Scheme & Syllabus for V and VI semesters B.E. Mechanical...
Transcript of Scheme & Syllabus for V and VI semesters B.E. Mechanical...
1
Scheme & Syllabus for V and VI semesters B.E. – Mechanical Engineering Academic Year 2015-16
V Semester
Course Code Subject Name L T P C
ME 501 Heat Transfer 3 1 0 4
ME 502 Manufacturing Science - II 4 0 0 4
ME 503 Design of Machine Elements - I 3 1 0 4
ME 504 Measurement Science 3 0 0 3
ME 505 Engineering Economics & Industrial Management 4 0 0 4
ME 506 Principles of CAD & CAM 4 0 0 4
ME 507 Computer Aided Drafting & Modeling Laboratory 0 0 3 1.5
ME 508 Fluid Mechanics & Machinery Laboratory 0 0 2 1
HS 006 Environmental Science (Audit Course) 2 0 0 0
Total Credits 25.5
VI Semester
Course Code Subject Name L T P C
ME 601 Mechanical Vibrations 3 1 0 4
ME 602 Manufacturing Science – III 4 0 0 4
ME 603 Design of Machine Elements - II 3 1 0 4
ME 604 Microprocessors & Mechatronics 4 0 0 4
ME 65X Elective – I 3 0 0 3
ME 66X Elective – II 3 0 0 3
ME 607 Machine Shop 0 0 6 3
ME 608 Fuels & Engine Laboratory 0 0 2 1
HS 004 Communication Skills - II 0 0 3 1.5
HS 005 Constitution of India & Professional Ethics (Audit Course) 2 0 0 0
Total Credits 27.5
* Elective * Elective
ME651 – Casting Technology ME661 - Internal Combustion Engines
ME652 - Theory of Elasticity ME662 -Refrigeration & HVAC Systems
ME653 - Automotive Engineering ME663 - Behavioral Science
ME654 - Computer Graphics ME664 - Artificial Intelligence & Expert System
ME655 - Nanotechnology ME665 - Non Conventional Energy Sources
Prerequisite:
Wherever the term prerequisite has been suggested for any of the courses, the student must have
registered for the prerequisite course(s) and must have fulfilled minimum attendance requirement.
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HEAT TRANSFER
ME501 TPC: 3-1-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Prerequisites:
ME 302, ME 305
Course objective:
The objective of this course is to impart the knowledge of basic principles of heat transfer
and its applications in engineering process design and product development
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) understand laws of heat transfer and energy balance in thermal
engineering systems 1, 4,5, 9, 11
2) acquire the knowledge of systematic approach in solving heat transfer
problems 1, 4, 9
3) design experiments involving different modes of heat transfer 1, 4,9
4) know the concept of transient heat transfer 1, 8, 9
COURSE CONTENTS:
PART – A
Unit – 1 Introductory concepts and definitions: Modes of heat transfer; Basic laws governing
conduction, convection and radiation heat transfer. Conduction-Basic Equations: Derivation of
general form heat conduction equation in rectangular coordinates, heat conduction equation in
cylindrical and spherical coordinates (no derivation). Boundary conditions of conduction
problems. 07 Hrs.
Unit – 2 One dimensional steady state conduction: Steady state conduction in a slab, cylinder
and sphere with and without heat generation, Composite wall, overall heat transfer coefficient,
critical thickness of insulation, conduction in rectangular fins, fin efficiency, fin effectiveness
and problems. 07 Hrs.
PART – B
Unit – 3 One dimensional transient conduction: Transient heat conduction in slab, long
cylinder and sphere: use of transient temperature charts. 07 Hrs.
Unit – 4 Concepts and basic relations in boundary layers: Flow over a body, velocity &
thermal boundary layer: critical Reynolds number, general expression for drag coefficient and
drag force, Nusselt number and problems. 06 Hrs.
3
PART – C
Unit – 5 Forced Convection: Application of dimensional analysis for forced convection
problems. Significance of Reynolds, Prandtl and Nusselt numbers. Flow over a flat plate, over a
cylinder and across a tube bundle. 06 Hrs.
Unit – 6 Free or natural convection: Application of dimensional analysis significance of
Grashoff number; free convection from or to vertical, horizontal and inclined flat plates, vertical
and horizontal cylinders. 06 Hrs.
PART – D
Unit – 7 Condensation and boiling: Types of condensation; Nusselt’s theory, vertical flat
surface film thickness. Regimes of pool boiling correlations.
Heat exchangers: Classification of heat exchangers and LMTD methods, Introduction to NTU
method. 07 Hrs.
Unit – 8 Radiation heat transfer: Definitions, Stefan-Boltzman law, Kirchoff’s law, Plank’s
law and Wein’s displacement law.’ Radiation between two parallel black surfaces, gray
surfaces, radiation shield. 06 Hrs.
TEXT BOOKS:
1. P.K.Nag, Heat & Mass Transfer, TMH, 2008. ISBN:0-07-047337-4
REFERENCE BOOKS:
1. P.S Ghoshdastidar, Heat Transfer, 2nd
Edition, ISBN-10:0-19-807997-4
2. S.P.Sukhatme, Heat transfers, 4th
edition. ISBN:8173715440
3. R.K.Rajputh, Heat & Mass Transfer, S.Chand & Company Ltd, 3rd
Edition, 2006.
ISBN :81-219-1777-8
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MANUFACTURING SCIENCE – II
ME 502 LTPC: 4-0-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Course Objective:
To impart knowledge of principles, technology and recent developments in techniques of
metal joining and forming processes
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course the student shall be able to:
1. understand the application of the different joining techniques, and be able to
select an appropriate technique according to a specific requirement
2, 3
2. learn the principles and operations of different Metal Forming Processes 3, 5
COURSE CONTENTS:
PART – A
Unit – 1 Introduction to Joining processes : Principles of Welding, common sources of heat
for Fusion welding, Electric Arc Structure, Characteristics and Power, Metallurgy of welding –
Weld Metal Solidification, HAZ and microstructure of Weld, Weld cracking, Corrosion of
weld, Residual stresses in welding, Defects in Welding. 07 Hrs.
Unit – 2 Welding: Classification, Electric Arc welding – Arc Welding equipments, Welding
Electrodes–Types, Consumable and Non Consumable, Flux coatings, Types of Welded joints.
06 Hrs.
PART – B
Unit – 3 Welding Processes: Principles and operations of SMAW, TIGW, MIGW, SAW,
Electro-slag Welding, Thermit Welding, AHW and LBW. 07 Hrs.
Unit – 4 Resistance Welding: Principle, Spot, Seam & projection welding, Flash Butt
Welding. Soldering and Brazing. 06 Hrs.
PART – C
Unit – 5 Introduction to Metal Forming: Hot, Cold and Warm working, Nature of plastic
deformation, Plane stress-strain and true stress –strain concepts, Determination of Flow stress.
Tresca and Von Mises yield criteria. Effect of Temperature, strain rate, friction, lubrication and
Hydrostatic pressure in metal forming. Methods of metal deformation analysis. 07 Hrs.
Unit – 6 Forging: Principle, Open and Closed Die forging, Forging operations. Advantages,
Limitations, Applications, and Defects in Forging. 06 Hrs.
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PART – D
Unit – 7 Rolling: Principle, Roll Stand arrangement, Roll passes & Roll Pass sequence.
Expression for Rolling load, power required for Rolling, maximum possible reduction.
Advantages, Limitations, Applications and Defects in Rolling, 06 Hrs.
Unit – 8 Extrusion – Principle, Hot and Cold Extrusion, Hydrostatic Extrusion, Extrusion of
Hollow shapes, Advantages, Limitations and Applications. Rod, Wire and Tube Drawing.
Sheet Metal Forming – Press tool operations, Shearing, Blanking, Bending, Drawing, Spinning,
Stretch Forming, Embossing and Coining operations. 07 Hrs.
TEXT BOOK:
1. P. N. Rao, Manufacturing Technology – Foundry, Forming and Welding, TMH, 3rd
Edition, 2008. ISBN:0-07-463843-2.
REFERENCE:
1. E. Paul Degamo, J. T. Black, Ronald A. Kohser, Materials and Processes in
Manufacturing, PHI, 8th
Edition, 2002. ISBN: 0471033065, 9780471033066.
2. Serope Kalpakjian, Steven R. Schmid, Manufacturing Processes for Engineering
Materials, Pearson Education, 4th
Edition, 2005. ISBN:0132272717, 9780132272711.
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DESIGN OF MACHINE ELEMENTS - I
ME 503 LTPC: 3-1-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Prerequisites:
ME-301, ME 304, ME 306, ME 405
Course objectives:
To introduce the students to apply knowledge of Strength of Materials, Kinematics and
Dynamics of Machinery courses to design machine elements.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) apply basic stress and strain analysis techniques to machine elements 1, 3, 6, 7, 8
2) utilize standard failure theories and fatigue analysis to develop safety
factors for machine elements 1, 3,7
3) to learn to use standard practices in design of machine elements and
standard data 6, 7
4) function effectively within engineering work teams 6, 7, 8, 9
COURSE CONTENTS:
PART – A
Unit – 1 Introduction: Review of definitions - normal, shear, Biaxial and Triaxial Stresses,
Principal Stresses. Design for Static Strength: Theories of failure – Maximum Normal stress
Theory, Maximum Shear stress Theory, Distortion Energy Theory; Brittle and ductile failure.
Stress concentration, Determination of Stress concentration factor.
Design for dynamic loads: Impact loads, Impact strength: Introduction, Impact stress due to
Axial, Bending and Torsional loads, Impact factor. 06 Hrs.
Unit – 2 Design for fatigue loads: Introduction, Fatigue failure, Definition of Low Cycle
Fatigue and High Cycle Fatigue, S-N diagram, Endurance Limit, Correction factors for Load,
Size and surface finish, Fatigue Stress concentration factor, Notch sensitivity, Factors affecting
Fatigue; Goodman and Soderberg relationship. Problems on members subjected to Axial,
Bending, Torsion and combined fatigue loads. Cumulative fatigue. 08 Hrs.
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PART – B
Unit – 3 Design of shafts: Types of shafts, Torsion of shafts. Design for strength and Rigidity
with steady loading. ASME & BIS codes for design of transmission–shafting. Shafts under
Bending, Torsion, Axial, fluctuating loads and combined loads. 08 Hrs.
Unit – 4 Fasteners: Threaded Fasteners: Stresses in Threaded Fasteners. Effect of Initial
Tension, Design of Threaded Fasteners under Static, Dynamic and Impact loads. Eccentrically
loaded bolted Keys: Types of Keys, Selection of square keys. Selection of couplings: Rigid and
Flexible couplings: Flange Coupling, Bush and pin type Coupling. 06 Hrs.
PART –C
Unit – 5 Riveted Joints: Failures of Riveted joints, Design of Boiler joints as per IBR,
Eccentrically loaded riveted joints, Welded Joints – Types, Strength of Butt and Fillet welds,
Eccentrically loaded welded joints. 06 Hrs.
Unit – 6 Power Screws: Mechanics of power screw, stresses in power screw, efficiency and
self-locking, Design of Power Screw. Introduction to Ball screws. 06 Hrs.
PART –D
Unit – 7 Clutches & Brakes: Design of clutches: Single plate and multi plate clutches, cone
clutches, Block and Band brakes. 06 Hrs.
Unit – 8 Design of Flexible Machine Elements: V- Belts, Selection of V-belts, Selection of
wire ropes, selection of roller chains. 06 Hrs.
TEXT BOOK:
1. Maleev & Hartman’s, Machine Design in SI units, 5th
Edition, C B S Publications,
Delhi, 2005. ISBN:9788123906379
REFERENCE BOOKS:
1. M.F. Spotts, T.E. Shoup, L.E. Hornberger, S.R.Jayaram & C.V.Venkatesh, Design
of Machine Elements, Pearson Education, 8th
Edition, 2006. ISBN
9788177584219.
2. Joseph Edward Shigley, Mechanical Engineering Design, Mc. Graw Hill, 8th
Edition, 2008. ISBN:9780073529288.
3. V. B. Bhandari, Design of Machine Elements, TMH, 3rd
Edition, 2007.ISBN:
9780070681748.
Design Data Hand Books:
1. K. Mahadevan and Balaveera Reddy, Design Data Hand Book, C B S Publications,
Delhi. ISBN:9788123901626.
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MEASUREMENT SCIENCE
ME 504 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course objectives:
The objective of this course is to impart knowledge of measuring methods and systems
used in engineering practice.
Course Outcomes (COs){with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) understand operating principles of a range of widely used instrumentation
techniques in mechanical engineering 1,2,5,9
2) recognize the limitations of measurement and measuring devices 1,9
3) identify and apply accepted standard practices for all measurements 1,7,9,6
4) apply concepts of metrology in designing inspection tools 3, 9
COURSE CONTENTS: PART-A
Unit –1- Measurement and Measurement systems: Definition, methods of
measurements, significance of measurement, generalized measurement systems,
performance characteristics of measuring systems. Errors in measurement - types and
sources. 06 Hrs.
Unit –2- Intermediate Modifying and Terminating Devices: Transducers-
classification, types and their functions. Introduction to intermediate modifying devices
and their functions.Terminating devices- CRO, Oscillographs. 05 Hrs.
PART-B
Unit –3- Measurement of Strain, Force and Torque: Introduction, strain measurements:
Strain gauges, preparation and mounting of strain gauges, gauge factor. Force
measurements: Cantilever beams, proving ring, load cell. Torque measurements:
Mechanical, electrical and hydraulic dynamometers. 05 Hrs.
Unit –4- Pressure and Temperature Measurements: Methods of measuring pressure,
use of elastic members, Bridge man gauge, McLeod gauge, Pirani gauge. Temperature
measurements: Introduction, classification of temperature measuring devices,
thermocouple, materials for thermocouple and pyrometers. 05 Hrs.
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PART – C
Unit –5- Standards of measurement: Definition and objectives of metrology, standards
of measurements, Slip gauges, Wringing phenomenon, ASTM Standards, Indian Standards
(M-87 & M-112), Numerical problems on building of slip gauges. 05 Hrs.
Unit –6- System of Limits, Fits, Tolerances and gauges: Principle of interchangeability
and selective assembly, tolerances,limits of size, types of fits and their designation, hole
basis system, shaft basis system, classification of gauges, design of gauges (Taylor's
Principles) - with numerical examples. 05 Hrs.
PART – D
Unit –7- Comparators: Introduction, characteristics of comparators, classification of
comparators - Mechanical, mechanical optical, pneumatic, electrical and electronic
comparators, construction and working of different types of comparators. 05 Hrs.
Unit –8- Surface Texture: Meaning of surface texture and definitions, factors affecting
surface texture, elements of surface texture, symbols for specifying surface finish,
methods for measuring surface finish, surface finish measuring instruments. 05 Hrs.
TEXT BOOK:
1. Engineering Metrology – R.K. Jain. Khanna Publishers, 20th edition, 2008.
ISBN:9788174091536.
2. Mechanical Measurements – Thomas G. Beckwith, Roy D. Marangoni& John H.
Lienhard V., Pearson education Inc. 5th edition, 2004. ISBN:0201569477,
9780201569476
REFERENCE BOOKS:
1. Metrology and Measurements – Anand K. Bewoor and Vinay A. Kulkarni,
TMH, 2009. ISBN:978-0-07-014000-4
2. A text book of Measurement and Metrology - A.K. Sawhney and M. Mahajan.,
DhanpatRai& Sons pvt. Ltd., 2004
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ENGINEERING ECONOMICS & INDUSTRIAL MANAGEMENT
ME 505 LTPC: 3-1-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Course Objective:
To know the basic concepts of economics, managerial and decision making ability towards
cost estimation of engineering projects.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs)}
Upon successful completion of this course, the student shall be able to:
1) apply concepts of economics and management towards engineering perspective 1, 5
2) analyse cost / revenue data to carry out economic analysis and decision making 4, 8
3) compare the alternative projects on an economical basis 6, 8
4) acquire leadership and managerial skills 5 7, 8,12
COURSE CONTENTS:
PART – A
Unit – 1 Introduction to Engineering Economics: Introduction, engineering and economics,
problem solving and decision making, intuition and analysis, tactics and strategy.
Interest and interest factors: Origin of interest, simple interest, compound interest, notation
and cash-flow diagrams, Exercises and discussion. 07Hrs.
Unit – 2 Present Worth Comparisons: Conditions for present worth comparisons, basic
present worth comparisons, present worth equivalence, net present worth, assets with unequal
lives, Infinite lives, Future worth comparisons, Pay-back comparison. 06 Hrs.
PART – B
Unit – 3 Equivalent Annual Worth Comparisons: Introduction, Equivalent annual worth
Comparison methods, situations for equivalent annual worth comparison, consideration of asset
life, Comparison of assets with equal and unequal lives, Use of shrinking fund method, Annuity
contract for guaranteed income. 06 Hrs.
Unit – 4 Rate of Return Calculations: Introduction, rate of return, minimum acceptable rate of
return. Cost of capital concepts. Effect of inflation, causes of inflation, consequences of
inflation. Tax concepts and corporate income tax. 06 Hrs.
PART - C
Unit – 5 Estimating, Costing and Depreciation: Components of costs, estimation and costing,
selling price estimation, estimation of material cost. Causes of depreciation, basic methods of
computing depreciation charges, straight line method, sinking fund method, diminishing
balance method and sum of digits method. 07 Hrs.
11
Unit – 6 Management Concepts: Introduction, history of management, Principles of
management, Process of management, levels of management and types of management.
Contribution by Pioneers like Frederick W. Taylor, Henry Fayol, Frank B. Gillbreth, Henry
Gantt and Elton Mayo. 06 Hrs.
PART - D
Unit – 7 Organisation: Definition of organization, formal and informal organization. Steps in
setting up an organization and principals of organization. Types of organizations:- Military
organization, line and staff organization, functional organization, matrix organization and
committee organization. Accountability of managers in types of organization. 07 Hrs.
Unit – 8 Ownership: Types of industrial ownership, single ownership, partnership, joint stock
companies, cooperative organization, state and central government organizations. Methods of
raising capital: loans, hire purchase, shares and public deposits. 07 Hrs.
TEXT BOOKS
1. Riggs J.L, Engineering Economy, McGraw Hill, 1st edition, 2002 (for Units 1- 5)
ISBN: 0-07-058670-5
2. Koontz O Dennel, Management, TMH, 1st edition, 2000 (for Units 6- 8) ISBN: 00-
70-354871 : 9780070354876
REFERENCE BOOKS
1. O.P.Khanna. Industrial Engineering and Management, Dhanpat Rai & Sons. New
Delhi, 2002 ISBN: 818992835-1-5
2. T. R Banga and S.C. Sharma Mechanical Estimation and Costing, Khanna
publication, New Dehli, 1992. ISBN : 9788174091000
3. Tarachand, Engineering Economics, Nem Chand &Bros. Roorkee, 1993. ISBN:
9788185240824
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PRINCIPLES OF CAD & CAM
ME506 LTPC: 3-1-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Course Objective:
Learn how to integrate Design and Manufacturing Systems through incorporation of
computers
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs)
Upon completion of the course, students shall be able to:
1) understand use of computers in design and manufacturing systems 1, 3, 4, 5,7
2) know about computerized manufacturing methods 1, 4, 5, 8
3) acquire the Knowledge of data bases , software s and hardware’s for
computer design in organization 1, 2, 3, 9
4) learn how to integrate Design and Manufacturing Systems through
incorporation of computers Identify, formulate and solve engineering
problems 1, 2, 5, 7, 10
COURSE CONTENTS:
PART – A
Unit–1 Computer Aided Design: Historical perspective of CAD & CAM, Introduction to CAD,
Definition of CAD & CAM tools, Product Life Cycle, Introduction and application of computers
for design, creating the manufacturing data base, benefits of CAD. 05 Hrs.
Unit–2 Hardware for CAD: Introduction, the design workstation, graphic terminals for CAD,
operator input devices, plotter and other output devices, the central processing unit, Secondary
storage. Hardware integration and networking. 07 Hrs.
PART – B
Unit–3 Software for CAD: Computer graphics software, software configuration for graphic
system, Graphic standards, Data base structure, CAD & CAM data exchange, Geometrical
modeling, types and its representations, wireframe, solid and surface model 08 Hrs.
Unit–4 Principles of Computer Graphics: Graphic primitives, Functions of Graphics Package,
User interface, Database Coordinate Systems, 2-D Transformation of geometry. Window, View
port, Viewing & Clipping 06 Hrs.
PART – C
Unit – 5 Mathematical representation of Surfaces and Solids : Introduction, Surface entities,
Surface representations, Types of curves and surfaces, surface manipulation, solid model and
entities, fundamentals of solid modeling, Visual realism, model clean up and visibility
techniques. 06 Hrs.
13
Unit – 6 Computer Aided Manufacturing: Introduction, Numerical control techniques, Basic
components of NC-systems, NC procedure, NC coordinate systems, NC motion control systems.
NC, CNC, DNC features and their advantages and disadvantages. 07 Hrs.
PART – D
Unit – 7 CNC Programming Techniques: Steps and commands used in part programming, part
programming for Drilling, Milling and Turning operations. (Typical examples)
CNC Machining and turning centers, CNC Tooling and presetting. 07 Hrs.
Unit –8 Virtual and Rapid prototyping: Introduction to Virtual and Rapid prototyping, RP
data formats and Information workflow, Classifications of RP, Process involving Liquid,
discrete particle and solid sheet of standard methods of each, Technical characteristics of
standard methods. Applications of RP 06Hrs.
Text Books:
1. Michel P Groover & Emory W Zimmeres, JR, CAD & CAM, TMH, 2nd
Edition,
2004. ISBN-81-203-04020-0
2. Ibrahim Zeid, S.Subramanya, V.Raju, CAD & CAM Theory and practice, TMH,
2nd
Edition, 2010 ISBN-0-07-463991-9
Reference Books:
1. D.T.Pham and SS Dimov, The technologies and applications of Rapid Prototyping and
Rapid Tooling, Springer -Verlag London limited2001. ISBN :1-85233-360-X
2. P.N. Rao, CAD & CAM Principles & Application, TMH, 2nd
Edition, 2004. ISBN-(13)
-978-81-234-2236-8
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COMPUTER AIDED DRAFTING & MODELING LABORATORY
ME507 LTPC: 0-0-3-1.5
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 39
Course objective:
To impart students with the necessary skills for drafting and modeling machine
components using CAD tools
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs)
Upon completion of the course, students shall be able to:
1) Practice ISO and BIS standards for drafting 1, 4, 5, 9, 11
2) Model and assemble machine parts 1, 2, 3, 4, 11
3) Generate 2D-drawings from 3D models 1, 4, 11, 8, 11
4) Know about the industrial models and their usages in practical
design and manufacturing fields. 1, 2, 3, 4, 5
COURSE CONTENTS:
Introduction to computer aided drafting
a) BIS drawing conventions, Line types, arrows, drawing scales and sheet setup.
b) Geometrical constructions – line, circle, curve, spline, rectangle, holes etc.,
c) Edit drawings – trim, fillet, extend and cut operations.
d) Transformation – rotate, move, scale, mirror etc.,
e) Dimensioning practice.
Solid Modeling – Assembly of machine parts and detailed drawing of the following
a) Tail Stock of a Lathe
b) Tool head of a Shaper
c) Plummer block
d) Lever safety valve.
e) Stop valve
f) Leaf Jig
TEXT BOOKS:
1. K.R. Gopal Krishna, Machine Drawing, Subhas Publishers, 11th
Edition, 1997, ISBN-
657981975
2. P.N. Rao, CAD/CAM Principles & Application, TMH, 2nd
Edition, 2010, ISBN-0-07-
058373-0
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REFERENCE BOOKS:
1. N.D.Bhat & Panchal, Machine Drawing Charotar Publishers, 13th
Edition, 1996.
ISBN-978-93-803-58-61-1
2. K.L. Narayan, P.Kannaiah and K. Venkat Reddy, Machine Drawing, New age
International publisher, 1st Edition, 1994.ISBN: 978-81-224-2518-5.
SEE Scheme:
1. Solid modeling & Assembly 40 Marks
2. Drafting and Dimensioning of assembled parts 10 Marks
Total: 50 Marks
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FLUID MECHANICS & MACHINERY LABORATORY
ME508 LTPC: 0-0-2-1
Exam Hours : 3 Hours / Week : 02
SEE : 50 Marks Total hours : 26
Prerequisites:
ME302, ME402
Course objective:
To provide students with the necessary skills to conduct experiments, collect data, perform
analysis and interpret results to draw valid conclusions through standard test procedures to
determine characteristics of hydraulic machines and performance of fluid flow devices
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to::
1 reinforce and enhance their under-standing of the fundamentals of fluid
mechanics and hydraulic machines 1
2 calibrate fluid flow measuring devises 2, 5
3 conduct performance studies on hydraulic machines 2
4 use their analytical, teamwork, leadership skills in the development of
fluid flow measuring devises and hydraulic machines so as to provide
solutions to problems sought by local and/or global community
2, 8
COURSE CONTENTS:
1 Determination of coefficient of friction of flow in a pipe.
2 Determination of minor losses in flow through pipes.
3 Experiments on flow measuring devices
a) Orifice plate
b) Venture-meter
4 Impact of jets on vanes
5 Performance tests on:
a) Pelton Wheel
b) Francis Turbine
c) Kaplan turbine
6 Performance tests on:
a) Centrifugal pump
b) Reciprocating Pump.
SEE Scheme:
1. One experiment from 1, 2, 3 & 4 15 Marks
2. One experiment from 5 or 6 25 Marks
3. Viva Voce 10 Marks
Total: 50 Marks
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MECHANICAL VIBRATIONS
ME 601 LTPC: 3-1-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Course objectives:
The students should be able to acquire knowledge of fundamental concepts of mechanical
vibration and analysis
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) mathematically model mechanical systems 1, 2, 3, 4
2) solve problems on free and forced vibration of one & two degree of freedom
systems 1, 4, 3
3) solve problems on multi degree freedom systems using numerical methods 1, 2, 3, 4, 5
4) design mechanical systems for vibration isolation and measurement 1, 3, 4, 5
COURSE CONTENTS:
PART – A
Unit–1 introduction: Types of Vibrations, Simple Harmonic Motion (S.H.M), principle of
super position applied to Simple Harmonic Motion, Beats, Fourier theorem.
06 Hrs.
Unit–2 Undamped Free Vibrations: Single degree of freedom systems, Undamped free
vibrations natural frequency of free vibration, stiffness of spring elements, effect of mass of
spring, Compound Pendulum. 07 Hrs.
PART – B
Unit–3 Damped Free Vibrations: Single degree freedom systems, different types of
damping, concept of critical damping and its importance, study of response of viscous damped
systems for cases of under damping, critical and over damping, Logarithmic decrement.
06 Hrs.
Unit – 4 Forced Vibrations: Single degree freedom systems, steady state solution with
viscous damping due to harmonic force. Solution by Complex algebra, reciprocating and
rotating unbalance, vibration isolation-transmissibility ratio, due to harmonic excitation and
support motion. 07Hrs.
PART – C
Unit–5 Vibration Measuring Instruments & Whirling Of Shafts: Vibrometer and
accelerometer. Whirling of shafts with and without air damping, discussion of speeds above
and below critical speeds. 06 Hrs.
18
Unit –6 Systems With Two Degrees Of Freedom: Introduction, principal modes and normal
modes of vibration, co-ordinate coupling, generalized and principal co-ordinates, free vibration
in terms of initial conditions. 06 Hrs.
PART – D
Unit–7 Applications Of Two Degrees Of Freedom Systems: Geared systems. Forced
oscillations - Harmonic excitation. Applications (a) vehicle suspension, (b) dynamic vibration
absorber, c) Dynamics of reciprocating Engines. 06 Hrs.
Unit–8 Numerical Methods For Multi Degree Freedom Systems: Introduction, Influence
coefficients, Maxwell reciprocal theorem, Dunkerley’s equation. Orthogonality of principal
modes, method of matrix iteration - Method of determination of all the natural frequencies using
sweeping matrix and orthogonality principle. Holzer’s method, Stodola method. 08 Hrs.
TEXT BOOKS:
1. S.S. Rao, Mechanical Vibrations, Pearson Education Inc, 4th
Edition, 2003.
ISBN- 9780130489876.
REFERENCE BOOKS:
1. Leonanrd Meirovitch, Elements of Vibrations Analysis, TMH, Special Indian
edition, 2007, ISBN-81-7700-047-0
2. S.Graham Kelly, Mechanical Vibrations, Schaum’s outline series, TMH,
Special Indian Edition, 2007, ISBN-14-09780070616790.
19
MANUFACTURING SCIENCE – III
ME602 LTPC: 4-0-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Course Objectives:
To impart knowledge of theory of metal cutting, grinding and advanced machining
processes
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1. acquire knowledge on cutting tool materials, tool geometry, mechanics
of machining and cutting fluids. 1, 2, 3
2. estimate machining temperatures, tool wear and tool life. 1, 2,3, 4
3. understand the grinding operations and measurement of surface
roughness. 1, 2, 3, 4
4. understand the principle, operation, advantages and limitations of
different non traditional machining processes. 1, 2, 3, 4,
5, 6
COURSE CONTENTS:
PART – A
Unit–1 Cutting Tool Materials – Introduction, Tool Materials – Properties,
Characteristics and applications.
Cutting Tool Geometry – Tool angles, Systems of Tool Geometry – ASA, DIN and
ISO (Normal rake system), Tool signature (designation), indexable Inserts, Chip
breakers. 06 Hrs.
Unit – 2 Mechanics of Metal Cutting – Mechanism of chip Formation, Types of
Machining Chips, Cutting Ratio, Shear Angle and its significance, Forces in orthogonal
machining, Merchant’s circle diagram, Earnst & Merchant, Lee – Shaffer’s Theories on
orthogonal Machining 07 Hrs.
PART – B
Unit–3 Machining temperature and its control – Heat sources in machining,
Temperature distribution, determination of chip – Tool interface temperature, cutting
Fluids. 06 Hrs.
Unit–4 Tool Wear, Tool Life and Machinability – Modes of tool failure, ISO tool
life criteria for tool materials, tool tife & Taylor’s tool life equation, machinability.
06 Hrs.
20
PART – C
Unit – 5 Grinding – Abrasive wheels, characteristics and ISO designation of Grinding
wheels, effect of Grinding condition on wheel behaviour, Determination of the density
of active grains, equivalent diameters of grinding wheels, grinding wheel life, wheel
turing and dressing. 07 Hrs.
Unit – 6 Machined Surface Roughness and Surface Integrity – Introduction, effect
of machining parameters on surface finish, expression for surface roughness in turning
and milling, surface integrity – definition, factors affecting surface integrity and
importance of surface integrity 06 Hrs.
PART – D
Unit–7 Non Traditional Machining Processes – Introduction – Need & classification,
principle, operation, advantages, limitations, process variables, process capabilities and
applications of AJM, AWJM, USM, EDM & ECDM 07 Hrs.
Unit–8 Principle, operation, advantages, limitations, process variables, process
capabilities and applications of ECM, ECG, LBM & EBM (No detailed description of
equipments). 07 Hrs.
TEXT BOOKS
1. Geoffrey Boothroyd, Fundamentals of Metal Machining and Machine Tools, McGraw-
Hill, International student edition, 1985 (for Units 1- 6). ISBN: 0070850577,
9780070850576.
2. V. K. Jain, Advanced Machining Processes, Allied publications, 1st Edition, 2004 (for
Units 7- 8). ISBN:81-7764-294-4
REFERENCE BOOKS
1. B. L. Juneja, G. S. Shekhon, Nithin Seth, Fundamentals of Metal Cutting and Machine
Tools, New Age international publishers, 2nd
Edition, 2005. ISBN: 81-224-14672-2.
2. P. N. Rao, Manufacturing Technology – Metal Cutting and Machine Tools, TMH, 2nd
Edition, 2008. ISBN: 0-07-463843-2.
21
DESIGN OF MACHINE ELEMENTS – II
ME603 LTPC: 3-1-0-4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Prerequisites:
ME301, ME 304, ME 306, ME 405, ME503
Course objectives:
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) apply basic stress and strain analysis techniques to machine elements 1, 3, 6, 7, 8
2) utilize standard failure theories and fatigue analysis to develop safety
factors for machine elements 1, 3, 7
3) to learn to use standard practices in design of machine elements and
standard data 6, 7
4) function effectively within engineering work teams 6, 7, 8, 9
COURSE CONTENTS:
PART – A
Unit – 1 Curved Beams: Winkler bach equation, Stresses in curved beams of standard cross
sections used in crane hook, Punching presses and clamps. 06 Hrs.
Unit –2 Springs: Types of springs - Stresses in coiled springs of circular and non-circular cross
sections and concentric springs. Springs under fluctuating loads, Leaf and carriage springs.
Stress in Leaf springs. Torsion, Belleville and Rubber springs. 06 Hrs.
PART – B
Unit – 3 Design of Gears, Spur and Helical Gears: Definitions, stresses in gear tooth, Lewis
equation and form factor, design for strength, dynamic and wear loads. 08 Hrs.
Unit – 4 Bevel Gears: Definitions, formative number of teeth, stresses in gear tooth, design for
strength, dynamic and wear loads. 06 Hrs.
PART – C
Unit– 5 Worm Gears: Definitions, design based on strength, dynamic, wear loads and
efficiency of worm gear drives. 06 Hrs.
Unit–6 Design of Internal Combustion engine parts: Cylinder, design of trunk piston,
connecting rod, design for strength of over hung and centre crank shafts. 08 Hrs.
22
PART – D
Unit – 7 Lubrication and Bearing: Mechanisms of lubrication, bearing modulus, coefficient
of friction minimum oil film thickness, heat generated, heat dissipated – Examples of journal
bearing and thrust bearing design. Ball and Roller Bearings, Types, Bearing Life, equivalent
bearing load, selection of bearings of different types. 06 Hrs.
Unit–8 Cylinders and Cylinder Heads: Review of Lame’s equations, compound cylinders,
stress due to different types of fits. Flat plates & cylinder heads, flat heads, bolted and welded
heads, dished heads. 06 Hrs.
TEXT BOOK:
1. Maleev & Hartman’s, Machine Design in SI units, 5th
Edition, C B S Publications,
Delhi, 2005. ISBN:9788123-9-0637-9
REFERENCE BOOKS:
1. M.F. Spotts, T.E. Shoup, L.E. Hornberger, S.R.Jayaram & C.V.Venkatesh, Design
of Machine Elements, Pearson Education, 8th
Edition, 2006. ISBN 9788177584219
2. Joseph Edward Shigley, Mechanical Engineering Design, Mc. Graw Hill, 8th
Edition, 2008. ISBN:9780073529288.
3. V. B. Bhandari, Design of Machine Elements, TMH, 3rd
Edition, 2007.
ISBN:9780070681748
Design Data Hand Books:
1. K. Mahadevan and Balaveera Reddy, Design Data Hand Book, C B S Publications,
Delhi. ISBN: 9788123901626.
23
MICROPROCESSORS AND MECHATRONICS
ME 604 LTPC: 4-0-0- 4
Exam Hours : 3 Hours / Week : 04
SEE : 50 Marks Total hours : 52
Prerequisites:
EC103/203
Course Objectives:
To impart the knowledge of Microprocessors, Microcontrollers, and PLCs’ and its
role in Mechatronic systems
To introduce the students, the fundamentals of interdisciplinary engineering
components and their integration in Mechatronic systems design approach
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon successful completion of this course, students shall be able to:
1) identify the problem, design and optimize integrated solutions
adopting new directions 1, 3, 5, 8, 9,
2) involve, interact and solve electro mechanical systems 2, 4, 5, 9
3) develop and evaluate alternate solutions to real world problems 1, 2, 5, 6, 9,
11
COURSE CONTENTS:
PART – A
Unit -1 Introduction to Microprocessors: Evolution of Microprocessor, organization of
Microprocessor based system, Microprocessor instruction set, Computer language.
Microprocessor architecture and its Operations, Initiated operations and 8085 bus organization,
Internal data operations and 8085 registers. 06 Hrs.
Unit –2 Memory, Flip-Flop as a storage element, memory map and addresses, memory address
range and address lines, memory word size and instruction fetch, Input output devices. 8085
Microprocessor architecture – 8085 Microprocessor, Communication and Bus timing,
Generating control signals. 07 Hrs.
PART – B
Unit – 3 The 8085 programming model, Instruction classification, Instruction and Data format.
Microcontrollers – Architecture of Intel 8051 microcontroller and its selection factors,
applications. 07 Hrs.
Unit – 4 Mechatronics – Introduction, The Design process, Systems, Measurement systems,
Control systems, Microprocessor based controllers. 06 Hrs.
24
PART – C
Unit – 5 Signal conditioning – Interfacing with Microprocessor, Signal conditioning process.
Digital signals – Analogue to digital conversion, Digital to analogue conversion, Multiplexers,
Data acquisition. Introduction to data presentation systems. 07 Hrs.
Unit – 6 Actuation systems – Introduction to Pneumatic, Hydraulic and Mechanical actuation
systems. Electrical systems, Mechanical switches, Solid state switches, Solenoids, D.C. Motors
and its controls, A. C. Motors, Stepper motors and its controls, Merits and demerits.
06 Hrs.
PART – D
Unit–7 Programmable logic controllers – Introduction, Basic PLC structure, Input/output
processing, Ladder programming, Instruction lists, Timers and Counters. PLCs versus
Computers. 07 Hrs.
Unit-8 Design of Mechatronics systems – Introduction, Mechatronics approach to design, Case
studies, Future trends. 06 Hrs.
TEXT BOOK:
1. R. S. Ganokar, Microprocessor Architecture, programming and applications with
8085/8085A, Wiley Eastern, 2nd
Edition, 1995. ISBN – 978-81-900828-7-6
2. W. Bolton, Mechatronics, Electronics Control Systems in Mechanical and Electrical
Engineering, Pearson Education, 4rd
Edition, 2012. 978-81-317-6257-8
Reference:
1. K. P. Ramachandran, G.K. Vijayaraghavan, M.S. Balasundram, Mechatronics
Integrated Mechanical Electronic systems, Wiley India Pvt. Ltd, 2012. ISBN-978-81-
265-1837-1
2. Aditya P. Matur, Introduction to Microprocessors, TMH, 3rd Edition, 2000. 0-07-
460222-5
3. Godfrey C. Onwubolu, Mechatronics Principles and Applications, Butterworth-
Heinemann, 2011. ISBN-978-0-07-069968-7.
25
CASTING TECHNOLOGY
ME 651 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course objectives:
The objective of this course is to impart knowledge of principles, technology and recent
developments in casting.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) acquire knowledge on moulding materials, foundry machines and
equipments 1, 5, 9
2) estimate charges for different melting furnaces and final alloying
proportions 1, 9
3) identify casting defects, understand reasons and recommend remedial
measures. 1, 9
4) know the standard melting practices of ferrous, nonferrous metals and
their alloys 8, 9,
COURSE CONTENTS:
PART-A
Unit –1 Introduction: General review of metals and alloys used in the foundry.
Feeding of Casting: Solidification of metals and alloys, factors affecting fluidity,
elements of gating systems, feeding technology, and Metal filtration. 06 Hrs.
Unit –2 Casting Design: Functional design, dimensional design, metallurgical design,
optimization of casting design. 05 Hrs.
PART-B
Unit –3 Melting Furnaces: Cupola, rotary furnace, induction furnace, arc furnace
melting, application of vacuum metallurgy in steel making. 05 Hrs.
Unit –4 Cast Irons: Introduction, Gray cast iron, malleable cast iron, Spheroidal graphite
iron, welding metallurgy of Gray and Ductile cast iron. 05 Hrs.
PART – C
Unit –5 Cast Steels: Introduction, types of steels, austenitic manganese steel, stainless
steel, maraging steel, and weld repair of steel castings. 05 Hrs.
Unit –6 Cast Nonferrous Alloys: Principles of melting and casting of nonferrous alloys,
Titanium and its casting alloys. 05 Hrs.
26
PART - D
Unit –7 Mechanization of foundry: Need for modernization and mechanization, areas of
mechanization, environment control in foundries, material handling equipments. 05 Hrs.
Unit –8 Casting Inspection and Defects: Inspection of casting by ND methods, defects in
casting – causes and rem 05 Hrs.
TEXT BOOK:
3. A. K. Chakrabarthi, Casting Technology and Cast Alloys - PHI, 2005.
ISBN :8120327799
REFERENCE BOOKS:
1. Heine, Loper and Rosanthal, Principles of metal Castings - TMH, 2nd Edition,
2007. ISBN: 0070993483
2. P. L. Jain, Principles of Foundry Technology, TMH, 2nd
Edition, 2006. ISBN:
0070447608.
27
THEORY OF ELASTICITY
ME 652 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Prerequisites:
ME 301
Course objectives:
Definition and notations of stress and strain. Discussion on stress at a point and strain at a
point, to find the stress in an infinite plate and to study the effect of thermal stress.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) understand fundamentals of the theory of elasticity including
strain/displacement and Hooke’s law relationships 1, 9
2) investigate Airy’s stress function for simple beam problems. 2, 4
3) solve torsion problems in bars and thin walled members. 1, 4
4) demonstrate Thermo elastic stress-strain relationship, Principle of super
position, reciprocal theorem 5, 9
COURSE CONTENTS:
PART – A
Unit – 1 Definition And Notation: Stress, stress at a point, equilibrium equations, principal
stresses, Mohr's diagram, Maximum shear stress, boundary conditions. 05 Hrs.
Unit–2 Strain At A Point: Compatibility equations, principal strains, generalised Hooke's law,
methods of solution of elasticity problems - plane stress - Plane Strain problems.
06 Hrs.
PART – B
Unit–3 Two Dimensional Problems: Cartesian co-ordinates - Airy's stress functions -
Investigation of Airy's Stress function for simple beam problems - Bending of a narrow
cantilever beam of rectangular cross section under edge load - method of Fourier analysis - pin
ended beam under uniform pressure. 05 Hrs.
Unit–4 General Equations In Cylindrical Co-Ordinates: Thick cylinder under uniform
internal and / or external pressure, shrink and force fit, stress concentration. 05 Hrs.
28
PART – C
Unit – 5 Stresses In An Infinite Plate (with a circular hole) subjected to uniaxial and biaxial
loads, stress concentration, stresses in rotating discs and cylinders.
05 Hrs.
Unit – 6 Torsion Of Circular, Elliptical And Triangular Bars: Membrane analogy,
torsion of thin open sections and thin tubes. 05 Hrs.
PART – D
Unit–7 Thermal Stresses: Thermo elastic stress strain relationship, equations of equilibrium
Thermal stresses in thin circular discs and in long circular cylinder, sphere.
05 Hrs.
Unit– 8 Uniqueness Theorm: Principle of super position, reciprocal theorem, saint venant
principle 05 Hrs.
TEXT BOOKS:
1. S.P. Timoshenko and JN Gordier, Theory of Elasticity, MC Graw Hill
International, 3rd
Edition, 1975. ISBN: 9780070701229.
REFERENCES BOOKS:
1. Dr. Sadhu Singh, Theory of Elasticity, Khanna Publications, 2013. ISBN:
9788174090607.
2. Martin H. Sadd, Elasticity, Theory, Applications & Numericals, Elsevier, 2005.
ISBN:13 -9780123744463
29
AUTOMOTIVE ENGINEERING
ME 653 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course objectives:
To impart knowledge of automotive structures and operating components of automobiles.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) understand the layout and arrangement of principal parts of an automobile 1
2) comprehend knowledge of automotive operating and control systems 4
3) identify the technical problems and suggest remedies for automotive
operating and control systems 5
4) compare and suggest appropriate components for automotive operating and
control systems 5
5) know automobile emissions and its effects on environment 10
COURSE CONTENTS:
PART – A
Unit –1 Engine Components And Cooling & Lubrication Systems: Spark Ignition (SI) &
Compression Ignition (CI) engines, cylinder - arrangements and their relatives merits, liners,
piston, connecting rod, crankshaft, valves, valve actuating mechanisms, valve and port timing
diagrams, compression ratio, choice of materials for different engine components, engine
positioning, cooling requirements, methods of cooling, different lubrication arrangements.
05 Hrs.
Unit–2 Fuels, Fuel Supply Systems For Si And Ci Engines: Conventional fuels,
alternative fuels, normal and abnormal combustion, cetane and octane numbers, fuel mixture
requirements for SI engines, types of carburetors, C.D.& C.C. carburetors, multi point and
single point fuel injection systems,. 05 Hrs.
PART – B
Unit –3 Superchargers And Turbochargers: Naturally aspirated engines, forced Induction,
types pf superchargers, turbocharger construction and operation, Intercooler, Turbocharger lag.
05 Hrs.
Unit– 4 Ignition Systems: Battery ignition systems, magneto Ignition system, transistor assist
contacts. electronic ignition, automatic Ignition advance systems. 05 Hrs.
30
PART – C
Unit – 5 Power Trains: General arrangement of clutch, principle of friction clutches, torque
transmitted, constructional details, single plate, multi-plate and centrifugal clutches.
Gear box: Necessity for gear ratios in transmission, synchromesh gear boxes, speed gear
boxes. Free wheeling mechanism, Epicyclic gear box, principle of automatic transmission,
calculation of gear ratios, Numerical calculations for torque transmission by clutches.
05 Hrs.
Unit –6 Drive To Wheels: Propeller shaft and universal joints, Hotchkiss and torque tube
drives, differential, rear axle, steering geometry, camber, king pin inclination, included angle,
castor, toe in & toe out, condition for exact steering, steering gears, power steering, numerical
problems, 06 Hrs.
PART – D
Unit –7 Suspension, Springs And Brakes: Requirements, Torsion bar suspension systems,
leaf spring, coil spring, independent suspension for front wheel and rear wheel. Air suspension
system. Types of brakes, mechanical compressed air, vacuum and hydraulic braking systems,
Disk brakes, drum brakes, antilock - braking systems, purpose and operation of antilock-
braking system, Numerical Problems. 05 Hrs.
Unit-8 Automotive Emission Control Systems: Automotive emission controls, Controlling
crankcase emissions, Controlling evaporative emissions, Cleaning the exhaust gas,
Controlling the air-fuel mixture, Controlling the combustion process, exhaust gas
recirculation, treating the exhaust gas, Air-injection system, air-aspirator system, catalytic
converter, emission standards- Euro I, II, III and IV norms, Bharat Stage II, III norms.
05 Hrs.
TEXT BOOKS:
1. William H. Crouse & Donald L. Anglin, Automotive Mechanics, TMH, 10th
Edition, 2007. ISBN: 13:978-0-07-0634350
REFERENCE BOOKS:
1. K.K.Ramalingam, Fundamentals of Automobile Engineering, SciTech
Publications (India) Pvt. Ltd. ISBN: 10-8188429481, ISBN: 13: 978-8188429486.
2. R. B. Gupta, Automobile Engineering, Satya Prakashan, 4th
Edition.1984. ISBN:
9788176843799.
31
COMPUTER GRAPHICS
ME 654 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Prerequisites:
ME 506
Course Objective:
The objective of this course is to acquire knowledge of computer graphics tools for
generating 2D and 3D models, animation and its controlling techniques of engineering
systems
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs)
Upon completion of the course, students shall be able to:
1) to acquire knowledge of computer graphics tools for generating 2D and
3D models, animation and its controlling techniques of engineering
systems
1, 2, 3, 4
2) understand the fundamental concepts of computer graphics 1, 2, 5
3) learn 2D and 3D transformations and their coordinate formation
techniques 1, 5, 7
4) understand different viewing techniques, model clean up options and
different graphic color concepts 1, 2, 4
COURSE CONTENTS:
PART - A
Unit –1 Introduction: Overview of computer Graphics, Representative uses of Computer
Graphics, Development of Hardware & Software for Computer Graphics, conceptual Framework
for interactive Graphics, overview of Graphics Systems. 05 Hrs.
Unit –2 Geometric Transformations: 2-D Transformations, homogeneous coordinates & Matrix
Representation of 2D Transformation, Composition of 2D Transformation, The window to View
Transformation, Efficiency, Matrix Representation of 3D Transformation, Composition of 3D
Transformation, Transformation as a change in coordinate system. Transformation Functions &
Raster methods for transformation. 06 Hrs.
PART - B
Unit–3 Viewing Two Dimensional Viewing Functions, Clipping Operations, Projections,
Specifying an Arbitrary 3D View, Examples of 3D Viewing, The Mathematics of Planar
Geometric Projections, Implementing Planar Geometric Projections, Coordinate Systems. 05 Hrs.
32
Unit – 4 Solid Modeling: Introduction to Analytical and Synthetic Curves. Representing Solids,
Regularized Boolean Set Operation, Primitive Instancing, Sweep Representations, Boundary
Representations, Spatial-Partitioning Representations, Constructive Solid Geometry, Comparison
of Representation, User Interfaces for Solid Modeling. 05 Hrs.
PART - C
Unit– 5 Visual Realism: Introduction, Model Cleanup, Hidden Line Removal Algorithms, Hidden
Surface Removal and Hidden Solid Removal. 05 Hrs.
Unit – 6 Shading: Models, Surfaces, Enhancements and Solids Polygon-Rendering Methods.
Transparency, Shadows and Texture. 05 Hrs.
PART - D
Unit –7 Color Models & Color Application: Properties of Light, Standard Primaries and the
Chromaticity Diagram, Intuitive Color Concepts, RGB, YIQ, CMY, HSV & HSL Colour Model
05 Hrs.
Unit –8 Computer Animation: Introduction, Conventional & Computer assisted Animation,
Animation Systems, Animation Types, Animation Techniques Design of Animation Sequences,
Animation Languages, Methods of Controlling Animation, Basic rules of Animation, Motion
Specifications. 05 Hrs.
TEXT BOOKS:
1. C, Foley, Van Dam, Feiner & Hughes, Computer Graphics – Principles & Practice,
Pearson Education, 2nd
Edition, 2004. (for Units 1 – 3) ISBN:10-0321491696
2. Ibrahim Zied, S.Subramanya raju, CAD/CAM Theory & Practice, TMH, 2nd
Edition,
2010 (for Units 4 – 8). ISBN- 0-07-463991-9
REFERENCE BOOKS:
1. Donald Hearn & M. Pauline Baker, Computer Graphics, PHI, 2nd
Edition, 2004.
ISBN-0-13-015390-7
2. Steven Harrington, Computer Graphics – A Programming Approach, McGraw-Hill,
2nd
Edition, 2004. ISBN -978-3-7913-3963-4.
33
NANOTECHNOLOGY
ME655 LTPC: 3-0-0- 3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course Objective:
This course is to address the most exciting, novel and interdisciplinary issues in nano
science and engineering and particular attention will be on carbon.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs)}
Upon completion of the course, students shall be able to:
1) understand the rapidly developing field of nanoscience and Nanotechnology 1,5
2) know the physics of nanostructured systems, their current roles in
technology and future impact 1, 5, 9, 10
3) comprehend structure, properties, manufacturing, and applications of carbon
materials and characterization methods in nanotechnology 3, 4, 5, 8
COURSE CONTENTS:
PART – A
Unit–1 An overview of Nanoscience & Nanotechnology: Historical background, nature,
scope and content of the subject, multidisciplinary aspects – industrial, economic and societal
implications. 05Hrs.
Unit –2 Experimental Techniques and Methods: Investigating and manipulating materials in
the nano scale, electron microscope, scanning probe microscope – optical and other
microscopes – light scattering – x-ray diffraction. 05 Hrs.
PART – B
Unit–3 Fullerenes: Synthesis and purification, chemistry of fullerenes in the condensed phase,
orientational ordering, pressure effects, conductivity and superconductivity, ferromagnetism,
optical properties.
Carbon Nanotubes: Synthesis and purification, filling of nanotubes, mechanism of growth,
electronic structure, transport properties, mechanical and physical properties & applications.
06 Hrs.
Unit – 4 Self-assembled Monolayers: Monolayers on gold, growth process, phase transitions,
patterning monolayers, mixed monolayers – applications.
Gas Phase Clusters: History of cluster science, formation and growth, detection and analysis –
type and properties of clusters – bonding in clusters. 05 Hrs.
34
PART – C
Unit – 5 Semiconductor Quantum Dots: Synthesis, electronic structure of nanocrystals, how
quantum dots are studied, correlation of properties with size – uses. 05 Hrs.
Unit–6 Shell Nanoparticles: Method of preparation, characterization, properties,
functionalized metal nanoparticles – applications. 05 Hrs.
PART – D
Unit – 7 Nanosensors: Nanoscale organization for sensors, characterization, nanosensors based
on optical properties, nanosensors based on quantum size effects, electrochemical sensors,
sensors based on physical properties, nanobiosensors, sensors of the future. 05 Hrs.
Unit–8 Molecular Nanomachines: Covalent and non-covalent approaches – molecular motors
and machines – other molecular devices – single molecular devices – practical problems
involved. 05 Hrs.
TEXT BOOKS:
1. T Pradeep (Professor, IIT Madras); NANO: The Essentials – Understanding
Nanoscience and Nanotechnology; Tata McGraw-Hill India (2007)
ISBN: 9780070617889.
2. Richard Booker & Earl Boysen; Nanotechnology, Wiley (2005). ISBN:
1118054504, 9781118054505.
REFERENCE BOOKS:
1. Introduction to Nanoscale Science and Technology [Series: Nanostructure Science
and Technology], Di Ventra, et al (Ed); Springer (2004) ISBN: 1402077203,
9781402077203.
2. Linda Williams & Wade Adams, Nanotechnology Demystified, McGraw-Hill
(2007) ISBN : 0071460233, 978-0071460231
3. Charles P Poole Jr, Frank J Owens, Introduction to Nanotechnology, Wiley India
Pvt. Ltd., New Delhi, 2007. ISBN: 0471079359, 9780471079354.
35
INTERNAL COMBUSTION ENGINES
ME 661 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course objectives:
To gain knowledge of theory and basic principles of operation and performance of
Internal Combustion (IC) engines
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) comprehend the significance of thermodynamics behind combustion and
detonation phenomena as applied to IC engines 5
2) understand the design of inlet / exhaust manifold, combustion chamber
and valve gear 3
3) recognize and understand reasons for differences among operating
characteristics of different engine types and designs 4
4) understand optimization of engine design for specific sets of constraints
(fuel economy, performance, emissions) 4
5) develop an appreciation for theoretical and practical limits to engine
performance and fuel economy 9
COURSE CONTENTS:
PART - A
Unit – 1 Thermodynamic cycle analysis: Air standard, fuel-air cycles and actual cycles and
their comparison 05 Hrs.
Unit – 2 Combustion in S I engines: Stages of combustion, normal and abnormal combustion,
knocking and its effect on performance, Octane number, Pre ignition and post ignition.
05 Hrs.
PART - B
Unit –3 Combustion in C I engines: Stages of combustion, Delay period and factors affecting
delay period, Diesel knock and its control, Knock rating of diesel fuel.
05 Hrs.
Unit– 4 Combustion chambers: Requirements of combustion chambers, combustion chambers
for S.I. engines and C.I. Engines and their comparison. 05 Hrs.
36
PART - C
Unit – 5 Fuels: Hydrocarbon fuels, chemical structures, alternate fuels, alcohols, vegetable oils
and bio gas as diesel fuel. 05 Hrs.
Unit – 6 Carburetion: Mixture requirements in S.I. engines, Simple carburetor, its drawback,
constant choke and constant vacuum type.
Fuel injection systems: Diesel injection systems, Petrol injection systems, electronic fuel
injection system. 05 Hrs.
PART - D
Unit – 7 Cooling system: Water, air and liquid cooling systems, role of thermostats – radiators.
Modern Developments – turbo charging and super charging, stratified charge engines, multi-
fuel, rotary piston engines. 06 Hrs.
Unit – 8 Emission regulation and control systems: Mechanism of pollutant formation, total
emission control package, control of NOx – exhaust gas recirculation – water injection.
05 Hrs.
TEXT BOOKS:
1. V. Ganeshan, Internal Combustion Engines, TMH, 2nd
Edition, 2003, ISBN : 0-07-
049457-6
REFERENCE BOOKS:
1. R. K. Rajputh, A Text Book of Internal Combustion Engines, Laxmi Publishers (P)
Ltd, 2nd
Edition, ISBN : 81-318-0066-0
2. W.W. Pulkrabek, Engineering Fundamentals of the Internal Combustion Engines,
Pearson publications, 2nd
edition, ISBN 9780131918559.
37
REFRIGERATION AND HVAC
ME 662 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Prerequisites:
ME302, ME305, ME404, ME501
Course objectives:
To introduce the students of under graduate level the application of thermodynamic
principles to carry out design and analysis of different refrigeration & air conditioning
systems
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) understand the fundamentals of Refrigeration and HVAC systems 1, 2, 5
2) know how thermodynamic principles are applied with in the Refrigeration
and Air-Conditioning. 4, 5
3) understand the differences, types and classification, choose a right
refrigerant and explain its effect on ozone depletion 6, 9, 10
4) carryout cooling load calculations and duct design for different Air-
Conditioning systems 5 , 8
COURSE CONTENTS:
PART - A
Unit -1 Brief review of various methods of Refrigeration. Vapour Compression Cycle: Analysis of
Vapour Compression cycle using ph and T-S diagrams- calculations, Standard rating of operating
conditions, Actual vapour compression cycle. Brief review of Vapour Absorption System.
05 Hrs.
Unit-2 Refrigerants: Survey of Refrigerants, Comparative study of Ethane and Methane
derivatives. Selection of Refrigerants, Requirements of Refrigerants, Effect of lubricants in
Refrigerants. Mixture Refrigerants-azeotropic mixtures. 05 Hrs.
PART - B
Unit-3 Multi Pressure Vapour Compression systems: Multi evaporator systems,Cascade systems,
Calculations, Production of Solid Carbon dioxide. Ventilation Systems; Introduction Air Pollution,
Contaminents, Ventilation standards, Ventilation system design. Introduction to Industrial
Ventilation systems. 05 Hrs.
38
Unit–4 Equipments used in vapor compression Refrigeration system:Compressors: Principle,
types of compressors, Capacity Control.Condensers: Types and construction, Expansion devices:
Types- automatic expansion valve, Thermostatic expansion valves, Capillary tube. 05 Hrs.
PART - C
Unit –5 Psychrometry of Air conditioning Process- Review: Summer Air conditioning, Apparatus
Dew point, and Winter Air conditioning. Design Conditions: Out side design conditions, Choice
of Inside conditions, Comfort chart. 05 Hrs.
Unit –6 Load Calculations and Applied Psychrometrics; Internal heat gains,System heat gains,
Break up of Ventilation Load and Effective Sensible Heat Factor, Cooling Load Estimate.
Psychrometric calculations for cooling. Selection of Air conditioning Apparatus for Cooling
and Dehumidification. 06 Hrs.
PART - D
Unit–7 Transmission and Distribution of Air: Room Air Distribution, Friction loss in ducts, dynamic
losses in ducts, Air flow through simple Duct system, Duct design. 05 Hrs.
Unit–8 Controls in Refrigeration and Air conditioning equipments: High pressure and Low pressure
cut out, Thermostats, Pilot operated solenoid valve, Motor controls, By pass control -Damper
motor. 05 Hrs. TEXT BOOKS:
1. C.P. Arora, Refrigeration and Air-conditioning, TMH, 2nd
edition, 2001, ISBN:
0074630105, 9780074630105.
REFERENCE BOOKS:
1. Dossat, Principles of Refrigeration, TMH, 1st edition, 2000 ISBN: 0132333716,
9780132333719
2. Jordon & Priester, Refrigeration & Air conditioning, PHI, 1st edition, 1995. ISBN:
9780750618588.
DATA HAND BOOKS:
1. Carrier, Air conditioning System Design Hand Book, McGraw Hill 2000. ISBN: 10:
007010090X.
2. Nijaguna & Samaga, Thermodynamics Data Hand Book, 2002, ISBN: 13:
978007010909.
39
BEHAVIOURAL SCIENCE
ME663 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Total hours : 41
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1. apply concepts of professional ethics, design and cultural reward
systems towards engineering perspective 5, 6, 9, 12
2. analyze different theories related to motivation and conflict
management 1, 2
3. compare leadership qualities, perception and stress symptoms 8, 9, 12
4. acquire leadership and managerial skills 5, 6, 7, 9
COURSE CONTENTS:
PART - A
Unit–1 Introduction: Definition of Organization Behaviour and Historical development,
Environmental context (Information Technology and Globalization, Diversity and Ethics, Design
and Cultural, Reward Systems) 05 Hrs.
Unit–2 The Individual: Foundations of individual behaviour, Ability 05 Hrs.
PART - B
Unit-3 Learning: Definition, Theories of Learning, Individual Decision Making, classical
conditioning, operant conditioning, social learning theory, continuous and intermittent
reinforcement. 05 Hrs.
Unit-4 Perception: Definition, Factors influencing perception, attribution theory, selective
perception, projection, stereotyping, Halo effect. 05 Hrs.
PART - C
Unit – 5 Values and Attitudes: Definitions - values, Attitudes: Types of values, job satisfaction,
job involvement, professional Ethics, Organizational commitment, cognitive dissonance.
05 Hrs.
Unit-6 Motivation: Maslow's Hierarchy of Needs, Me. Gregor's theory X and Y, Herzberg's
motivation Hygiene theory, David Me Cleland three needs theory, Victor vroom's expectancy
theory of motivation. 05 Hrs.
40
PART - D
Unit–7 Conflict Management: Definition of conflict, functional and dysfunctional conflict, stages
of conflict process. Stress Management: What is stress, symptoms of stress, measurement of stress,
sources of management, consequences of stress, how to manage with stress. 06 Hrs.
Unit-8 Leadership Definition, Behavioural theories - Blake and Mounton managerial grid,
Contingency theories - Hersey - Blanchard's situational theory, Leadership styles - characteristics,
Transactional, transformation leaders. 05 Hrs.
TEXT BOOKS:
1. Stephen P Robbins, Organizational Behaviour, Pearson Education, 9th
Edition,
2002 (for Units 1 – 6) ISBN : 10 -0733977669
2. Fred Luthans, Organizational Behaviour, Me Graw Hill, 12th
Edition, 2010. (for
Units 7 – 8) ISBN :10 :007-12-0071289399
REFERENCE BOOKS:
1. Aswathappa, Organizational Behaviour, Himalaya Publishers, 2001, ISBN :
8174939202
2. VSP Rao and others, Organizational Behaviour, Konark, Publishers, 2002, ISBN
:10-8174467475
41
ARTIFICIAL INTELLIGENCE AND EXPERT SYSTEM
ME664 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course Objectives:
This course intends to provide knowledge on importance of AI, knowledge representation,
Expert system, AI Languages, machine learning and applications in engineering.
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1. define AI, underlying assumptions and identify the strategies and state
space representation.
1 ,9, 10
2. address knowledge representation issues, predicate logic, with illustrative
examples.
4, 5, 8
3. know expert system structures, categories, pattern recognition and uses, 5 ,9 ,10
4. use of AI Language , machine learning and intelligent editors for real life
problem solving and engineering applications.
3, 4, 5, 8,
9
COURSE CONTENTS:
PART – A
Unit-1Artificial Intelligence: Introduction, definition, History and Evaluation, underlying
assumption, essential abilities of Intelligence, importance of Al, AI applications.
05 Hrs.
Unit – 2 State Space representation: Defining a problem. Problem search, strategies and
characteristics, AND-OR graphs, Game trees. Best- first Search, Breadth First Search,
Depth First Search, Problem reduction and Numerical Examples 06 Hrs.
PART - B
Unit – 3 Knowledge Representation Issues - Representations and Mappings, Types of
Knowledge - Procedural Vs Declarative Logical Representations. Use of Predicate Logic -
Representing simple facts, ISA and ISPART relationships, Syntax and Semantics. 05 Hrs.
Unit – 4 FOP logic, FQPL, properties of wffs, Conversion to Clause form, Resolution of
FOP Logic, Natural deduction, use of RRT for profs and answers, Illustrative examples.
05 Hrs.
42
PART - C
Unit–5 Expert Systems, Structure and uses, Representing and using domain knowledge,
F/w & B/w reasoning Expert System Shells, Expert system Development. 05 Hrs.
Unit–6 Expert system Categories Pattern recognition. Introduction to Knowledge
Acquisition, Typical Expert Systems – MYCIN and Variants of MYCIN. 05 Hrs.
PART - D
Unit – 7 AI Languages: LisP, LisP Primitives sample, LisP segment, property defining
functions. “ProLog”: fundamentals and sample programs. 05 Hrs.
Unit – 8 Introduction to Machine Learning - Perceptrons, Checker Playing Examples,
Learning Automata, Genetic Algorithms, Intelligent Editors. 05 Hrs.
TEXT BOOKS:
1. Dan W. Patterson, Introduction to AI&ES, PHI, 2005, ISBN :8120307771
REFERENCE BOOKS:
1. Elaine Rich & Kevin Knight, Artificial Intelligence, TMH, 1983. ISBN: 0-07-
052263-4
2. Nils J Nilson, Principles of Artificial Intelligence, Springer Verlag, Berlin, 3rd
edition,
1990. ISBN: 07458-0718-6.
43
NON CONVENTIONAL ENERGY SOURCES
ME665 LTPC: 3-0-0-3
Exam Hours : 3 Hours / Week : 03
SEE : 50 Marks Total hours : 41
Course objectives:
The objective of this course is to impart the knowledge of various renewable and non-
renewable energy resources and its applications
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) identify various energy resources, limitations and applications 1, 4,5, 9, 11
2) analyze theoretically the potential for utilizing renewable and non-
renewable energy sources 1, 4, 9
3) understand the concepts of energy storage and energy conservation. 1, 4, 9
COURSE CONTENTS:
PART – A
Unit –1 Introduction: Energy sources – renewable and non renewable. 05 Hrs.
Unit – 2 Solar Radiation: Measurement of solar radiation, schematic diagrams and principle of
working. Solar Radiation Geometry: latitude, declination angle, hour angle etc. 06 Hrs.
PART – B
Unit – 3 Solar Thermal Conversion: Collection and storage, thermal collection devices and
collection efficiency. 05Hrs.
Unit -4 Performance Analysis of Liquid flat plate collectors: General descriptions, collector
geometry, selective surface. Photovoltaic Conversion: Principle of working and characteristics,
applications. 05 Hrs.
PART – C
Unit-5 Wind Energy: Availability of wind energy in India, major problems associated with
wind power, wind machines. 05 Hrs.
Unit-6 Tidal Power, Ocean Power& Geothermal Energy: Fundamental characteristics of
tidal power, principle of working ocean power. Geothermal energy conversion: Principle of
working, types of geothermal station with schematic diagram. 05 Hrs.
PART – D
Unit-7 Energy from Bio mass: Energy plantation and description of biogas plant (Batch type
Floating & Fixed type), advantages and disadvantages. 05 Hrs.
Unit-8 Hydrogen Energy: Properties of Hydrogen with respect its utilization, sources of
hydrogen, production of hydrogen, storage and transportation methods. 05 Hrs.
44
TEXT BOOKS:
1. G.D. Rai, Non conventional energy sources, Khana Publishers, 2003, ISBN:
8186308296
REFERENCE BOOKS:
1. P.K. Nag, Solar power Engineering, TMH, 2003, ISBN: 0-07-043599-5.
2. Domkundwar, Power Plant Engineering, Dhanpath Rai & Sons, 3rd Edition, 2003.
45
MACHINE SHOP
ME607 LTPC:0-0-6- 3
Exam Hours : 4 Hours / Week : 06
SEE : 50 Marks Total hours : 78
Course Objective: To impart practical and working knowledge about M/c Tools and
machining operations
Course Outcomes:
Upon successful completion of this course, the student shall be able to:
1. understand operational principles of M/c Tools like, Lathe, Drilling,
Milling, Shaping ,and Slotting machines
1, 3, 8 2. perform machining operations
3. Select appropriate tools for specific operations
COURSE CONTENTS:
PART – A 1. Introduction to machine tools – Description of Lathe, Drilling, Milling Shaping, Slotting
and Grinding machines.
2. Preparation of 2 models to include facing and countersinking, turning, taper turning,
eccentric turning, thread cutting, concave and convex turning, grooving, chamfering and
boring operations on lathe.
3. Models are to be so given that the students will have to assemble the two models.
PART – B
1. Model I – Machining rectangular, triangular & dove tail slots on shaping machine.
2. Model II – Face milling, milling keyways using end mill cutters, spur and helical gear
cutting.
Note: - (1) Class hours - (3 + 3) per week
(2) Examination - 4 hours
SEE Scheme:
1. One model on lathe individual 25 Marks
2. One model on milling / shaping 15 Marks
3. Viva Voce 10 Marks
Total: 50 Marks
46
FUELS AND ENGINE LABORATORY
ME 608 LTPC:0-0-2-1
Exam Hours : 3 Hours / Week : 02
SEE : 50 Marks Total hours : 26
Prerequisites:
ME302, ME305, ME404
Course objectives:
To provide students with the necessary skills to conduct experiments, collect data,
perform analysis and interpret results to draw valid conclusions through standard test
procedures to understand characteristics of different fuels, energy conversion and
performance of I.C. Engines
Course Outcomes (COs) {with mapping shown against the Program Outcomes (POs))
Upon completion of the course, students shall be able to:
1) determine characteristics of different fuels 2, 3
2) understand the energy conversion from one form to another 5, 2
3) find out performance parameters and draw heat balance sheet for an I.C.
Engine 2, 5, 4
4) determine area of irregular boundary using planimeter 2, 5
5) use their analytical, teamwork, leadership skills in the development of
energy conversion engineering devices so as to provide solutions to
problems sought by local and/or global community 6, 8
COURSE CONTENTS:
PART – A
1. Determination of Flash and Fire point of Lubricating oil using open cup and closed cup
apparatus.
2 Determination of C.V. of solid fuels, Liquid & gaseous fuels.
3 Determination of Viscosity of Lubricating oil using Red wood, Saybolt & Torsion
viscometer.
4 Valve Timing/Port opening diagram of an I.C. engine
5 Determination of areas of irregular shapes using Planimeter
47
PART – B
6 Performance Tests on I.C. engines, calculation of I.P, B.P. F.P, and heat balance sheet
for
a) 4-stroke diesel engine.
b) 4-stroke petrol engine.
c) Two stroke petrol engine.
SEE Scheme:
1. Question from Part A 15 Marks
2. Question from Part B 25 Marks
3. Viva 10 Marks
Total: 50 Marks