - Integrated
circuits (IC) - Digital circuits.
5
11. CNC systems - Introduction - Configuration of the CNC systems - Interfacing -
Monitoring - Diagnostics - Machine data - Direct numerical control (DNC)
5
Books for Reference:
1. W.BOLTON Mechatronics - Electronic control systems in mechanical engineering -
Awlongman publications, 1996.
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2. MECHATRONICS by HMT LIMITED ,Tata Mc Graw Hill Publishing Co. 1998.
Scheme of Examination:
Examiners are to set four questions from each Unit.
Students are to answer five full questions choosing at least two from each Unit.
VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 806 CAD/CAM & Robotics Laboratory
Class: 3 Hrs / week Internal Assessment Marks: 25
Examination: 3 Hrs Max marks for Examination:
100
1. Production of components using CNC lathe. (Minimum 2)
2. Production of Components using CNC milling machine. (Minimum 2)
3. Computer simulation and programming of robots for pick and place, stacking,
palletizing, assembly, inspection, etc. applications using suitable software and
hardware.
4. Use of Computer vision and interfacing with robots for industrial applications.
5. Computer Simulation of Manufacturing Systems using packages like
ARENA/QUEST or a suitable package.
6. Computer simulation of engineering problems like inventing, queue, segmenting, etc.
Note: The details of the relevant theory for conducting above experiments are to be
covered during laboratory hours.
Experiments to be done in group: Experiment Numbers: 1,2, 3 & 4.
Experiments to be done individually: Experiment Numbers: 5 & 6.
Scheme of Examination:
Two experiments are to be conducted as follows:
1. One experiment comprising of 3 students in a group carrying 50 marks.
2. One experiment to be done individually carrying 30 marks.
3. Viva – voce: 20 marks.
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VIII SEMESTER B.E MECHANICAL ENGINEERING
2K6 ME 807 PROJECT WORK
Class: 6 Hrs / week Internal Assessment Marks: 75
Max marks for Examination:
150
The project work is assigned at the beginning of VII Semester to students in groups of not
more than four students. The project work may be carried out either in the college or in
recognized industries / R&D establishments/National Laboratories.
Project works carried out at commercial tutorial establishments, Continuing Education
Centers and at Software coaching centers are not permitted to submit the project work.
Any repetition of previous project works carried out either in this College or elsewhere
will not be accepted.
When the project work is done outside the college, it should be under the close
supervision of the internal guide (a teaching staff of the Department) and an external
guide from the establishment where the students do the work. In such cases, it is
mandatory to attach a Certificate for having carried out the Project work from the
establishment, where the project was carried out.
At the end of the project work, a report is submitted in a bound from. The internal
assessment is based on the presentation made by each student which is judged by a
Departmental Committee consisting of teaching staff members and the respective guides
as one of the members.
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In the viva voce examination, the project work is assessed by two examiners.