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ID1021: Engineering Practice (4 Credits) Engineering Drawing: Introduction to engineering drawing - lettering - coordinate axes and
types of views - orthographic sketching - dimensioning - sectioning - isometric sketching -
boolean operations on 3D sketches Workshop: Fitting Shop - Dovetail Fitting, V-fitting, U T fit, Joining two pieces (male and
female): Welding – Single V-butt joint, Double lap Joint, Corner joint, T- joint, Edge joint, Gas
cutting (Demo): Machine Shop – Facing & Longitudinal turning, Step & taper turning,
Chamfering & drilling: Electronics Shop – Diode characteristics, Bridge rectifier, LDR Circuit,
Connecting resistors: Electrical Shop – Wiring basics, Stair case wiring, Switch circuits,
Characteristics of DC motor.
References: 1. Jon M. Duff and William A. Ross, "Engineering Design and Visualization", CENGAGE Learning
India, India Edition, 2009. 2. N. D. Bhatt, “Engineering Drawing: Plane and Solid Geometry”, Charotar Publishing House,
India, 2012. 3. K. Venugopal, “Engineering Drawing + AutoCAD”, New Age International, India, 2013. 4. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy, “Elements of Workshop
Technology: Vol 1 - Manufacturing Processes”, Fifteenth Reprint, Media printers and
publishers, India, 2012. 5. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy,, “Elements of Workshop
Technology: Vol 2 – Machine Tools”, Fifteenth Reprint, Media printers and publishers, India,
2012. 6. W. A. J. Chapman, “Workshop Technology Part 2”, 4th ed., Elsevier, 1972. 7. A.K. Sawhney and Puneet Sawhney, “A Course in Electrical and Electronic Measurements
and Instrumentation”, Dhanpat Rai Publications, India, 2012.
ID1041: Engineering Drawing (2 Credits) Introduction to engineering drawing - lettering - coordinate axes and types of views -
orthographic sketching - dimensioning - sectioning - isometric sketching - boolean operations
on 3D sketches.
References: 1. Jon M. Duff and William A. Ross, "Engineering Design and Visualization", CENGAGE Learning
India, India Edition, 2009. 2. N. D. Bhatt, “Engineering Drawing: Plane and Solid Geometry”, Charotar Publishing House,
India, 2012. 3. K. Venugopal, “Engineering Drawing + AutoCAD”, New Age International, India, 2013.
ID1054: Digital Fabrication (2 Credits) Complete process chain for design and subsequent realization of concepts making use of 3D
modelling and additive manufacturing (3D printing) processes: Familiarization with 3D solid
modelling for creation of engineering and freeform geometries; 3D Scanning using CMM and
laser scanners. 3D Printing concepts for conversion of CAD model into real part: slicing, effect
of part orientation. Project involving ideation, design and final fabrication using 3D printing.
ID1071: Mechanical Workshop (2 Credits) Fitting Shop - Dovetail Fitting, V-fitting, U T fit, Joining two pieces (male and female): Welding –
Single V-butt joint, Double lap Joint, Corner joint, T- joint, Edge joint, Gas cutting (Demo):
Machine Shop – Facing & Longitudinal turning, Step & taper turning, Chamfering & drilling:
Electronics Shop – Diode characteristics, Bridge rectifier, LDR Circuit, Connecting resistors:
Electrical Shop – Wiring basics, Stair case wiring, Switch circuits, Characteristics of DC motor.
References: 1. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy, “Elements of Workshop
Technology: Vol 1 - Manufacturing Processes”, Fifteenth Reprint, Media printers and
publishers, India, 2012. 2. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy,, “Elements of Workshop
Technology: Vol 2 – Machine Tools”, Fifteenth Reprint, Media printers and publishers, India,
2012. 3. W. A. J. Chapman, “Workshop Technology Part 2”, 4th ed., Elsevier, 1972. 4. A.K. Sawhney and Puneet Sawhney, “A Course in Electrical and Electronic Measurements
and Instrumentation”, Dhanpat Rai Publications, India, 2012.
ID1091: Fabrication Lab - II (2 Credits) Machine Shop – Introduction to general machines, Facing, Step turning, Drilling, Knurling,
Boring, Taper turning, Thread Cutting (only Demo): Welding – TIG Welding (Butt Joint with
S.S.Plate), MIG welding (Butt Joint with M.S.Plate): Pneumatics Lab – Circuits and applications:
Advance Electronics – Microprocessor Programming and Applications.
References: 1. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy, “Elements of Workshop
Technology: Vol 1 - Manufacturing Processes”, Fifteenth Reprint, Media printers and
publishers, India, 2012.
2. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy,, “Elements of Workshop
Technology: Vol 2 – Machine Tools”, Fifteenth Reprint, Media printers and publishers, India,
2012. 3. W. A. J. Chapman, “Workshop Technology Part 2”, 4th ed., Elsevier, 1972. 4. A.K. Sawhney and Puneet Sawhney, “A Course in Electrical and Electronic Measurements
and Instrumentation”, Dhanpat Rai Publications, India, 2012. 5. Albert P. Malvino and Jerald A. Brown, “Digital Computer Electronics”, McGraw-Hill Higher
Education, 3rd ed., 1992.
ID1100: Fluid Mechanics - I (2 Credits) Introduction – scope and relevance; Method of analysis – system vs control volumes –
differential vs integral approach, Units and dimensions; Fluid properties – continuum, density,
viscosity, surface tension, velocity, pressure, temperature; Fluid Statics – Hydrostatics, Fluid
forces on planes and curved surfaces, submerged and floating bodies, Buoyancy and stability,
Atmosphere as a fluid; Fluid Concepts – Streamlines, streaklines, pathlines, viscous vs inviscid
flows, laminar vs turbulent flows, compressible vs incompressible flows; Engineering bernoulli
equation; Control Volume analysis: Basic laws – Mass conservation law, thermodynamic laws,
Newton’s laws, Angular-Momentum principle; Buckingham Pi-theorem; Similitude and
modeling - scaling effects; Flows in a pipes and channels - friction factor, flow measurement
devices – Venturi meter, Orifice meter.
References: 1. Introduction to Fluid Mechanics by R. W. Fox, P. J. Pritchard and A. T. McDonald, Wiley 2. Fundamental of Fluid Mechanics by B. R. Munson, A. P. Rothmayer, T. H. Okiishi and W. W.
Huebsch, Wiley 3. Introduction to Fluid Mechanics and Fluid Machines by S. K. Som, G. Biswas and S.
Chakraborty, Tata McGraw-Hill 4. Multimedia Fluid Mechanics (DVD) by G. M. Homsy et al., Cambridge University Press 5. Fluid Mechanics by Frank M. White, McGraw-Hill
ID1130: Engineering Statics (2 Credits) Particle, deformable and rigid bodies, statics, dynamics, fundamental laws of mechanics,
parallelogram law and triangular law, vector operations; Resultant of coplanar and concurrent
forces; Components of forces in space; Equilibrium of a particle and a rigid body. Trusses, Frames and Machines, analysis of forces in trusses using the method of joints and the
method of sections; Special conditions in truss members: zero-force members; Condition of
statically determinate system; Force analysis in frames and machines.
Internal forces-normal or axial force, shear force, bending moment, torsional moment; Sign
convention for different internal forces; Application of the method of sections to determine
internal forces; Relationship between applied load, shear force, and bending moment; Method
of superposition to obtain shear force diagram and bending moment diagram. Friction: Introduction to the concept of dry friction, Equilibrium of rigid bodies subjected to dry
friction; Examples demonstrating the application of frictions on wedges, screws, belts, and
bearings; Concept of rolling resistance. Center of gravity and centroid; Moment of inertia; Theorems of Pappus and Guldinus; Moment
of inertia for simple geometries; Parallel-axis theorem; Perpendicular-axis theorem; Polar
moment of area; Radius of gyration; Application to Composite areas; Mass moment of inertia.
References: 1. R.C. Hibbeler, “Engineering Mechanics: Statics and Dynamics”, 2010, 12th Edition, Pearson
Prentice Hall, New Jersey, USA. 2. Irving H. Shames, “Engineering Mechanics: Statics and Dynamics”, 1996, 4th Edition, Prentice
Hall, 1989. 3. F. Beer and Jr. E. R. Johnston, “Vector Mechanics for Engineers: Statics and Dynamics”, 2006,
McGraw Hill."
ID1140: Thermodynamics - I (1 Credits) State of a system, 0th law, equation of state; First law - Work, heat, Internal energy; Expansion
work; quasi-static and reversible processes; Open and Closed systems, Enthalpy, Adiabatic
changes; Carnot cycle; Second law - Entropy and the Clausius inequality; Entropy and
irreversibility; Thermodynamic table and charts
References: 1. Thermodynamics: An Engineering Approach, Y. Cengel, McGraw-Hill. 2. Engineering Thermodynamics by P.K. Nag, McGraw-Hill. 3. Thermodynamics by J.P. Holman, McGraw-Hill. 4. Thermodynamics: Concepts and Applications, Stephen R. Turns, Cambridge University Press.
ID1150: Thermodynamics - II (2 Credits) Statements of the second law, heat engines and refrigerators, absolute temperature scale;
Entropy: theoretical development, second law in terms of entropy, the Gibbs equation, entropy
for ideal gases, entropy change for reversible and irreversible processes, tabulation of entropy,
adiabatic reversible processes for ideal gases, entropy of mixing, probabilistic approach;
Second law analysis for control volumes: irreversible entropy production; Cycles: Otto, Diesel,
Rankine, Brayton, refrigeration; Exergy; Maxwell relations, heat capacity, real gas behavior and
non-ideal equations of state; Thermochemistry - Application of first and second laws to
chemical reactions, Calorimetry.
References: 1. Thermodynamics: An Engineering Approach, Y. Cengel, McGraw-Hill. 2. Engineering Thermodynamics, P.K. Nag, McGraw-Hill. 3. Thermodynamics, J.P. Holman, McGraw-Hill. 4. Thermodynamics: Concepts and Applications, Stephen R. Turns, Cambridge University Press. 5. Thermodynamics and its Applications, Jefferson W. Tester and Michael Modell, Prentice Hall. 6. Fundamentals of Thermodynamics, Gordon J. Van Wylen and Richard E. Sonntag, Wiley
Publishers.
ID1160: Solid Mechanics - I (2 Credits) Introduction – Mechanical behaviour of materials, tension, compression and shear stresses,
axially loaded members, torsion, beam bending, transverse shear, combined loading, and
impact loading
References: 1. James M. Gere and Barry J. Goodno, “Mechanics of Materials”, Cengage Learning, India,
2009. 2. Ferdinand Beer, E. Russell Johnston, Jr., John DeWolf and David Mazurek, “Mechanics of
Materials” , 6th ed., Tata-McGraw Hill, India, 2013 . 3. Egor P. Popov, “Engineering Mechanics of Solids”, 2nd ed., Prentice Hall, India, 2013. 4. Ansel C. Ugural, “Mechanics of Materials”, Wiley, 2007. 5. Irving H. Shames and James M. Pitarresi, “Introduction to Solid Mechanics”, 2nd ed.,
Prentice Hall, India, 2013
ID11711: Fabrication Lab - I (2 Credits) Fitting Shop - Dovetail Fitting, V-fitting, U T fit, Joining two pieces (male and female): Welding –
Single V-butt joint, Double lap Joint, Corner joint, T- joint, Edge joint, Gas cutting (Demo):
Machine Shop – Facing & Longitudinal turning, Step & taper turning, Chamfering & drilling:
Electronics Shop – Diode characteristics, Bridge rectifier, LDR Circuit, Connecting resistors:
Electrical Shop – Wiring basics, Stair case wiring, Switch circuits, Characteristics of DC motor.
References: 1. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy, “Elements of Workshop
Technology: Vol 1 - Manufacturing Processes”, Fifteenth Reprint, Media printers and
publishers, India, 2012.
2. A. K. Hajra Choudhury, S. K .Hajra Choudhury and Nirjhar Roy,, “Elements of Workshop
Technology: Vol 2 – Machine Tools”, Fifteenth Reprint, Media printers and publishers, India,
2012. 3. W. A. J. Chapman, “Workshop Technology Part 2”, 4th ed., Elsevier, 1972. 4. A.K. Sawhney and Puneet Sawhney, “A Course in Electrical and Electronic Measurements
and Instrumentation”, Dhanpat Rai Publications, India, 2012.
ID2020: Solid Mechanics - II (2 Credits) Deflections of beams, energy methods, analysis of stress and strain, stress transformation,
applications of plane stress, pressure vessel, column buckling, and statically indeterminate
structures .
References: 1. James M. Gere and Barry J. Goodno, “Mechanics of Materials”, Cengage Learning, India,
2009. 2. Ferdinand Beer, E. Russell Johnston, Jr., John DeWolf and David Mazurek, “Mechanics of
Materials” , 6th ed., Tata-McGraw Hill, India, 2013 . 3. Egor P. Popov, “Engineering Mechanics of Solids”, 2nd ed., Prentice Hall, India, 2013. 4. Ansel C. Ugural, “Mechanics of Materials”, Wiley, 2007. 5. Irving H. Shames and James M. Pitarresi, “Introduction to Solid Mechanics”, 2nd ed.,
Prentice Hall, India, 2013
ID2030: Fluid Mechanics and Rate processes (4 Credits) System vs control volumes; Units and dimensions; Fluid continuum, density, viscosity, surface
tension, velocity, pressure, temperature; Fluid Statics – Hydrostatics, Fluid forces on planes and
curved surfaces, submerged and floating bodies, Buoyancy and stability; Fluid Concepts –
Streamlines, streaklines, pathlines, viscous vs inviscid flows, laminar vs turbulent flows,
compressible vs incompressible flows; Control Volume analysis: Basic laws – Mass conservation
law, Momentum conservation, Angular-Momentum principle. Differential analysis to fluid flow:
Stream-function and velocity potential Continuity, Euler equations, Navier-Stokes equations,
Dimensional analysis – similitude and Wind-tunnel testing; Exact solutions of Navier-Stokes
equations; Internal flows – flows in a pipes and channels, friction factor, flow measurement
devices; External flows – Boundary layer over a flat plate, concept of similarity; Flow
separation; Brief introduction to turbulence – characteristics of turbulence. Heat conduction:
Fourier's law; steady 1-D conduction; thermal resistances; unsteady and steady conduction
equations in several dimensions; boundary conditions; Convection: Nusslet number
significance and correlations; Mass transfer-heat-transfer analogy. Diffusion and convection in
dilute mixtures.
References: 1. Introduction to Fluid Mechanics by R. W. Fox, P. J. Pritchard and A. T. McDonald, Wiley 2. Fluid Mechanics by P. K. Kundu, I. M. Cohen and D. R. Dowling, Academic Press 3. A Textbook on Heat Transfer by S. P. Sukhatme, Universities Press 4. Fundamentals of Heat and Mass Transfer, T. L. Bergman, A. S. Lavine, F. P. Incropera, D. P.
DeWitt, Wiley 5. Heat and Mass Transfer: Fundamentals and Applications, Y. Cengel and A. Ghajar, McGraw-
Hill 6. NPTEL – Fluid Mechanics: http://nptel.ac.in/courses/112105171/ 7. NPTEL – Heat and Mass
Transfer: http://nptel.ac.in/courses/112101097/"
ME1010: Manufacturing Technology (1 Credits) Introduction to Product Design, Introduction to manufacturing, Evolution of manufacturing.
Engineering Materials and their selection, Classification of Manufacturing Processes: Formative
Processes (Molding Processes, Deformation Processes), Additive Processes (Joining and Rapid
Prototyping Processes), Removal Processes (machining, non-conventional), Introduction to
Measurements, Machine Tools and Data Communication, Importance of Integrated Design and
Manufacturing.
References: 1. M. P. Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems,
Third edition. Wiley India Private Limited, 2009. 2. S. Kalpakjian, Manufacturing Processes for Engineering Materials, Fifth edition. Pearson
Education, 2009. 3. G. K. Lal and S. K. Choudhury, Fundamentals Of Manufacturing Process, 2009
ME1020: Dynamics (2 Credits) Kinematics of particles – Rectilinear motion of particles, curvilinear motion of particles,
Kinematics of rigid bodies, Kinetics of particles, system of particles, plan motion of rigid
bodies, energy and momentum methods, kinetics of rigid bodies in three dimensions, and
introduction to mechanical vibrations.
References: 1.Irving H. Shames and G. Krishna Mohana Rao, “Engineering Mechanics- Statics and
Dynamics”, 4th ed., Prentice Hall, India, 2006. 2. R. C. Hibbeler and Ashok Gupta, “Engineering Mechanics- Statics & Dynamics”, 11th ed.,
Prentice Hall, India, 2009.
3. Ferdinand Beer, E. Russell Johnston, Jr., Phillip Cornwell and Dr. Sanghi, “Vector Mechanics
for Engineers – Dynamics”, 10th ed., Tata- McGraw Hill, India, 2013. 4. J. L. Meriam and L. G. Kraige, “Engineering Mechanics: Volume 2 – Dynamics”, 7th ed., John-
Wiley, India, 2013.
ME1121: Engineering Graphics (2 Credits) Review of engineering drawing, introduction to the application of software (SOLID EDGE),
basics of drafting, introduction to various menus of the software, sheet setup, selecting
projection method (first angle, third angle), understanding functions like line, rectangle, circle,
arc, fillet, chamfer, offset, trim, extend, move, rotate, hatch, relations tab. Introduction to 3D
modelling, extrude, sweep, loft, Boolean operations – add, cut, trim, round, springs, patterns
(arrays), datum planes, and associated drawing. Introduction to assembly and assembly
constraints.
References: 1. N. D. Bhatt, “Engineering Drawing: Plane and Solid Geometry”, Charotar Publishing House,
India, 2012. 2. K. Venugopal, “Engineering Drawing + AutoCAD”, New Age International, India, 2013
ME1210: Engineering Mechanics (4 Credits) Definition for rigid body, statics, vector operations, resultant of system of coplanar forces
(parallelogram and triangular construction), free body diagram, resolution of forces in 3D,
equilibrium equation, shear force and bending moment diagram, analysis of trusses – method
of joints and method of sections, stability of trusses, space trusses, mass and geometric
properties of members, centre of gravity and moment of inertia for simple geometries, parallel
and perpendicular axes theorem, kinematics and kinetics of rigid bodies, virtual work done,
energy methods.
References: 1. Irving H. Shames and G. Krishna Mohana Rao, “Engineering Mechanics- Statics and
Dynamics”, 4th ed., Prentice Hall, India, 2006. 2. R. C. Hibbeler and Ashok Gupta, “Engineering Mechanics- Statics & Dynamics”, 11th ed.,
Prentice Hall, India, 2009. 3. Ferdinand Beer, E. Russell Johnston, Jr. and David F. Mazurek, “Vector Mechanics for
Engineers – Statics”, 10th ed., Tata- McGraw Hill, India, 2013. 4. Ferdinand Beer, E. Russell Johnston, Jr., Phillip Cornwell and Dr. Sanghi, “Vector Mechanics
for Engineers – Dynamics”, 10th ed., Tata- McGraw Hill, India, 2013. 5. J. L. Meriam and L. G. Kraige, “Engineering Mechanics: Volume 1 – Statics”, 7th ed., John-
Wiley, India, 2013.
6. J. L. Meriam and L. G. Kraige, “Engineering Mechanics: Volume 2 – Dynamics”, 7th ed.,
John-Wiley, India, 2013.
ID1110: Fluid Mechanics - II (1.5 Credits) Differential analysis to fluid flow: Conservation of Mass – Coordinate systems, Kinematics –
Translation, Rotation, Deformation, derivation of Governing equations of fluid flows –
continuity, Euler equations, Potential flows - Bernoulli equation and applications to external
aerodynamics, Navier-Stokes equations, Non-dimensional analysis; Exact solutions of Navier-
Stokes equations; Internal flows; External flows – Prandtl's Boundary layer theory - flow over a
flat plate, concept of similarity; Approximate methods - von Karman Integral analysis;
(Thwaites method); Flow separation; Brief introduction to turbulence – characteristics of
turbulence, drag crisis.
References: 1. Fluid Mechanics by P. K. Kundu, I. M. Cohen and D. R. Dowling, Academic Press 2. Introduction to Fluid Mechanics by R. W. Fox, P. J. Pritchard and A. T. McDonald, Wiley 3. Fundamental of Fluid Mechanics by B. R. Munson, A. P. Rothmayer, T. H. Okiishi and W. W.
Huebsch, Wiley 4. Multimedia Fluid Mechanics (DVD) by G. M. Homsy et al., Cambridge University Press 5. MIT-OCW, Fluid Mechanics : http://ocw.mit.edu/courses/aeronautics-and-astronautics/16-
01-unified-engineering-i-ii-iii-iv-fall-2005-spring-2006/fluid-mechanics/ 6. NPTEL – Fluid Mechanics: http://nptel.ac.in/courses/112105171/"
ME2030: Manufacturing Science -I (2 Credits) Introduction to Manufacturing and its evolution, Net and near-net shape manufacturing; Metal
Casting: Solidification of Alloys and its mechanism, Gating System Design and Estimation of
Solidification time, Riser Design and Riser Placement, Process Variations, Defects and Product
Design; Metal Forming: Mechanism of plastic deformation, fundamentals of plasticity,
Introduction to Force equilibrium method, State of Stress and boundary conditions in
Upsetting/forging, Rolling, Wire and tube drawing, Extrusion and Deep Drawing, Defects, Load
estimation for one plane strain and one axi-symmetric bulk deformation processes, Analysis of
Deep Drawing and Bending, Introduction to High velocity forming processes; Powder
Processing (Metals and Ceramics), Polymer Part Manufacturing, Introduction and properties of
polymer melts and Visco-elasticity, Processing of Thermoplastics (Extrusion, Injection Molding,
Blow Molding, Rotational Molding) and Thermosets (compression and transfer molding), Tool
and product design principles; Rapid Manufacturing: Need for RP/RT/RM, Introduction to
Processes for Prototyping, Tooling and Manufacturing; Joining and Welding: Introduction, Solid
State and Fusion Joining, Brazing and Soldering, Mechanical and Adhesive Joining, Metal and
nonmetal joining; Metrology: Tolerancing (Dimensional and Geometric) principles and their
measurements (Geometrical tolerances using point data), Interferometry – principles, flatness
testing using optical flat, optical interferometers, Moire fringe system measurements.
References: 1. Ghosh and Mallick A. K., Manufacturing Science. Affiliated East-West Press Pvt. Ltd. 2010. 2. M. P. Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems,
Third edition. Wiley India Private Limited, 2009. 3. S. Kalpakjian, Manufacturing Processes for Engineering Materials, Fifth edition. Pearson
Education, 2009. 4. G. K. Lal and S. K. Choudhury, Fundamentals Of Manufacturing Process, 2009. Boca Raton,
FL: CRC Press, 2011. 5. J.P.Holman, Experimental Methods for Engineers, McGraw Hills Int. Edition. 6. R.K.Jain, Engineering Metrology, Khanna Publishers, 2013.
ME2040: Instrumentation (1.5 Credits) Introduction to measurements, various principles of measurements, errors in measurement,
basic statistics, calibration procedures, displacement measurement, measurement of
temperature, measurement of pressure, measurement of fluid flow, obstruction meters,
measurement of fluid velocities, thermal anemometry, strain gauges, measurement of force,
torque and power, load cells, torque cells, dynamometers, vibration measurement, velocity
and acceleration measurement.
References: 1. Mechanical Measurements by Thomas G. Beckwith, Roy D. Marangoni and John H. Lienhard,
Pearson Prentice Hall, 2007 2. Instrumentation for Engineers and Scientists, John Turner and Martyn Hill, Oxford University
Press , 1999 3. Theory and Design for Mechanical Measurements, Richard S. Figliola and Donald E. Beasley,
John Wiley & Sons (Asia) Pte Ltd, 2008 4. Measurement Systems, Ernets O Doebelin and Dhanesh N Manik, Tata McGraw-Hill, 2007
ME2060: IC Engines - I (1 Credits) Classification, Basic Working Principles, Components of an IC Engine; Engine Operating Events
and Parameters: Geometry, Torque, Power and Work; Fuel Consumption and Efficiencies,
Engine Cycle Models: Basic Thermodynamic Analysis; Air Standard Cycles
References:
1. Heywood, J.B., Internal Combustion Engine Fundamentals, McGraw-Hill 2. Ganesan V., Internal Combustion Engines, Tata McGraw-Hill 3. Stone, R., Introduction to Internal Combustion Engines, PHED
ME2070: Introduction to Mathematical Modelling (1.5 Credits) Introduction to mathematical modelling, introduction to symbolic and numerical computation,
degrees of freedom, modelling in dependent and independent coordinates, lagrange
equations, and numerical solution of mathematical models.
References: 1. Getting Started with MATLAB by Rudra Pratap, Oxford University Press 2. Analytical Dynamics: A New Approach, F. E. Udwadia and R. E. Kalaba, Cambrdge Univerisy
Press 3. Classical mechanics, H Goldstein, C. P. Poole, and J.L. Safko, Pearson
ME2110: Mechanics of Solids (4 Credits) Introduction – Mechanical behaviour of materials, tension, compression and shear stresses,
axially loaded members, torsion, beam bending, transverse shear, combined loading, and
impact loading. Deflections of beams, energy methods, analysis of stress and strain, stress
transformation, applications of plane stress, pressure vessel, column buckling, and statically
indeterminate structures.
References: 1. James M. Gere and Barry J. Goodno, “Mechanics of Materials”, Cengage Learning, India,
2009. 2. Ferdinand Beer, E. Russell Johnston, Jr., John DeWolf and David Mazurek, “Mechanics of
Materials” , 6th ed., Tata-McGraw Hill, India, 2013 . 3. Egor P. Popov, “Engineering Mechanics of Solids”, 2nd ed., Prentice Hall, India, 2013. 4. Ansel C. Ugural, “Mechanics of Materials”, Wiley, 2007. 5. Irving H. Shames and James M. Pitarresi, “Introduction to Solid Mechanics”, 2nd ed.,
Prentice Hall, India, 2013.
ME2120: Thermodynamics (3 Credits) Introduction to thermodynamics. System, surroundings, boundaries, Units and dimensions.
Properties of systems. Equilibrium, processes, interactions. The work interaction.
Thermodynamic definition of work. Adiabatic systems and processes. Adiabatic work. The First
Law. Basic form. Energy of a system. The heat interaction. Diathermic boundary. Zeroth law.
Isothermal states. Gas thermometer. The ideal gas. The state principle. Equations of state.
Properties of gases. Properties of steam. Introduction to steam tables. Other equations of
state. Critical state. Reduced equation of state. First law for open systems. Special cases.
Steady-flow energy equation. The Second Law. Kelvin-Planck and Clausius statements. Carnot
theorem. Thermodynamic temperature. Kelvin scale. Carnot engine. Clausius inequality.
Definition of entropy. Evaluation of entropy. Principle of increase of entropy. Formulation of
second law for closed and open systems. Combined first and second laws. Cycles: Otto, Diesel,
Rankine, Brayton, refrigeration; Availability and Exergy. Lost work. Air-Water mixtures,
Psychrometric tables, Desert coolers.
References: 1. Thermodynamics: An Engineering Approach, Y. Cengel, McGraw-Hill. 2. Engineering Thermodynamics, P.K. Nag, McGraw-Hill. 3. Thermodynamics, J.P. Holman, McGraw-Hill. 4. Thermodynamics: Concepts and Applications, Stephen R. Turns, Cambridge University Press. 5. Thermodynamics and its Applications, Jefferson W. Tester and Michael Modell, Prentice Hall. 6. Fundamentals of Thermodynamics, Gordon J. Van Wylen and Richard E. Sonntag, Wiley
Publishers.
ME2220: Kinematics & Dynamics of Machinery (4 Credits; Both Fractal and Non-Fractal) Basic kinematic concepts, introduction to mechanisms, links, kinematic pairs, kinematic chains,
mechanism and inversions, Kennedy’s theorem, velocity and acceleration in mechanism,
relative velocity methods, instantaneous center of rotation, acceleration diagram, synthesis of
planar mechanisms. Cams: synthesis of translating flat-face, translating roller and oscillating
roller follower cams. gears: terminology, fundamental law of gearing, involute profile,
interference and undercutting, minimum number of teeth, contact ratio, bevel helical, spiral
and worm gears, gear trains – simple, compound and epicyclic gear trains; sliding gear boxes
and synchronous gear boxes. dynamics of machines: dynamics of rigid bodies in plane motion;
dynamic force analysis of machines. Flywheels, balancing of rotors and in-line internal
combustion engines, Chain and belt drive.
References: 1. R L Norton “Kinematics & Dynamics of Machinery” McGraw- Hill companies, 2009 2. Kenneth J. Waldron and Gary L. Kinzel, “Kinematics, Dynamics and Design of Machinery”,
Wiley India Edition 3. Amitabha Ghosh, Ashok Kumar Malik, “Theory of Mechanisms and Machines”, East-West
Press Private Limited, New Delhi, 2004. 4. John J. Uicker, Gordon R. Pennock, Joseph E. Shigley, “Theory of Machines and
Mechanisms”, Oxford University Press, New Delhi, 2009.
5. S. S. Rattan, “Theory of Machines”, Tata-McGraw Hill Eductaion Private Ltd, New Delhi, 2009.
6. David H. Myszka, “Machines and Mechanisms”, Prentice-Hall Inc (PHI) Learning Private
Limited, New Delhi, 2009.
ME2230: Manufacturing Science -1 (3 Credits) Introduction to Manufacturing and its evolution, Net and near-net shape manufacturing; Metal
Casting: Solidification of Alloys and its mechanism, Gating System Design and Estimation of
Solidification time, Riser Design and Riser Placement, Process Variations, Defects and Product
Design; Metal Forming: Mechanism of plastic deformation, fundamentals of plasticity,
Introduction to Force equilibrium method, State of Stress and boundary conditions in
Upsetting/forging, Rolling, Wire and tube drawing, Extrusion and Deep Drawing, Defects, Load
estimation for one plane strain and one axi-symmetric bulk deformation processes, Analysis of
Deep Drawing and Bending, Introduction to High velocity forming processes; Powder
Processing (Metals and Ceramics), Polymer Part Manufacturing, Introduction and properties of
polymer melts and Visco-elasticity, Processing of Thermoplastics (Extrusion, Injection Molding,
Blow Molding, Rotational Molding) and Thermosets (compression and transfer molding), Tool
and product design principles; Rapid Manufacturing: Need for RP/RT/RM, Introduction to
Processes for Prototyping, Tooling and Manufacturing; Joining and Welding: Introduction, Solid
State and Fusion Joining, Brazing and Soldering, Mechanical and Adhesive Joining, Metal and
nonmetal joining; Metrology: Tolerancing (Dimensional and Geometric) principles and their
measurements (Geometrical tolerances using point data), Interferometry – principles, flatness
testing using optical flat, optical interferometers, Moire fringe system measurements.
References: 1. Ghosh and Mallick A. K., Manufacturing Science. Affiliated East-West Press Pvt. Ltd. 2010. 2. M. P. Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems,
Third edition. Wiley India Private Limited, 2009. 3. S. Kalpakjian, Manufacturing Processes for Engineering Materials, Fifth edition. Pearson
Education, 2009. 4. G. K. Lal and S. K. Choudhury, Fundamentals Of Manufacturing Process, 2009. Boca Raton,
FL: CRC Press, 2011. 5. J.P.Holman, Experimental Methods for Engineers, McGraw Hills Int. Edition. 6. R.K.Jain, Engineering Metrology, Khanna Publishers, 2013.
ME2411: ME Lab I (Fluid & Solid Mechanics) (2 Credits) Fluid Mechanics: Measurement of fluid properties: density, specific gravity and viscosity;
Measurement of pressure: Manometers, Bourdon pressure gauge; Measurement of discharge
coefficient: Venturi meter, Orifice meter, Rota meter and V/Rectangular notches; Friction loss
coefficients in pipe flows: Impact of water jet and stability of floating bodies; channel flow. Solid Mechanics: Torsion testing, UTM-tensile testing, thin cylinder behavior, buckling of struts,
deflection of beams, spring stiffness, impact testing and hardness testing
ME2421: Solid Mechanics Lab (1 Credits) Solid Mechanics: Torsion testing, UTM-tensile testing, thin cylinder behavior, buckling of struts,
deflection of beams, spring stiffness, impact testing and hardness testing.
ME2431: Fluid Mechanics Lab (1 Credits) Fluid Mechanics: Measurement of fluid properties: density, specific gravity and viscosity,
surface tension; Measurement of pressure: Manometers, Bourdon pressure gauge;
Measurement of discharge coefficient: Venturi meter, Orifice meter, Rota meter and
V/Rectangular notches; Friction loss coefficients in pipe flows: Impact of water jet and stability
of floating bodies; channel flow.
ME3010: Manufacturing Science - II (2 Credits) Conventional Removal and Finishing Processes: Importance of Material Removal and allied
processes, classification; Chip Formation; Types of Chips; Tool Specification: Coordinate and
Orthogonal Systems; Mechanics of Metal Cutting: Merchant’s Circle Diagram, Stress, Strain and
Strain Rate, determination of Shear Plane Angle; Tool Wear and Tool Life; Variables affecting
Tool Life; Practical Machining Operations: Turning, drilling, milling; Finishing Operations:
Grinding (MRR estimation, Wheel Specifications, Wheel Wear) and other processes; Economics
of machining: Minimum Production Cost Criterion, Maximum Production Rate and Maximum
Profit Rate Criteria; Unconventional Removal and Finishing Processes: Abrasive Jet Machining,
Ultrasonic Machining; Electro Discharge Machining; Abrasive Jet Machining; Electron Beam
Machining; Laser Beam Machining, Finishing processes (AFM and other variants); Micro-
Manufacturing and Scaling Laws: Miniaturization and its importance, Micro-Manufacturing
Processes (Additive, formative and Removal), Scaling laws with emphasis on micro-
Manufacturing.
References: 1. Ghosh and Mallick A. K., Manufacturing Science. Affiliated East-West Press Pvt. Ltd. 2010. 2. M. P. Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems,
Third edition. Wiley India Private Limited, 2009. 3. S. Kalpakjian, Manufacturing Processes for Engineering Materials, Fifth edition. Pearson
Education, 2009.
4. G. K. Lal and S. K. Choudhury, Fundamentals Of Manufacturing Process, 2009 5. M. J. Madou, Fundamentals of Microfabrication and Nanotechnology, 3rd Edition, CRC Press,
2011.
ME3020: IC Engines - II (3 Credits) Thermochemistry for IC Engines: Fuels and Testing; Combustion Reactions; Combustion
Efficiencies; Chemical Kinetics and Exhaust Gas Analysis, Engine Cycle Models: Fuel-Air
Standard Cycles; Comparisons to Real Engines Cycles, Intake Flow Considerations: Gas Flow
Processes; Valve Design; Fuel Induction Processes for SI and CI Engines, Combustion Chamber
Considerations: In-cylinder Aerodynamics; Burning Process for SI and CI Engines; Abnormal
combustion in SI Engines (Knock), Pollutant Formation and Control: Emission Measurement –
NOx, CO, Unburned Hydrocarbon, Particulates, formation and their control, New Combustion
Concepts in IC Engines - Gasoline Direct Injection, Homogeneous Charge Compression Ignition,
Dual Fuel Ignition, Renewable Fuels for IC Engines
References: 1. Heywood, J.B., Internal Combustion Engine Fundamentals, McGraw-Hill 2. Ganesan V., Internal Combustion Engines, Tata McGraw-Hill 3. Stone, R., Introduction to Internal Combustion Engines, PHED 4. Taylor, C.F., Internal Combustion Engine in Theory and Practice, Vol 1 & 2, MIT Press 5. Baumgarten, C., Mixture Formation in Internal Combustion Engines, Springer Berlin
Heidelberg 6. Hiereth, H., Prenninger, P., Drexl, K., Charging The Internal Combustion Engine, Springer
ME3030: Modeling & Simulation (3 Credits) Introduction to modelling and simulation, introduction to symbolic and numerical
computations, degrees of freedom, modelling in dependent and independent coordinates,
Lagrange equations, state space formulation, Newton-Raphson method, explicit integrator,
implicit integrator, dynamics of constrained mechanical systems as differential algebraic
equations, Baumgaurte stabilization, Gauss principle, and inverse problems.
References: 1. Getting Started with MATLAB by Rudra Pratap, Oxford University Press 2. Analytical Dynamics: A New Approach, F. E. Udwadia and R. E. Kalaba, Cambridge University
Press 3. Classical mechanics, H Goldstein, C. P. Poole, and J.L. Safko, Pearson
ME3040: Mathematical Elements for Geometrical Modeling (1.5 Credits) Introduction to computer aided design, fundamentals of computer graphics; geometric
modelling of synthetic curves: Hermite, Bezier, B-spline, NURBS. Parametric representation of
surfaces: plane, ruled, revolution; Part modelling techniques: wireframe, surface and solid
modelling, data representation and exchange formats, geometry and topology. Three-
dimensional transformations and projections.
References: 1. Groover, M. CAD/CAM. First edition. Delhi: Pearson Education, 2003. 2. Lee, Kunwoo. Principles of CAD/CAM/CAE. 1 edition. Reading, Mass: Prentice Hall, 1999. 3. Rao, P. N. CAD/CAM: Principles and Applications. 3 edition. New Delhi: Mcgraw-Hill
Education, 2010. 4. Zeid, Ibrahim, and R. Sivasubramanian. CAD/CAM: THEORY & PRACTICE: Special Indian
Edition. 2 edition. New Delhi: Tata McGraw Hill Education, 2009.
ME3050: Computer Integrated Manufacturing (1.5 Credits) Current developments in CAD- feature based modeling, design by feature, function, feature
linkages, application of feature based models, parametric modeling; Computer Aided
Manufacturing: fundamentals of part programming, path generation, post processing and
verification; Group Technology, Computer aided process planning (CAPP), computer aided
inspection & reverse engineering, manufacturing process simulation, virtual & distributed
manufacturing, computer integrated manufacturing.
References: 1. Groover, M. CAD/CAM. First edition. Delhi: Pearson Education, 2003. 2. Lee, Kunwoo. Principles of CAD/CAM/CAE. 1 edition. Reading, Mass: Prentice Hall, 1999. 3. Rao, P. N. CAD/CAM: Principles and Applications. 3 edition. New Delhi: Mcgraw-Hill
Education, 2010. 4. Zeid, Ibrahim, and R. Sivasubramanian. CAD/CAM: THEORY & PRACTICE: Special Indian
Edition. 2 edition. New Delhi: Tata McGraw Hill Education, 2009.
ME3060: Experimental Testing Techniques (1 Credits) Basics of statistics. Determining the sample size, hypothesis testing and confidence intervals.
Design of experiments, curve fitting and regression analysis, error analysis, practical aspects to
documenting, interpreting and reporting experimental data. Data Acquisition and Processing.
Data interpretation using graphical tools. Case studies.
References: 1. Kiemele, Mark J. Basic Statistics: Tools for Continuous Improvement. 4 edition. Colorado
Springs, Colo.: Air Academy Press, 1997. 2. Holman, J. P., Experimental Methods for Engineers, Mc-Graw Hill, 7th Ed, Singapore, 2001. 3. Montgomery, Douglas C. Design and Analysis of Experiments: International Student Version.
Eighth edition. Wiley India Private Limited, 2013. 4. E.O.Doeblin, Engineering Experimentation, McGraw Hills Int. Edition.
ME3110: Heat & Mass transfer (3 Credits; Both Fractal and Non-Fractal) Introduction – Steady State heat conduction in one-dimensional systems. One dimensional
unsteady state conduction; extended surface heat transfer (Fins). Convection: Basic equations,
Dimensional analysis, Boundary layers; Forced convection: External and internal flows,
correlations, Natural convection and Mixed convection. Design of heat exchangers: LMTD and
NTU methods. Radiation heat transfer: Basic laws, Properties of surfaces, view factors, network
method and enclosure analysis for gray-diffuse enclosures containing transparent media.
Concepts of Mass transfer. Current trends of research in the field of heat transfer.
References: 1. Fundamentals of Heat and Mass transfer, Frank P Incropera and David P Dewitt, Wiley –
India edition, 5th edition- 2009. 2. Heat transfer, J. P. Holman, Tata-Mc-Graw Hill, New Delhi, 9th edition- 2009. 3. Heat and Mass transfer - A Practical approach, Yunus A Cengel, Tata-Mc-Graw Hill education
private Limited, New Delhi, 2009. 4. Process Heat Transfer, Donald Q. Kern, McGraw-Hill.
ME3120: Manufacturing Science -2 (3 Credits) Conventional Removal and Finishing Processes: Importance of Material Removal and allied
processes, classification; Chip Formation; Types of Chips; Tool Specification: Coordinate and
Orthogonal Systems; Mechanics of Metal Cutting: Merchant’s Circle Diagram, Stress, Strain and
Strain Rate, determination of Shear Plane Angle; Tool Wear and Tool Life; Variables affecting
Tool Life; Practical Machining Operations: Turning, drilling, milling; Finishing Operations:
Grinding (MRR estimation, Wheel Specifications, Wheel Wear) and other processes; Economics
of machining: Minimum Production Cost Criterion, Maximum Production Rate and Maximum
Profit Rate Criteria; Unconventional Removal and Finishing Processes: Abrasive Jet Machining,
Ultrasonic Machining; Electro Discharge Machining; Abrasive Jet Machining; Electron Beam
Machining; Laser Beam Machining, Finishing processes (AFM and other variants); Micro-
Manufacturing and Scaling Laws: Miniaturization and its importance, Micro-Manufacturing
Processes (Additive, formative and Removal), Scaling laws with emphasis on micro-
Manufacturing.
References: 1. Ghosh and Mallick A. K., Manufacturing Science. Affiliated East-West Press Pvt. Ltd. 2010. 2. M. P. Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems,
Third edition. Wiley India Private Limited, 2009. 3. S. Kalpakjian, Manufacturing Processes for Engineering Materials, Fifth edition. Pearson
Education, 2009. 4. G. K. Lal and S. K. Choudhury, Fundamentals Of Manufacturing Process, 2009 5. M. J. Madou, Fundamentals of Microfabrication and Nanotechnology, 3rd Edition, CRC Press,
2011.
ME3130: Design of Machine Elements (4 Credits; Both Fractal and Non-Fractal) Design consideration – limits, fits, tolerances, and standardization, a brief introduction to
strength of materials, modes of failure, failure theories, design of shafts under static and
fatigue loadings, design of springs – helical, compression, tension, torsional and leaf springs,
design of joints – threaded fasteners, preloaded bolt joints, welded and glued joints, design
and analysis of sliding and rolling contact bearings, analysis and applications of power screws
and couplings, analysis of clutches and brakes, design of belt and chain drives, design of spur
and helical gears.
References: 1. Norton, "Machine Design”, Pearson. 2. Shigley, “Mechanical Engineering Design”, McGraw-Hill. 3. V. B. Bhandari, "Design of Machine Elements," Tata McGraw-Hill.
ME3140: IC Engines (3 Credits) Classification, Basic Working Principles, Components and Engine Operating Events of an IC
Engine; Engine Operating Parameters: Geometry, Torque, Power and Work; Fuel Consumption
and Efficiencies; Thermochemistry for IC Engines: Fuels and Testing; Combustion Reactions;
Combustion Efficiencies; Chemical Kinetics and Exhaust Gas Analysis; Engine Cycle Models:
Basic Thermodynamic Analysis; Air Standard Cycles; Fuel-Air Standard Cycles; Comparisons to
Real Engines Cycles; Intake Flow Considerations: Gas Flow Processes; Valve Design; Fuel
Induction Processes for SI and CI Engines; Combustion Chamber Considerations: In-cylinder
Aerodynamics; Burning Process for SI and CI Engines; Abnormal combustion in SI Engines
(Knock); Pollutant Formation and Control: Emission Measurement; NOx, CO, Unburned
Hydrocarbon, Particulates, formation and their control
References: 1. Heywood, J.B., Internal Combustion Engine Fundamentals, McGraw-Hill 2. Ganesan V., Internal Combustion Engines, Tata McGraw-Hill 3. Stone, R., Introduction to Internal Combustion Engines, PHED 4. Taylor, C.F., Internal Combustion Engine in Theory and Practice, Vol 1 & 2, MIT Press 5. Baumgarten, C., Mixture Formation in Internal Combustion Engines, Springer Berlin
Heidelberg 6. Hiereth, H., Prenninger, P., Drexl, K., Charging The Internal Combustion Engine, Springer
ME3210: Instrumentation & Control (3 Credits) Introduction to measurements, various principles of measurements, errors in measurement,
basic statistics, calibration procedures, displacement measurement, measurement of
temperature, measurement of pressure, measurement of fluid flow, obstruction meters,
measurement of fluid velocities, thermal anemometry, strain gauges, measurement of force,
torque and power, load cells, torque cells, dynamometers, vibration measurement, velocity
and acceleration measurement. Concept of control, modeling physical systems, Laplace
transforms and transfer function, block diagrams, Routh’s stability criterion, transient and
steady state response specification, root locus analysis, lead, lag, and lead-lag compensator
design through root locus – P, PI, PD, and PID controllers.
References: 1. K. Ogata, Modern Control Engineering, Prentice Hall. 2. Farid Golnaraghi, and Benjamin C. Kuo, Automatic Control Systems, Wiley. 3. Goodwin, Graebe, and Salgado, Control System Design, Prentice Hall. 4. Mechanical Measurements by Thomas G. Beckwith, Roy D. Marangoni and John H. Lienhard,
Pearson Prentice Hall, 2007 5. Instrumentation for Engineers and Scientists, John Turner and Martyn Hill, Oxford University
Press , 1999 6. Theory and Design for Mechanical Measurements, Richard S. Figliola and Donald E. Beasley,
John Wiley & Sons (Asia) Pte Ltd, 2008 7. Measurement Systems, Ernets O Doebelin and Dhanesh N Manik, Tata McGraw-Hill, 2007
ME3220: Production Engineering (3 Credits) Mathematical tools: Basics of probability and statistics, Linear Programming and applications,
Queuing theory and its applications, forecasting approaches, Monte Carlo simulation; Quality
management and control: Quality Improvement, Cost of Quality, Statistical Process Control,
Central Tendency & Dispersion, Control Charts, Acceptance Sampling, New Quality Concepts,
Taguchi Methods, Design of Experiments (DoE), Robust Design, Ishikawa Diagram, ISO
certification, Kaizen, Zero Defects Program, Total Quality Management (TQM), Six Sigma;
Product Design: Design for Manufacture and Assembly (DFM), Concurrent engineering; Work
systems design: Work study and classifications, Method study – work measurement, work
sampling, Cost Estimation, Calculation of Machining Times, Cost Depreciation, Productivity,
Productivity Measurement, Time study, Recording Techniques for Work Study, Information
Collection Techniques, Job Evaluation, Ranking system, Incentive Schemes, Individual-Group-
Company-wide Bonus Schemes, Behavioural aspects of Incentives; Maintenance Management:
Preventive and breakdown maintenance approaches, reliability, Work study for Maintenance,
Total Productive Maintenance (TPM), Spare Parts Management, Characteristics and
classification of Spare parts; Supply Chain design, scheduling, layout design: Materials
Requirement Planning (MRP), MRP-II, Enterprise Resource Planning (ERP), Logistics,
Distribution and Supply chain Management, Inventory Planning & Control, Deterministic and
Probabilistic Models, Economic Order Quantity (EOQ), Plant layout, Ergonomics, CRAFT,
Cellular Manufacturing, Scheduling, Assembly Line Balancing, Future directions in Production.
References: 1. R. Dan Reid, Nada R. Sanders, “Operations Management - An Integrated Approach”, 5th
Edition, Wiley Publications 2010 2. David Simchi-Levi, Philip Kaminsky, Edith Simchi-Levi, Ravi Shankar, “ Designing and
Managing the Supply Chain – Concepts, Strategies and Case Studies”, 3rd Edition (Special
Indian Edition), McGraw Hill Education,2008 3. S. N. Chary, “Production and Operations Management”,3rd Edition, Tata McGraw Hill
Publishers, 2004 4. Eric. V. Denardo, "The Science of Decision Making: A Problem based approach using Excel",
John Wiley and Sons
5. MIT OpenCourseware 2.854/2.853 Introduction to Manufacturing Systems
http://ocw.mit.edu/courses/mechanical-engineering/2-854-introduction-to-manufacturing-
systems-fall-2010/index.htm
6. MIT OpenCourseWare 2.830J/ 6.780J / ESD.63J Control of Manufacturing Processes (SMA
6303) http://ocw.mit.edu/courses/mechanical-engineering/2-830j-control-of-manufacturing-
processes-sma-6303-spring-2008/
ME3230: Turbo Machines (3 Credits) Axial and radial flow turbomachines; Basic Principles; Dimensional Analysis; Two-dimensional
cascades; Axial flow turbines; Axial flow compressors and ducted fans; Centrifugal pumps,
Fans, compressors; Radial flow gas turbines; Hydraulic turbines.
References:
1. Fluid Mechanics and Thermodynamics of Turbomachinery, Dixon, S.L., Hall, C.A., Elsevier 2. Principles of Turbomachinery, Turton, R.K., Chapman & Hall.
ME3311: ME Lab II (FEM & CFD) (2 Credits) Finite element methods for solving boundary value problems in solid mechanics. Introduction,
Spatial Modelling, Geometric discretization, Element Library, Material Modelling, Loading and
Boundary Conditions, Constraints, Surface/Interfaces modelling, Step and job handling and
Post-processing. FEA Implementation and Visualization of 1D Problems, Truss Problem, Beam
bending, Plane and axisymmetric Problems and 3D problems. Various analysis such as, Static,
Transient, Harmonic, Modal, Dynamics and Multi Physics (Thermomechanical, etc). CFD mesh generation techniques, CFD experiments using commercial code - boundary layer
flow, convective heat transfer, turbulent mixing and heat transfer, at least one analysis on an
advanced topic like multiphase flow, combustion, turbo-machines.
ME3413: Machine Drawing & Solid Modelling (3 Credits) Principle of drawing. Introduction to machine drawing, production drawing, assembly drawing.
Different sectional views. Fits, limits, tolerances and surface finish. Solid modelling of different
machine elements. Example, threads, bolts, and nuts, welded and riveted joints, shafts, keys,
cotter, and pin joints; couplings and clutches, springs, belts, and pulleys; bearings, gears.
Assembly of different components of IC engine.
References: 1. K. L. Narayana, P. Kannaiah, K. Venkata Reddy, Machine Drawing, New Age International,
2010.
2. N. D. Junnarkar, Machine DrawingPearson Education India, 2007.
3. Engine model resources: http://grabcad.com/
ME3413: Machine Drawing & Solid Modelling (2 Credits in Fractal, 3 credits in Non-Fractal;
Both Fractal and Non-Fractal) Principle of drawing. Introduction to machine drawing, production drawing, assembly drawing.
Different sectional views. Fits, limits, tolerances and surface finish. Solid modelling of different
machine elements. Example, threads, bolts, and nuts, welded and riveted joints, shafts, keys,
cotter, and pin joints; couplings and clutches, springs, belts, and pulleys; bearings, gears.
Assembly of different components of IC engine.
References: 1. K. L. Narayana, P. Kannaiah, K. Venkata Reddy, Machine Drawing, New Age International,
2010.
2. N. D. Junnarkar, Machine DrawingPearson Education India, 2007.
3. Engine model resources: http://grabcad.com/
ME3425: Mini-project (3 Credits; Both Fractal and Non-Fractal) Objective: To direct students toward the process of designing and development through
visualization, planning and manufacturing of a product leading to ‘Invention and Innovation’.
Deliverables: Visualize, Draw, Build, Improve, Modify, Identify, Suggest. Constituents: Concept,
Design (Mechanical, thermal, chemical), Drawing (2D/3D manufacturing details),
Manufacturing, Testing, Simulation.
ME3431: ME Lab III (Metrology & IC Engines) (2 Credits) Metrology Lab: Job preparation using CNC machining, Robotic welding, 3D printing, EDM,
Injection molding. Measurements of parts using CMM; Form measurement; Digitization using
3D scanner, surface roughness testing. Deep drawing using forming machine. Cutting force
measurement using dynamometer. Sample preparation and characterization using Optical
Microscope. IC Engines: Objective: Experimental exposure to testing performance of IC engines at varying
operating conditions. Experiment list: Components of an IC engine - CI and SI types; Testing & performance of IC
engines by varying speed, load, compression ratio and other parameters. Study of Valve Timing
Diagram.
ME3445: Finite Element Methods Lab (1 Credits) Finite element methods for solving boundary value problems in solid mechanics. Introduction,
Spatial Modelling, Geometric discretization, Element Library, Material Modelling, Loading and
Boundary Conditions, Constraints, Surface/Interfaces modelling, Step and job handling and
Post-processing. FEA Implementation and Visualization of 1D Problems, Truss Problem, Beam
bending, Plane and axisymmetric Problems and 3D problems. Various analysis such as, Static,
Transient, Harmonic, Modal, Dynamics and Multi Physics (Thermomechanical, etc).
References: ANSYS/ABAQUS Documentation
ME3455: Computational Fluid Dynamics Lab (1 Credits) CFD mesh generation techniques, CFD experiments using commercial code - boundary layer
flow, convective heat transfer, turbulent mixing and heat transfer, at least one analysis on an
advanced topic like multiphase flow, combustion, turbo-machines.
ME3465: Manufacturing Lab (1 Credits) Job preparation using CNC machining, Robotic welding, 3D printing, EDM, Injection molding.
Measurements of parts using CMM; Form measurement; Digitization using 3D scanner, surface
roughness testing. Deep drawing using forming machine. Cutting force measurement using
dynamometer. Sample preparation and characterization using Optical Microscope.
ME3475: IC Engines Lab (1 Credits) Objective: Experimental exposure to testing performance of IC engines at varying operating
conditions. Experiment list: Components of an IC engine - CI and SI types; Testing & performance of IC
engines by varying speed, load, compression ratio and other parameters. Study of Valve Timing
Diagram.
References: 1. VCR Engine manual that includes experimental procedures to follow, specifications of
various equipments, and theoretical calculation procedures and formulae. 2. Internal Combustion Engine fundamentals, J.B. Haywood, McGraw-Hill.
ME4010: Control Systems (1.5 Credits) Concept of control, modeling physical systems, Laplace transforms and transfer function, block
diagrams, Routh’s stability criterion, transient and steady state response specification, root
locus analysis, lead, lag, and lead-lag compensator design through root locus – P, PI, PD, and
PID controllers.
References: 1. K. Ogata, Modern Control Engineering, Prentice Hall. 2. Farid Golnaraghi, and Benjamin C. Kuo, Automatic Control Systems, Wiley. 3. Goodwin, Graebe, and Salgado, Control System Design, Prentice Hall.
ME4020: Turbo Machines (3 Credits) Axial and radial flow turbomachines; Basic Principles; Dimensional Analysis; Two-dimensional
cascades; Axial flow turbines; Axial flow compressors and ducted fans; Centrifugal pumps,
Fans, compressors; Radial flow gas turbines; Hydraulic turbines.
References: 1. Dixon, S.L., Hall, C.A., Fluid Mechanics and Thermodynamics of Turbomachinery, Elsevier 2. Turton, R.K., Principles of Turbomachinery, Chapman & Hall
ME4030: Operations Research (1 Credits) Basics of probability and statistics, Linear Programming and applications, Queuing theory and
its applications, forecasting approaches, Monte Carlo simulation procedure (OR). Inventory
models discussion (deterministic and probabilistic Models), Newsvendor model, Inventory
Planning & Control, Decision support system tools, Economic Order Quantity (EOQ).
References: 1. Eric. V. Denardo, "The Science of Decision Making: A Problem based approach using Excel",
John Wiley and Sons 2. MIT OpenCourseware 2.854/2.853 Introduction to Manufacturing Systems
http://ocw.mit.edu/courses/mechanical-engineering/2-854-introduction-to-manufacturing-
systems-fall-2010/index.htm
ME4040: Industrial Engineering (1 Credits) Product Design: Design for Manufacture and Assembly (DFM), Concurrent engineering Work
systems design: Work study and classifications, Method study – work measurement, work
sampling, Cost Estimation, Calculation of Machining Times, Cost Depreciation, Productivity,
Productivity Measurement, Time study, Recording Techniques for Work Study, Information
Collection Techniques, Job Evaluation, Ranking system, Incentive Schemes, Individual-Group-
Company-wide Bonus Schemes, Behavioural aspects of Incentives Plant layout, Ergonomics,
CRAFT, Cellular Manufacturing, Scheduling, Assembly Line Balancing, Future directions in
Production.
References: 1. R. Dan Reid, Nada R. Sanders, “Operations Management - An Integrated Approach”, 5th
Edition, Wiley Publications 2010 2. S. N. Chary, “Production and Operations Management”,3rd Edition, Tata McGraw Hill
Publishers, 2004
ME4050: Production Planning & Control (1 Credits) Quality management and control: Quality Improvement, Cost of Quality, Statistical Process
Control, Central Tendency & Dispersion, Control Charts, Acceptance Sampling, New Quality
Concepts, Taguchi Methods, Design of Experiments (DoE), Robust Design, Ishikawa Diagram,
ISO certification, Kaizen, Zero Defects Program, Total Quality Management (TQM), Six Sigma;
Maintenance Management: Preventive and breakdown maintenance approaches, reliability,
Work study for Maintenance, Total Productive Maintenance (TPM), Spare Parts Management,
Characteristics and classification of Spare parts; Supply Chain design, scheduling, layout design:
Materials Requirement Planning (MRP), MRP-II, Enterprise Resource Planning (ERP), Logistic,
Distribution and Supply chain Management, Applications of Newsvendor model in supply
chains.
References: 1.R. Dan Reid, Nada R. Sanders, “Operations Management - An Integrated Approach”, 5th
Edition, Wiley Publications 2010 2. David Simchi-Levi, Philip Kaminsky, Edith Simchi-Levi, Ravi Shankar, “ Designing and
Managing the Supply Chain – Concepts, Strategies and Case Studies”, 3rd Edition (Special
Indian Edition), McGraw Hill Education, 2008 3. MIT OpenCourseWare 2.830J/ 6.780J / ESD.63J Control of Manufacturing Processes (SMA
6303) http://ocw.mit.edu/courses/mechanical-engineering/2-830j-control-of-manufacturing-
processes-sma-6303-spring-2008/
ME4110: CAD/CAM (3 Credits) Introduction to computer aided design, fundamentals of computer graphics; geometric
modelling of synthetic curves: Hermite, Bezier, B-spline, NURBS. Parametric representation of
surfaces: plane, ruled, revolution; Part modelling techniques: wireframe, surface and solid
modelling, data representation and exchange formats, geometry and topology. Three-
dimensional transformations and projections. Current developments in CAD- feature based modeling, design by feature, function, feature
linkages, application of feature based models, parametric modeling; Computer Aided
Manufacturing: fundamentals of part programming, path generation, post processing and
verification; Group Technology, Computer aided process planning (CAPP), computer aided
inspection & reverse engineering, manufacturing process simulation, virtual & distributed
manufacturing, computer integrated manufacturing.
References: 1. Groover, M. CAD/CAM. First edition. Delhi: Pearson Education, 2003.
2. Lee, Kunwoo. Principles of CAD/CAM/CAE. 1 edition. Reading, Mass: Prentice Hall, 1999. 3. Rao, P. N. CAD/CAM: Principles and Applications. 3 edition. New Delhi: Mcgraw-Hill
Education, 2010. 4. Zeid, Ibrahim, and R. Sivasubramanian. CAD/CAM: THEORY & PRACTICE: Special Indian
Edition. 2 edition. New Delhi: Tata McGraw Hill Education, 2009.
ME4120: Modeling & Simulation (3 Credits) Introduction to modelling and simulation, introduction to Matlab, degrees of freedom,
modelling in dependent and independent coordinates, Lagrange equations, state space
formulation, Newton-Raphson method, explicit integrator, implicit integrator, dynamics of
constrained mechanical systems as differential algebraic equations, Baumgaurte stabilization,
Gauss principle, and inverse problems.
References: 1. Getting Started with MATLAB by Rudra Pratap, Oxford University Press 2. Analytical Dynamics: A New Approach, F. E. Udwadia and R. E. Kalaba, Cambrdge Univerisy
Press 3. Classical mechanics, H Goldstein, C. P. Poole, and J.L. Safko, Pearson
ME4311: ME Lab IV (Dynamics + Heat Transfer) (2 Credits) Dynamics Lab: Gear Efficiency Measurement, Planar Mechanism Demonstration, Rotary
Balancing, Reciprocating Balancing, Static and Dynamic Analysis of Cam, Whirling of Shaft,
Governors, Moment of inertia measurement. Heat Transfer: Temperature measurement and calibration: Measurement of thermal
conductivity: solids and liquids; Heat exchangers: Concentric tube; shell and tube;
Measurement of convective heat transfer coefficient: Free and Forced convection;
measurement of emissivity; Pool boiling and Condensation.
References: 1. Frank P Incropera and David P Dewitt, “Fundamentals of Heat and Mass transfer” Wiley –
India edition, Fifth edition- 2009. 2. J. P. Holman, “Heat transfer” Tata-Mc-Graw Hill education private Limited, New –Delhi,
Ninth edition- 2009."
ME4435: Dynamics lab (1 Credits)
Gear Efficiency Measurement, Planar Mechanism Demonstration, Rotary Balancing,
Reciprocating Balancing, Static and Dynamic Analysis of Cam, Whirling of Shaft, Governors,
Moment of Inertia Measurement
ME4445: Heat Transfer lab (1 Credits) Heat Transfer: Temperature measurement and calibration; Measurement of thermal
conductivity: solids and liquids; Heat exchangers: Concentric tube, shell and tube;
Measurement of convective heat transfer coefficient: Free and Forced convection;
Measurement of emissivity; Pool boiling and Condensation.
References: 1. Fundamentals of Heat and Mass transfer, Frank P Incropera and David P Dewitt, Wiley –
India edition, 5th edition- 2009. 2. Heat transfer, J. P. Holman, Tata-Mc-Graw Hill, New Delhi, 9th edition- 2009.
ME5010: Mathematical Methods for Engineers (3 Credits) Vectors, operations and operators, identities; Cartesian tensors: definition, notation,
transformation matrix, orthogonal properties, order of a tensor, operations, contraction,
quotient rule, vector identities and theorems in tensor form. First and second order ODEs, linear ODEs with constant coefficients; Laplace transforms;
Second order linear homogenous differential equations and their solutions; Sturm-Liouville
problem; orthogonal functions; Gram-Schmidt procedure PDEs: Classification of PDEs, analytical solution of linear PDEs, Fourier series, and Fourier
transforms transformation of PDEs between different coordinate systems. Linear algebraic equations: matrix form, matrix operations, determinants, Cramer’s rule,
Inverse, singularity, inconsistent equations, Gauss elimination, Gauss-Seidel, LU decomposition,
finding inverses, echelon form, general solution for under-determined systems, generalized
inverses, least-squares solution for over-determined systems, eigen-values and eigenvectors,
orthogonalization, singular value decomposition (without proof) Introduction to Integral equations, classifications, solution methodology. Function, functional
and an introduction to integral of calculus, Euler-Lagrange equation.
References: 1. Aristotle D. Michal, Matrix and Tensor Calculus: With Applications to Mechanics, Elasticity
and Aeronautics, 2008, Dover 2. Rutherford Aris, Vectors, Tensors and the Basic Equations of Fluid Mechanics, 1990, Dover. 3. A.I. Borissenko and I.E. Tarapov, Vector and Tensor Analysis with Applications, 1979, Dover. 4. Donald Danielson, Vectors and Tensors in Engineering and Physics: 2nd Edition, 2003,
Westview Press, 2nd Edition.
5. David Kay, Schaums Outline of Tensor Calculus, 2011, McGraw Hill. 6. Bhaskar Dasgupta, Applied Mathematical Methods, 2007, Pearson Education. 7. Erwin Kreyszig, Advanced Engineering Mathematics, Edition: 10th , John Wiley & Sons 8. S.D. Joglekar, Mathematical Physics: The Basics, 2011, Universities Press (India) Private
Limited. 9. Alan J. Laub, Matrix Analysis for Scientists and Engineers, Society for Industrial and Applied
Mathematics, 2005. 10. C. D. Meyer, Matrix Analysis and Applied Linear Algebra, Society for Industrial and Applied
Mathematics, 2000. 11. A.C. King, J. Billingham and S. R. Otto, Differential Equations: Linear, Nonlinear, Ordinary,
Partial, 2003, Cambridge University Press 12. Vladimir I. Arnold, Ordinary Differential Equations, Springer, 2006. 13. Fritz John, Partial Differential Equations, Springer, 1982. 14. MATLAB, MAPLE, MATHEMATICA.
ME5020: Elasticity & Plasticity (1.5 Credits) Elastic and Plastic Behaviour of Metals; Stress: Introduction, Invariants, Deviatoric stress and
equilibrium equations; Strain: Introduction, Compatibility, Strain Invariants and Deviatoric
Tensor; Stress and Strain Relations (Elastic and Plastic); Yield and Flow: Yield Condition,
Isotropic Yield Criteria (von-Mises, Tresca and Hill), Experimental Verification of Yield Criteria,
Anisotropy and Anisotropic Yield Criteria.
References: 1. Elasticity: Theory, Applications & Numerics,"" Second Edition, by M. H. Sadd, Elsevier, 2009
2. S A Khan and S Huang, Continuum Theory of Plasticity, John Wiley, 1995 3. Dixit and Dixit,
Modelling of Metal Forming and Machining Processes, Springer, 2008 4. G K Lal and Reddy N V,
Introduction to Engineering Plasticity, Narosa, 2009.
ME5030: Fluid Mechanics & Heat Transfer (1.5 Credits) Introduction to Fluid flow; Lagrangian and Euler frames of reference; Material derivative;
streamlines, streamlines and path lines; velocity potential and stream function; Conservation
of mass and momentum; continuity equation; potential flows; Elliptic equations; boundary
conditions; Euler equations; Newton's law of viscosity; Navier-Stokes equations; boundary
conditions; Boundary layers; Turbulence; Turbulence modelling; Heat conduction; transient
and steady heat conduction equation; Natural convection; Forced Convection; Non-
dimensionalization, and non-dimensional parameters; Turbulent convection
References:
1. Fluid Mechanics by P. K. Kundu, I. M. Cohen and D. R. Dowling, Academic Press 2. Viscous Fluid Flow by Frank M. White, McGraw-Hill 3. Introduction to Fluid Mechanics and Fluid Machines by S. K. Som, G. Biswas and S.
Chakraborty, Tata McGraw-Hill 4. Introduction to Fluid Mechanics by James A. Fay, MIT Press 5. Fundamentals of Heat and Mass Transfer, T. L. Bergman, A. S. Lavine, F. P. Incropera, D. P.
DeWitt, Wiley 6. Heat and Mass Transfer: Fundamentals and Applications, Y. Cengel and A. Ghajar, McGraw-
Hill 7. NPTEL – Fluid Mechanics: http://nptel.ac.in/courses/112105171/ 8. NPTEL – Heat and Mass Transfer: http://nptel.ac.in/courses/112101097/
ME5040: Computational Fluid Dynamics Tools (1.5 Credits) Introduction to Navier Stokes equation, basics of discretization methods, finite volume
formulation of convection-diffusion equation, pressure-velocity coupling, boundary condition
implementation, mesh generation techniques in CFD, CFD applications in manufacturing
processes through examples - heat removal during machining process, laser welding process,
casting, spray coating process
References: 1. Patankar, S.V., Numerical Heat Transfer, Taylor & Francis 2. Versteeg, H.K., Malalasekera, W., An Introduction to Computational Fluid Dynamics - The
Finite Volume Method, Longman 3. Tannehill, J.C., Anderson, D.A., Pletcher, R.H., Computational Fluid Mechanics and Heat
Transfer, Taylor & Francis
ME5050: Material Science & Material Selection (1.5 Credits) Phase and Phase diagrams, Diffusion in Solids, Fundamentals of dislocations and strengthening
mechanisms, Mechanical behavior of materials. Materials and design, Evolution of Engineering
Materials and their Properties, Materials selection charts, Selection of Engineering materials
and their Shape, Selection of Manufacturing Processes, Examples and Case studies.
References: 1. G E Dieter, Mechanical Metallurgy, McGrawHill, YEAR 2. M F Ashby and K Johnson, Materials and Design, Butterworth-Heinemann, 2014 3. M F Ashby, Materials Selection in Mechanical Design, 4th Edition, Butterworth-Heinemann,
2010 4. K G Swift, Process Selection from Design to Manufacture, Butterworth-Heinemann, 2003.
ME5070: Design for Manufacturability & Assembly (1 Credits) Introduction to design for manufacturing concepts; importance of product specification and
standardization, selection of materials and shapes, design rules for various manufacturing
processes, design for assembly, design for reassembly, design for automated assembly, design
for ergonomics, design for quality and reliability, design for X concepts.
References: 1. Ashby. Materials Selection in Mechanical Design. Fourth edition. Elsevier, 2011 2. Boothroyd, Geoffrey, Peter Dewhurst, and Winston A. Knight. Product Design for
Manufacture and Assembly, 3rd edition, Fl: Standards media, 2010 3. Swift, K. G., and J. D. Booker. Manufacturing Process Selection Handbook, Butterworth-
Heinemann, 2013.
ME5080: Scaling Laws & Multi-scale Manufacture (1 Credits) Introduction to Macro and micro-manufacturing, Importance of Scaling Laws. Scaling Laws in
Mechanics, fluids , thermodynamics, Electromagnetism, tribology and Examples. Trimmer force
scaling vector. Micro-Fabrication – Fundamentals of Micro-fabrication and Materials, Micro
Manufacturing Processes (Additive, Formative and Removal) and their scientific and
technological details, Applications. Sensing (measurement) and Control.
References: 1. Y Qin, Macro Manufacturing Engineering and Technology, Elsevier, 2010 2. Mark Madou, Fundamentals of Microfabrication and Nano Technology, CRC Press, 2011
ME5090: Mathematical Elements for Geometrical Modeling (1.5 Credits) Introduction to computer aided design, fundamentals of computer graphics; geometric
modelling of synthetic curves: Hermite, Bezier, B-spline, NURBS. Parametric representation of
surfaces: plane, ruled, revolution; Part modelling techniques: wireframe, surface and solid
modelling, data representation and exchange formats, geometry and topology. Three-
dimensional transformations and projections.
References: 1. Groover, M. CAD/CAM. First edition. Delhi: Pearson Education, 2003. 2. Lee, Kunwoo. Principles of CAD/CAM/CAE. 1 edition. Reading, Mass: Prentice Hall, 1999. 3. Rao, P. N. CAD/CAM: Principles and Applications. 3 edition. New Delhi: Mcgraw-Hill
Education, 2010.
4. Zeid, Ibrahim, and R. Sivasubramanian. CAD/CAM: THEORY & PRACTICE: Special Indian
Edition. 2 edition. New Delhi: Tata McGraw Hill Education, 2009.
ME5100: Computer Integrated Manufacturing (1.5 Credits) Current developments in CAD- feature based modeling, design by feature, function, feature
linkages, application of feature based models, parametric modeling; Computer Aided
Manufacturing: fundamentals of part programming, path generation, post processing and
verification; Group Technology, Computer aided process planning (CAPP), computer aided
inspection & reverse engineering, manufacturing process simulation, virtual & distributed
manufacturing, computer integrated manufacturing.
References: 1. Groover, M. CAD/CAM. First edition. Delhi: Pearson Education, 2003. 2. Lee, Kunwoo. Principles of CAD/CAM/CAE. 1 edition. Reading, Mass: Prentice Hall, 1999. 3. Rao, P. N. CAD/CAM: Principles and Applications. 3 edition. New Delhi: Mcgraw-Hill
Education, 2010. 4. Zeid, Ibrahim, and R. Sivasubramanian. CAD/CAM: THEORY & PRACTICE: Special Indian
Edition. 2 edition. New Delhi: Tata McGraw Hill Education, 2009.
ME5110: Advanced Mechanics of Solids (3 Credits) Introduction, stress definition and stress-traction relations, deformation, strain definition,
strain-displacement relation, constitutive equations, equilibrium and compatibility equations,
two dimensional problem solutions – plane stress and plane strain, advanced two dimensional
problems – plate with a hole, disk under compression, axisymmetric problems, rotating disk,
torsion, Prandtl stress function, membrane analogy, special problems , wedge with boundary
tractions, concentrated force on half plane and thermoelasticity.
References: 1. S.P. Timoshenko and J.N. Goodier, “Theory of Elasticity”, 3rd Edition, McGraw Hill, New
Delhi, 2010. 2. Arthur P. Boresi and Richard J. Schmidt, “Advanced Mechanics of Materials”, 6th ed., John
Wiley, India, 2013. 3. T.C. Wang, “Applied Elasticity”, McGraw-Hill Book, 1963. 4. L.S. Srinath, “Advanced Mechanics of Solids”, Tata McGraw Hill Publications, New Delhi,
2008. 5. M. H. Saad, “Elasticity – Theory, Applications and Numerics”, Academic Press, Elsevier India,
New Delhi, 2010.
ME5120: Dynamics and Vibration (3 Credits) Analytical dynamics, degrees of freedom, equations of motion using Newton's laws and
Lagrange equations, constrained motion, free and forced vibration of single degree of freedom
damped and undamped systems, vibration isolation, Jeffcott rotor, free and forced vibration of
multi-degree of freedom systems, modal decoupling, free and forced vibrations of continuous
systems (vibrations of rods, strings, beams, and plates).
References: 1. Analytical Dynamics: A New Approach, F. E. Udwadia and R. E. Kalaba, Cambridge University
press 2. Theory of Vibration with Applications, W. T. Thompson, CRC Press 3. Analytical Methods in Vibration, L. Meirovitch, Mcmillan USA
ME5130: Finite Element Method (3 Credits) Theory and implementation of finite element methods for solving boundary value problems in
solid mechanics. Mathematical foundations (Calculus of Variation), review of energy theorems,
theory and implementation of 1D, 2D, and 3D elasticity problems. Introduction to FEM
softwares.
References: 1) RD Cook, DS Malkus and , Concepts and Applications of Finite Element Analysis, Wiley 1995,
ISBN 2) AF Bower, Applied Mechanics of Solids, Taylor & Francis Group, 2010, ISBN 978-1-4398-
0247-2. 3) K-J Bathe, Finite Element Procedures, Prentice-Hall, 1996 ISBN 978-0133014587. 4) OC Zienkiewicz and RL Taylor,The Finite Element Method for Solid and Structural Mechanics,
Elsevier ISBN 978-0750663229.978-0750663212
ME5140: Process Control & Optimization (1.5 Credits) Introduction to Processes and Variation, Probability Models of Manufacturing Processes,
Statistical modeling and control in manufacturing processes, Sampling Distributions and
Statistical Hypotheses, Statistical Process Control. Design of Experiments, ANOVA. Use of
experimental design and response surface modeling to understand manufacturing processes.
Multi criteria optimization. Case studies.
References:
1. Montgomery, Douglas C. Introduction to Statistical Quality Control. 5th ed. New York, NY:
Wiley, 2004. ISBN: 9780471656319. 2. Kiemele, Mark J. Basic Statistics: Tools for Continuous Improvement. 4 edition. Colorado
Springs, Colo.: Air Academy Press, 1997.
ME5150: Computational Intelligence (1.5 Credits) Function approximation and Pattern recognition: Statistical modelling, Neural Network, Fuzzy
system and Classification, Principal Component Analysis; Evolutionary computation: Genetic
algorithms; Meta-heuristic methods: Simulated annealing, Ant colony optimization, Tabu
search; Monte-Carlo simulation, Design and analysis of experiments.
References: 1. Foundations of neural networks, fuzzy systems, and knowledge engineering by Nikola K.
Kasabov. Publisher: Cambridge, Mass.: MIT Press. ISBN 0585038767, ISBN 9780585038766;
ISBN9781613448212 2. Computational intelligence in manufacturing handbook by Andrew Kusiak and Publishers:
CRC Press, ISBN 0849305926 3. Computational intelligence in design and manufacturing by Andrew Kusiak, Publisher: New
York: John Wiley & Sons, ISBN 0471348791 4. Montgomery, Douglas C. Design and Analysis of Experiments: International Student Version.
Eighth edition. Wiley India Private Limited, 2013.
ME5160: Material Removal Processes (3 Credits) Conventional and non-conventional machining operation; Machine tools; Cutting Tool: Tool
material, Tool geometry, Tool wear; Metal working fluids; Machinability. Mechanics of
Machining Operation, Dynamometry in machining operations. Surface Integrity; Precision
machining; Machining Economics; Environmentally friendly machining, Machining of difficult to
cut materials.
References: 1. Metal Machining: Theory and Applications by K. Maekawa , T. Obikawa , Y. Yamane , T.H.C.
Childs. Publisher: Butterworth-Heinemann. ISBN-10: 034069159X, ISBN-13: 978-0340691595 2. Manufacturing Processes 1 - Cutting by Fritz Klocke , Publisher: Springer ISBN: 978-3-642-
11978-1, 978-3-642-11979-8 3. Applied Machining Technology by Heinz Tschätsch , Publisher: Springer, ISBN: 978-3-642-
01006-4, 978-3-642-01007-1 4. Metal Cutting by E. M. Trent and Paul K. wright, Publishers: Butterworths, London. ISBN 10:
0408108568 / ISBN 13: 9780408108560
ME5170: Welding and Joining (3 Credits) Modern welding process: GMAW (Robotic, CMT, and STT), Micro plasma welding, EBW, LBW,
Diffusion bonding, Ultrasonic welding, Pulsed current welding, Friction stir welding, Magnetic
Pulse welding. Analysis of heat sources for material joining, 2D and 3D heat flow in welds,
Residual stress analysis, Arc physics. Parameters in welding and their control, Pre and post
weld heat treatment. Welding of Steels, Aluminum alloys, Ceramics, Plastics, Composites,
Welding of dissimilar materials; Weldment design for static and fatigue loading, Failure of
welds, NDT of welds, Inspection codes, Welding symbols; Welding of pressure vessels, offshore
structures and submarine pipelines, heavy structures.
References: 1. Principles of Welding: Processes, Physics, Chemistry, and Metallurgy by Robert W. Messler
Jr. Publisher: New York: John Wiley, ISBN 0471253766, 9780471253761 2. The Physics of Welding by J. F Lancaster. Publisher: Oxford, Pergamon. ISBN0080340768,
9780080340760 3. Computational Welding Mechanics by John A. Goldak and Mehdi Akhlaghi. Publisher:
Springer, ISBN 0387232877, 9780387232874 4. ASM Handbook, V. 6. Welding, Brazing, and Soldering. ISBN 0-87170-377-7
ME5180: Metal Forming Processes (3 Credits) Plasticity - Yield and Flow: Yield Condition, Yield Criteria(Isotropic and Anisotropic), Plastic
Instability; Slip-line Field Theory; Limit Analysis: Lower and Upper Bound Techniques, Metal
Forming- Bulk Processes: Rolling, Extrusion, Drawing and Forging (Each Process will be analysed
using Force Equilibrium, Slip-line and Upper Bound Methods), Tool Design, Defects and
Remedies; Sheet Metal Forming: Shearing, Bending, Deep Drawing (all its variants) and other
processes; Hydro Forming, Explosive Forming, Electro-Magnetic Forming, Electro-Plasticity.
Scaling laws in Plasticity and Micro-Forming; Analysis of Forming Processes including defects
using Finite Element Analysis.
References: 1. S A Khan and S Huang, Continuum Theory of Plasticity, John Wiley, 1995 W Hosford, The
Mechanics of Crystals and Textured Polycrystals, Oxford, 1993. 2. Dixit and Dixit, Modelling of Metal Forming and Machining Processes, Springer, 2008 3. D Banabic, Sheet Metal Forming Processes: Constitutive Modelling and Numerical
Simulation, Springer 2010 4. G K Lal and Reddy N V, Introduction to Engineering Plasticity, Narosa, 2009. Frank Vollertsen
(Ed.) Micro Metal Forming Springer 2013.
ME5190: Manufacturing Processes (2 Credits) Classification, operating parameters, and throughputs of manufacturing processes –
Generative, Additive, and Removal Processes; Conventional and Non-conventional process;
Contact and Non-contact processes; Hybrid manufacturing processes. Characterization of
manufactured products: Form and Surface features, Residual stress, Mechanical properties,
Corrosion resistance; Process control and feedback: Electrical, hydraulic, pneumatic, and
optical sensors; open and closed loop control.
References: 1. Principles of metal manufacturing processes by Jonathan Beddoes and M. J Bibby, Elsevier,
ISBN 8131201333, 9788131201336 2. Manufacturing Processes for Design Professionals by Rob Thompson, Publisher: Thames &
Hudson , ISBN-10: 0500513759, ISBN-13: 978-0500513750 3. Manufacturing Science by Amitabha Ghosh and Asok Kumar Malik, Publisher: Affiliated East-
West Press Pvt. Ltd. ISBN-10: 8176710636, ISBN-13: 978-8176710633.
ME5210: CAD/CAM (3 Credits) Introduction to computer aided design, fundamentals of computer graphics; geometric
modelling of synthetic curves: Hermite, Bezier, B-spline, NURBS. Parametric representation of
surfaces: plane, ruled, revolution; Part modelling techniques: wireframe, surface and solid
modelling, data representation and exchange formats, geometry and topology. Three-
dimensional transformations and projections. Current developments in CAD- feature based modeling, design by feature, function, feature
linkages, application of feature based models, parametric modeling; Computer Aided
Manufacturing: fundamentals of part programming, path generation, post processing and
verification; Group Technology, Computer aided process planning (CAPP), computer aided
inspection & reverse engineering, manufacturing process simulation, virtual & distributed
manufacturing, computer integrated manufacturing.
References: 1. Groover, M. CAD/CAM. First edition. Delhi: Pearson Education, 2003. 2. Lee, Kunwoo. Principles of CAD/CAM/CAE. 1 edition. Reading, Mass: Prentice Hall, 1999. 3. Rao, P. N. CAD/CAM: Principles and Applications. 3 edition. New Delhi: Mcgraw-Hill
Education, 2010. 4. Zeid, Ibrahim, and R. Sivasubramanian. CAD/CAM: THEORY & PRACTICE: Special Indian
Edition. 2 edition. New Delhi: Tata McGraw Hill Education, 2009.
ME5220: Material Removal Processes (3 Credits) Conventional and non-conventional machining operation; Machine tools; Cutting Tool: Tool
material, Tool geometry, Tool wear; Metal working fluids; Machinability. Mechanics of
Machining Operation, Dynamometry in machining operations. Surface Integrity; Precision
machining; Machining Economics; Environmentally friendly machining, Machining of difficult to
cut materials.
References: 1. Metal Machining: Theory and Applications by K. Maekawa , T. Obikawa , Y. Yamane , T.H.C.
Childs. Publisher: Butterworth-Heinemann. ISBN-10: 034069159X, ISBN-13: 978-0340691595 2. Manufacturing Processes 1 - Cutting by Fritz Klocke , Publisher: Springer ISBN: 978-3-642-
11978-1, 978-3-642-11979-8 3. Applied Machining Technology by Heinz Tschätsch , Publisher: Springer, ISBN: 978-3-642-
01006-4, 978-3-642-01007-1 4. Metal Cutting by E. M. Trent and Paul K. wright, Publishers: Butterworths, London. ISBN 10:
0408108568 / ISBN 13: 9780408108560
ME5310: Incompressible Fluid Flow (3 Credits) Tensors, Lagrangian and Euler frames of reference; Material derivative; Newton's law of
viscosity; velocity potential and stream function; Derivation of continuity equation; potential
flows; Euler equations; Derivation of Navier-Stokes equations; Elliptic & Parabolic equations;
boundary conditions; Analytical solutions of NS equations; Boundary layer Theory; Similarity
solutions; Approximate methods; Turbulence; RANS equations; Introduction to Turbulence
modelling; Non-dimensionalization, and non-dimensional parameters;
References: 1. Incompressible Flow by R. L. Panton, Wiley 2. Fluid Mechanics by P. K. Kundu, I. M. Cohen and D. R. Dowling, Academic Press 3. Viscous Fluid Flow by Frank M. White, McGraw-Hill 4. Elementary Fluid Dynamics by D. J. Acheson, Oxford University Press 5. An Introduction to Fluid Dynamics by G. K. Batchelor, Cambridge University Press 6. Multimedia Fluid Mechanics (DVD) by G. M. Homsy et al., Cambridge University Press 7. MIT-OCW, Advanced Fluid Mechanics: http://ocw.mit.edu/courses/mechanical-
engineering/2-25-advanced-fluid-mechanics-fall-2005/ 8. NPTEL – Fluid Mechanics:
http://nptel.ac.in/courses/112105171/"
ME5320: Advanced Heat Transfer (3 Credits) Introduction - Review of fundamentals of heat transfer. Conduction: General heat conduction
equation, Analytical solutions of two dimensional steady state heat conduction; Transient
conduction. Convection: Governing equations, boundary layer equations, Forced convection
over external surfaces and internal ducts; Similarity solutions. Free and Mixed convection
flows, Conjugate heat transfer analysis. Radiative Heat Transfer: Thermal radiation, Emissive
Power, Solid Angles, Radiative Intensity, Heat Flux, Pressure and Characteristics, Radiative
transport equation
References: 1. Intermediate heat transfer, Kau-Fui Vincent Wong, Marcel Dekker, Inc. New York-2003. 2. Fundamentals of Heat and Mass transfer, Frank P Incropera and David P Dewitt, Wiley –
India edition, Fifth edition- 2009. 3. Heat conduction, Latif M. Jiji, Springer-Verlag-2009 4. Introduction to convective heat transfer analysis, Patrick H. Oosthuizen and David Naylor,
McGraw-Hill international editions-1999. 5. Viscous fluid flow, Frank M White McGraw-Hill, 2009. 6. Radiative Heat Transfer, Michael F. Modest, Academic Press, 2003.
ME5330: Computational Fluid Dynamics (3 Credits) Introduction to numerical solutions of PDEs; importance of CFD; various methods; Taylor
Series; Finite-difference of first, second and third derivatives; Order of accuracy; finite-
differences on non-uniform grids; time-stepping; explicit and implicit time-stepping of 1-D
unsteady heat conduction equation; Boundary and Initial conditions; tri-diagonal solver;
Explicit and Implicit schemes for 2-D unsteady heat conduction equation; Gauss-seidel method;
Convergence; iterative vs direct methods; Types of PDEs, and their IC and BCs; the well-posed
problem; Methods of Elliptic PDE; False-transient method; Hyperboilc PDEs; 1st order wave
equation: characteristics; Methods: Lax, McCormack etc; modified equation; dissipative and
dispersive errors; systems of hyperbolic equations; diagonalization; Finite-volume method;
Convection-Diffusion equation; Convective schemes: Upwind, 2nd upwind, Quick, etc;
Vorticity-streamfunction formulation: Explicit, Implicit and Semi-Implicit schemes; coupled
temperature equation; segregated and coupled solution methods; SMAC method for Navier-
Stokes equations.
References: 1. Computational Fluid Mechanics and Heat Transfer, Second Edition, JC Tannehill, D Anderson,
and RH Pletcher, 1997 2. Computational Fluid Flow and Heat Transfer, Second edition, K. Muralidhar and T.
Sundararajan, Alpha science International, 2003.
ME5411: Design Engineering Core Lab I (2 Credits) Finite element methods for solving boundary value problems in solid mechanics. Introduction,
Spatial Modelling, Geometric discretization, Element Library, Material Modelling, Loading and
Boundary Conditions, Constraints, Surface/Interfaces modelling, Step and job handling and
Post-processing. FEA Implementation and Visualization of 1D Problems, Truss Problem, Beam
bending, Plane and axisymmetric Problems and 3D problems. Various analysis such as, Static,
Transient, Harmonic, Modal, Dynamics and Multi Physics (Thermomechanical, etc). Introduction to MATLAB - variables, structures, arrays, operators, conditional statements,
loops; root finding using Newton-Raphson method, optimization, solving ODEs and PDEs, event
detection; graphics; simulink based simulations
References:
1. Rudra Pratap, "Getting Started with MATLAB: A Quick Introduction to Scientists and
Engineers, Oxford University Press. 2. Cleve Moler, Numerical Computing with MATLAB, SIAM.
ME5421: FEM Lab (1 Credits) Finite element methods for solving boundary value problems in solid mechanics. Introduction,
Spatial Modelling, Geometric discretization, Element Library, Material Modelling, Loading and
Boundary Conditions, Constraints, Surface/Interfaces modelling, Step and job handling and
Post-processing. FEA Implementation and Visualization of 1D Problems, Truss Problem, Beam
bending, Plane and axisymmetric Problems and 3D problems. Various analysis such as, Static,
Transient, Harmonic, Modal, Dynamics and Multi Physics (Thermomechanical, etc).
ME5431: Integrated Design & Manufacturing Lab (2 Credits) Job preparation using CNC machining, Robotic welding, 3D printing, EDM, Injection molding.
Measurements of parts using CMM; Form measurement; Digitization using 3D scanner, surface
roughness testing. Deep drawing using forming machine. Cutting force measurement using
dynamometer. Sample preparation and characterization using Optical Microscope. Lab project
ME5441: CFD Lab (1 Credits) Mesh generation techniques, experiment using commercial CFD solver - turbulent mixing and
heat transfer, external flow, combustion, two-phase flow, turbo-machines
ME5451: Computational Mathematics Lab (1 Credits) Introduction to MATLAB - variables, structures, arrays, operators, conditional statements,
loops; root finding using Newton-Raphson method, optimization, solving ODEs and PDEs, event
detection; graphics; simulink based simulations
References: 1. Rudra Pratap, Getting Started with MATLAB: A Quick Introduction to Scientists and
Engineers, Oxford University Press. 2. Cleve Moler, Numerical Computing with MATLAB, SIAM.
ME5471: Thermo-Fluid Engineering Core Lab I (2 Credits) Mesh generation techniques, experiment using commercial CFD solver - turbulent mixing and
heat transfer, external flow, combustion, two-phase flow, turbo-machines
ME5610: Fracture Mechanics (3 Credits) Review of elements of solid mechanics, analysis of stress-strain-constitutive equations,
introduction to fracture mechanics, crack growth mechanisms, fracture mechanism, Inglis
solution, Griffith’s realization, energy principles, energy release rate, linear elastic fracture
mechanics, stress intensity factor, SIF for general cases – analytical/numerical/experimental,
multi-parameter stress field equation, elastic plastic fracture mechanics, J-integral definition,
fatigue crack propagation and evaluation of testing standards.
References: 1. Prashant Kumar, “Elements of Fracture Mechanics”, Tata McGraw-hill, New Delhi, 2009. 2. T. L. Anderson, “Fracture Mechanics: Fundamentals and Applications”, 3rd ed.,CRC press
Taylor & Francis, US, 2005. 3. David Broek, “Elements of Engineering Fracture Mechanics”, 4th ed., Kluwer Academic
Publishers, Dordretch, 2002. 4. R. J. Sanford, “Principles of Fracture Mechanics”, Prentice Hall, NJ, 2003. 5. E. E. Gdoutos, “Fracture Mechanics: An Introduction”, 2nd ed., Springer, Dordretch, 2005.
ME5620: Mechatronic Systems (3 Credits) Overview of mechatronic systems – mathematical modeling of systems – introduction to
control – sensors and transducers – signal conditioning – amplification, filtering, analog-to-
digital converters and digital-to-analog converters – data presentation systems – actuators –
electrical, mechanical, pneumatic, hydraulic – analog electric circuits, operational amplifiers –
digital logic circuits, microprocessors, microcontrollers, DSPs, Programmable Logic Controllers
– programming in assembly and C – communication interfaces – RTOS – machine vision
systems – robotics
References: 1. Bolton, W., Mechatronics: Electronic Control Systems in Mechanical and Electrical
Engineering, Prentice Hall. 2. Alciatore, D. G., and Histand, B. M., Introduction to Mechatronics and Measurement
Systems, Tata McGraw-Hill. 3. Robert H. Bishop, Mechatronics: An Introduction, CRC Press."
ME5630: Nonlinear Oscillation (3 Credits) Review of dynamical systems, solution methodology, phase space and different stability
analysis, different types of nonlinear systems and its classification based on the nature of
nonlinearity, modeling of single/multi-degree of freedom dynamical systems with
single/multiple inputs, evolution equations obtained from continuous systems, existence of
nonlinear resonances, regular perturbation, singular perturbation methods, multiple scales
method, equilibrium stability vs orbital stability of periodic and quasiperiodic systems, local
bifurcation theory and center manifold theorem, application of techniques to do nonlinear
analysis of mechanical systems under external/parametric excitation.
References: 1. Applied Nonlinear Dynamics: Analytical, Computational and Experimental Methods, Ali H
Nayfeh and B. Balachandran, Wiley-VCH 2. Nonlinear Oscillations, Ali. H. Nayfeh and Dean T. Mook, Wiley-VCH
ME5640: Multibody Dynamics (3 Credits) Review of kinematics and dynamics of point mass and rigid body – types of constraints –
constraints for revolute joints, translational joints, composite joints – formulation of planar
multi-body systems, kinematics and dynamics in point coordinates, body coordinates, and joint
coordinates – numerical methods for solution – analysis of planar multi-body systems,
kinematic analysis, inverse dynamic analysis, forward dynamic analysis, constraint stabilization
– case studies, McPherson strut suspension, Double A-arm suspension, planar robot
manipulator – Spatial multi-body systems
References: 1. Parviz E Nikravesh, "Planar Multibody Dynamics: Formulation, Programming, and
Applications," CRC Press.
2. Javier Garcia de Jalon, and Eduardo Bayo, "Kinematic and Dynamic Simulation of Multibody
Systems: The Real-Time Challenge," Springer-Verlag. 3. Roy Featherstone, "Rigid Body Dynamics Algorithms," Springer.
ME5650: Engineering Noise control (3 Credits) Introduction to noise control: definition of sound, acoustic wave equation, sound level and
spectra, octave and 1/3 octave bands, weighting networks (a, b, c and linear), hearing,
psychological response to noise, loudness interpretation, NC curves, masking, sound
propagation, plane wave, spherical wave, sound power, its use and measurement, sound
power and sound pressure level estimation procedure, characteristics of noise sources, source
ranking, passive noise control methods, sound absorption coefficient measurement,
transmission loss, room acoustics, sound in enclosed spaces, basics of muffler design, lined
plenum absorption, pipe wrapping, vibration isolation, vibration damping.
References: 1. Bies, D.A., and Hanson, C.H., Engineering Noise Control, Third Edition, Spon Press, London,
2003. 2. Irwin, J.D., and Graf, E.R., Industrial Noise and Vibration Control, Prentice Hall, Englewood
Cliffs, 1979. 3. István L. Vér, Leo Leroy Beranek. , Noise and vibration control engineering: principles and
applications, John Wiley & Sons, 2006 4. Michael Peter Norton, Denis G. Karczub, Fundamentals of noise and vibration analysis for
engineers, Cambridge University Press, Second Edition, 2003 5. Lawrence E.Kinsler, Austin R. Frey, Alan B. Coppens, James V. Sanders, Fundamentals of
Acoustics, John Wiley & Sons, 1999
ME5660: Applied Micro and Nanomechanics in Engineering (3 Credits) Review of different physical domains and their coupling in the design of micro and
nanomechanics based senors and actuators. Scaling laws - length and time scale. Inter and
intra-molecular forces, constitutive relationships in solids and fluids. Electrostatic potential,
and capacitance, pull-in phenomena, static and dynamic analysis. Application of the numerical
techniques through standard multidomain analysis softwares such as COMSOL
multiphysics/Intellisuite/Coventorware/ANSYS, etc.
References: 1. S.D. Sentura, Microsystem Design, Kluwer Academic Publishers, 2001, 2. Andrew N. Cleland, “Foundations of Nano mechanics-From Solid State Theory to Device
Applications”, Springer, 2010.
3. George Karniadakis, Ali Beskok, Narayana Rao Aluru, “Microflows and Nanoflows:
Fundamentals and Simulations, Springer, 2005. 4. K.F. Riley, M.P. Hobson, S.J. Bence, “Mathematical Methods for Physics and Engineering,
Second Edition,” Cambridge University Press, 2003."
ME5670: Vehicle Dynamics and Modeling (3 Credits) Vehicle Mechanics – Forces under static and dynamic equilibrium. Free body diagram of
different vehicle components. Simple linearized rigid models of different components. Dynamic
stability and the vehicle performance under different operating conditions such as
understeering, neutral steering, and oversteering. Concept of vehicle ride comfort. Vehicle
stability controls. Driveline models, Performance characteristics of a comfortable vehicle ride.
Introduction to the development of vehicle model using different software such as MATLAB
Simulink, MAPLESIM, System Modeller, ADAMS, CarSIM.
References: 1. Thomas Gillespie, “Fundamentals of Vehicle Dynamics”, SAE, 1992. 2. Dean Karnopp, “Vehicle Dynamics, Stability, and Control”, Second Edition, CRC Press, 2013. 3. Giancarlo Genta, “Motor Vehicle Dynamics-Modeling and Simulation”, World Scientific, 2013 4. John C. Dixon, “Tires, Suspension and Handling”, SAE, 1996. 5. Herb Adams, “Chassis Engineering: Chassis Design, Building & Tuning for High Performance
Handling, Brownian Dynamics”, HP Trade, 1992
ME5680: Fatigue and Damage Tolerance Evaluation (0.5 Credits) Introduction - Structural materials –metallic alloys – polymer composites – mechanical
properties. Fatigue - Fracture mechanics-Damage tolerance-Stress intensity factor- Strain
energy release rate. Failure mechanisms - Metallic alloys: defects- dislocations- ductile and
brittle failures, elastic and plastic deformation: Composites: damage modes-matrix cracks –
disbond- fiber fracture- delamination. Mechanical testing and evaluation - Metallic materials:
Tension, Fracture toughness, LCF, HCF, FCGR – ASTM standards – data acquisition and analysis:
Composites: Tension, compression, ILSS, Flexure, Fatigue, delamination fracture, spectrum
fatigue, ASTM standards, design allowables. Fatigue of materials - Metallic alloys: Basquin's law, Coffin -Manson relation, fatigue crack
growth rate, crack closure: Composites: Total fatigue life, delamination onset and growth
behavior, stiffness and strength. Fatigue Life prediction and DTE - Life prediction methods
under constant amplitude, Block and spectrum loads Metallic alloys:, Crack closure approach,
SIF approach: Composites:, Concept of Constant life diagram, Damage tolerance evaluation:
aircraft industry requirements.
References: 1. J. Schijve, “Fatigue of Structures and Materials”, 2nd ed., Springer, 2009. 2. Jones R. M., “Mechanics of Composite Materials”, CRC Press, 1998. 3. R. Talreja and Chandra Veer Singh, “Damage and Failure of Composite Materials”, Cambridge
University Press, 2012. 4. T. L. Anderson, “Fracture Mechanics: Fundamentals and Applications”, 3rd ed.,CRC press
Taylor & Francis, US, 2005.
ME5690: Advanced FEM (3 Credits) Theory and implementation of finite element methods for solving non-linear boundary value
problems in solid mechanics. review of fem and continuum mechanics, nonlinear bending of
beams and plates, nonlinear analysis of time dependent problems, material non-linearity, and
solution procedures for linear and nonlinear algebraic equations.
References: 1.JN Reddy, An Introduction to the nonlinear Finite Element Analysis, Oxford University Press 2) J C Simo and TJR Hughes, Computational Inelasticity, Springer 3)AF Bower, Applied Mechanics of Solids, Taylor & Francis Group, 2010, ISBN 978-1-4398-0247-
2. 4) K-J Bathe, Finite Element Procedures, Prentice-Hall, 1996 ISBN 978-0133014587. 5) OC Zienkiewicz and RL Taylor,The Finite Element Method for Solid and Structural Mechanics,
Elsevier Butterwoth-Heinemann, 2005, ISBN 978-0750663212
ME5710: CNC & Part Programming (3 Credits) Introduction: NC/CNC, CNC machines, Industrial applications of CNC, economic benefits of
CNC. CNC Machine Tools: Classification of machine tools, CNC machines tool design, control
systems. Position control velocity control and machine tool control, Interpolation and
electronics. Data Input: Punched tape, manual data input, tape punch, reader error checking.
CNC tooling: Qualified and pre-set tooling, tooling systems, tool setting, automatic tool
changers, work holding and setting. Programming: Part programming language, programming
procedures, proving part programmes, computer aided part programming. Advances:
Advances in CNC programming, integration with CAD, material handling in CNC machines,
manufacturing systems.
References: 1. Warren S. Seames, Computer numerical control: concepts and programming, Thomson
Learning, 2001
2. William W. Luggen, Computer numerical control: a first look primer, Thomson Publishing,
1996 3. Learning Barry Leatham - Jones, Introduction to Computer Numerical Control, Pitmans,
London, 1988. 4. T.K. Kundra, P.N. Rao and N.K. Tewari, Numerical control and Computer Aided
Manufacturing, Tata McGraw Hill Publishing Company Limited, New Delhi 1985."
ME5720: Advanced Material Joining Processes (3 Credits) Modern welding process: GMAW (Robotic, CMT, and STT), Micro plasma welding, EBW, LBW,
Diffusion bonding, Ultrasonic welding, Pulsed current welding, Friction stir welding, Magnetic
Pulse welding. Analysis of heat sources for material joining, 2D, 3D heat flow in welds, residual
stress analysis, Arc physics. Parameters in welding and their control, Pre and post weld heat
treatment. Welding of Steels, Aluminum alloys, Ceramics, Plastics, Composites, Welding of
dissimilar materials.
References: 1. Principles of Welding: Processes, Physics, Chemistry, and Metallurgy by Robert W. Messler
Jr. Publisher: New York: John Wiley, ISBN 0471253766, 9780471253761 2. The Physics of Welding by J. F Lancaster. Publisher: Oxford, Pergamon. ISBN0080340768,
9780080340760 3. Computational welding mechanics by John A. Goldak and Mehdi Akhlaghi. Publisher:
Springer, ISBN 0387232877, 9780387232874 4. ASM Handbook, V. 6. Welding, Brazing, and Soldering. ISBN 0-87170-377-7"
ME5730: Rapid Prototyping & Manufacturing (3 Credits) "Overview of Rapid Product Development: Product Development Cycle, virtual prototyping,
physical prototyping, Solid Modelling: Data formats, conversion, checking, repairing and
transmission. Synergic integration technologies, Part slicing and Build Orientation, Area-filling
strategies, applications and limitations of RPM. Classification of RPM processes: Sheet
Lamination, Material Extrusion, Photo-polymerization, Powder Bed Fusion, Binder Jetting,
Direct Energy Deposition. Popular RPM processes. Selection of rapid prototyping, tooling and
manufacturing systems based on product requirements. "
References: 1. Gibson, D. W. Rosen, and B. Stucker, Additive Manufacturing Technologies: Rapid
Prototyping to Direct Digital Manufacturing. Springer, 2010 2. C. K. Chua and K. F. Leong, Rapid Prototyping: Principles and Applications in Manufacturing.
World Scientific, 2003.
3. Lu, L., Fuh, J., Wong, YS., 2001, Laser Induced Materials and Processes for Rapid Prototyping,
Kluwer 4. Pique, A., Chrisey, DB., 2002, Direct Write Technologies for Rapid Prototyping Applications:
Sensors, Electronics and Integrated Power Sources, Academic Press. 5. Venuvinod, PK., Ma, W., 2004, Rapid Prototyping - Laser Based and Other Technologies,
Kluwer.
ME5740: Plasticity and Metal Forming (3 Credits) Plasticity - Plastic Behaviour of Metals: Introduction, Flow curve and Mechanism of Plastic
Deformation, Introduction to Metal Forming; Stress: Introduction, Invariants, Deviatoric stress
and equilibrium equations; Strain: Introduction, Compatibility, Strain Invariants and Deviatoric
Tensor; Stress and Strain Relations; Yield and Flow: Yield Condition, Isotropic Yield Criterion
(von-Mises, Tresca and Hill), Experimental Verification of Yield Criteria, Anisotropy and
Anisotropic Yield Criteria; Plastic Instability; Brief outline of Slip-line Field Theory; Limit
Analysis: Lower and Upper Bound Techniques Metal Forming- Bulk Processes: Rolling,
Extrusion, Drawing and Forging (each process will be analysed using Force Equilibrium, Slip-line
and Upper Bound Methods), Tool Design, Defects and Remedies; Sheet Metal Forming:
Shearing, Bending, Deep Drawing (all its variants) and other processes; Hydro Forming,
Explosive Forming, Electro-Magnetic Forming, Electro-Plasticity, Scaling laws in Plasticity and
Micro-Forming; Analysis of Forming Processes including defects using Finite Element Analysis.
References: 1. S A Khan and S Huang, Continuum Theory of Plasticity, John Wiley, 1995 2. Dixit and Dixit, Modelling of Metal Forming and Machining Processes, Springer, 2008 3. G K Lal and Reddy N V, Introduction to Engineering Plasticity, Narosa, 2009. 4. Frank Vollertsen (Ed.) Micro Metal Forming Springer 2013 "
ME5810: Advanced Computational Fluid Dynamics (3 Credits) Finite-volume method; pressure problem for incompressible Navier-Stokes equations;
Pressure-velocity decoupling; Staggered and collocated grids; semi-explicit (SMAC) method on
staggered grids; Convective schemes; Implicit SIMPLE method; higher-order accuracy
implementations; Non-orthogonal grids: problems with staggered grids; collocated grid;
implementation of semi-explicit and implicit schemes on rectangular collocated grids;
generalization to collocated non-rectangular hexahedral grids; Boundary conditions and their
implementation; adaptation of schemes to tetrahedral grids, general hybrid grids; advanced
linear equations solvers; algebraic multigrid methods.
References:
1. An Introduction to Computational Fluid Dynamics: The Finite Volume Method (2nd Edition),
H. Versteeg, W. Malalasekera, 1995. 2. Computational fluid dynamics, T. J. Chung, Cambridge University Press, 2010.
ME5820: Turbulence (3 Credits) Turbulence: Introduction, nature, origin, length and time scales in turbulent flows, Kolmogorov energy spectrum. RANS equations, Closure problem, Turbulent transport of momentum and heat. Dynamics of Turbulence: Kinetic energy of the mean flow, Kinetic
energy of turbulence, Vorticity dynamics, Dynamics of temperature fluctuations. Free-shear
flows, Wall bounded shear flows. CFD modelling of Turbulence: Algebraic models, One-
equation models, Two-equation models: Wall bounded flows; Wall functions and Low Reynolds
number effects, Beyond RANS for turbulence modelling; LES and DNS.
References: 1. A First Course in Turbulence, H. Tennekes and J.L. Lumley, The MIT Press, Cambridge,
Massachusetts, and London, England. 2. Turbulent Flows, S.B. Pope, Cambridge University Press, UK. 3. Turbulence - An Introduction for Scientists and Engineer, Davidson, P.A., Oxford University
Press 4. Turbulence Modeling for CFD, David C. Wilcox, DCW Industries. 5. Turbulence: Coherent Structures, Dynamical Systems and Symmetry, Holmes, P., Lumley, J.L.
and Berkooz, G., Cambridge University Press 6. Turbulence, J.O Hinze, McGraw-Hill international editions.
ME5830: Compressible Flow and its Computation (3 Credits) Basics: Introduction and review of Thermodynamics; Integral form of conservation equations;
One-dimensional Flow – Area-Velocity Relations and Isentropic Relations, Wave Propagation,
Speed of Sound, Shock Waves, Normal Shock Waves; Flow Through Nozzles and Duct, Flow
with Heat addition and friction; Two – dimensional Compressible Flow: Oblique Shocks,
Expansion Waves, Shock Interactions, Detached Shocks, Shock-Expansion Technique; Unsteady
Wave Motion; Analytic Methods: Method of Characteristics; Computation: Mathematical nature of Euler equations: Various forms of Euler equations;
Hyperbolic Equations; Riemann Problem. Basic Numerical Methods: Centred and upwind
discretisation. Artificial Viscosity, CFL condition and Numerical stability. Brief Historical
Evolution of the computational methods for compressible flow and their classification. Central
Schemes, First and Second order upwind scheme. Roe and MacCormack methods. Flux-Vector
Splitting, Godunov Methods, High Resolution Schemes: TVD and Flux-limiters. Boundary
Conditions: Treatments for physical and numerical Boundary Conditions. Modern Compressible
Flow and Current Research; Numerical Methods available in commercial and open source
software.
References: 1. Modern Compressible Flow with Historical Perspective by J.D. Anderson 2. www.aeromech.usyd.edu.au/aero/gasdyn/ 3. Laney, Culbert B. Computational Gasdynamics. Cambridge University Press, 1998. 4. Anderson, John D. Computational fluid dynamics. Vol. 206. New York: McGraw-Hill, 1995. 5. Hirsch, Charles. Numerical computation of internal and external flows: the fundamentals of
computational fluid dynamics. Vol. 1. Butterworth-Heinemann, 2007. 6. Toro, Eleuterio F. "Riemann Solvers and Numerical Methods for Fluid Dynamics: A Practical
Introduction." (2009).
ME5840: Introduction to Open CFD (1 Credits) Open source CFD software distribution; Meshing, Initialization, Boundary conditions, Selecting
models, Mesh conversion; Examples - Incompressible Flows, Compressible Flows, Multiphase
flows; Post-processing tools and visualization, Running in parallel, Programming new transport
and turbulence models.
References: 1. OPENFOAM documentation: http://www.openfoam.org/docs/
ME5850: Introduction to Molecular Solvers (1 Credits) Introduction to Continuum and Molecular Theories, Direct Simulation Monte Carlo Method,
Open source molecular solvers with applications to hypersonic, rarefied and microscale gas
flows; external aerodynamics; Molecular Dynamics Method, Applications to nano liquidics.
References: 1. OPENFOAM documentation: http://www.openfoam.org/docs/
ME5860: Introduction to Combustion & Reactor Models (1 Credits) Combustion background; 1st and 2nd law of thermodynamics applied to chemical reaction,
Gibbs free Energy, equilibrium temperature & composition; Arrhenius law, reaction rate for
single step and multistep reactions; PSR, PFR, const. pressure & const. volume reactor models
and their applications to simulate practical combustion systems.
References: 1. Introduction to Combustion: Concepts and Applications, Stephen Turns, McGraw-Hill. 2. Combustion Physics, Chung K. Law, Cambridge University Press.
ME5870: Chemical Kinetics & Modeling in Reacting Flows (2 Credits) Chemical Kinetics - elementary and global reactions, collision theory, rate of reaction in
multistep mechanisms, chemical time scales and partial equilibrium; Simplified conservation
equations applied to reaction systems, concept of conserved scalar; Laminar flames – premixed
& diffusion; Turbulent flames -premixed and diffusion; detonations & deflagration, liquid &
solid fuel combustion reaction modeling.
References: 1. Introduction to Combustion: Concepts and Applications, Stephen Turns, McGraw-Hill 2. Chemical Kinetics & Reaction Dynamics, Paul L. Houston, Dover 3. Chemical Kinetics, James E House, Academic Press 4. Combustion Physics by Chung K. Law, Cambridge University Press.
ME5880: Combustion and Flow Diagnostics (3 Credits) Detailed review of optical diagnostic techniques – PIV, PLIF, CARS, Raman & Rayleigh
scattering, interferometry, schlieren & shadowgraph; experimental applications to flow field
diagnostics; liquid fuel spray atomization characterization, combustion & pollutant formation;
optical measurements in direct injected diesel & gasoline engines; advanced developments -
Infrared laser-induced fluorescence imaging, novel flow-tagging velocimetry approach, new
diode laser sources for combustion diagnostics and control, CO2 interferences in engine
diagnostics
References: 1. Applied Combustion Diagnostics, Kathrina Kohse HoingHaus and Jay B Jeffries, CRC Press 2. Laser Diagnostics for Combustion Temperature and Species, Alan C Eckbreth, CRC Press. 3. Flow Visualization, Wofgang Merzkirch, Academic Press 4. Schlieren and Shadowgraph techniques, G S Settles, Springer
ME5911: Design Engineering Core Lab II (2 Credits) Experimental stress analysis lab: Strain measurement involving strain gages for tensile, torsion
and bending applications,Thick cylinder under internal pressure, Gage factor determination for
a strain gage, Introduction to photoelasticity, Material stress fringe value determination, Tardy
method of compensation for fringe order determination, Photoelasticity applications, Beam
under four point bending, Bending study of a diaphragm under pressure load Vibration Lab:
Vibration Fundamental Trainer, Whirling of Shaft, Experimental Modal Analysis, Laser
alignment system Mechatronics Design Lab: Traffic control using Programmable Logic
Controller, Magnetic levitation system, Stepper motor control through digital input/output
(DIO) using Labview, Temperature measurement through ADC using LabView.
References: 1. James W. Dally and William F. Riley, “Experimental Stress Analysis”, McGraw-Hill, US, 1978.
ME5941: Manufacturing Engineering Core Lab (2 Credits) Job preparation using CNC machining, Robotic welding, 3D printing, EDM, Injection molding.
Measurements of parts using CMM; Form measurement; Digitization using 3D scanner, surface
roughness testing. Deep drawing using forming machine. Cutting force measurement using
dynamometer. Sample preparation and characterization using Optical Microscope. Lab project
ME5971: Thermo-Fluid Engineering Core Lab II (2 Credits) Introduction about Subsonic Wind tunnel; Measurement of static and dynamic pressure;
Calibration of pressure transducers; Measurement of aerodynamic forces and flow
characteristics: Cylinder, flat plate, symmetric and asymmetric airfoils: Thermal conductivity of fluids: water and air; Fluidized bed heat transfer; Pool boiling and
Condensation.
References: 1. Fundamentals of Aerodynamics, John D. Anderson, McGraw Hill, 2010. 2. Viscous fluid flow, Frank M .White, McGraw-Hill, 2009. 3. Fundamentals of Heat and Mass transfer, Frank P Incropera and David P Dewitt, Wiley, 2009.
ME6106: Seminar (2 Credits) Thesis writing, research paper writing, delivering technical seminars, group discussion,
technical interview, text processing using LaTex.
References: 1.https://www.asme.org/
2.http://www.dst.gov.in/scientific-programme/call-for-papers/guidelines.pdf
3. Jane Summers and Brett Smith, "Communication Skills Handbook: How to Succeed in
Written and Oral Communication", 2nd Edition, John Wiley & Sons, 2005.
4. Emrald, How to write effectively Guide for Authors:
http://www.emeraldgrouppublishing.com/authors/guides/write/index.htm
ME7100: Advanced Topics in Mathematical Tools (3 Credits) Classical Optimization, stochastic optimization, Neural and Fuzzy system, FFT, Wavelets, monte
carlo simulations, design of experiments, Taguchi method. Introduction to linear and nonlinear
dynamical system, fixed points and stability, phase plane analysis, Limit cycles, Bifurcations in
1D and 2D of systems, Lyapunov stability, Deterministic chaos, Strange attractors, Regular and
singular perturbation, Boundary layer theory, Matched asymptotic expansions, and Method of
multiple scales.
References: 1. An Introduction to Neural Networks, James A. Anderson, Cambridge, MIT Press 2. Engineering Optimization: Theory and Practice, S. S. Rao, John Wiley & Sons 3. Engineering Optimization, Ranjan Ganguli, University Press 4. Fundamentals of Applied Probability Theory, Alvin W. Drake, MIT 5. Nonlinear Dynamics and Chaos, Stephen H. Strogatz, Perseus Books, Cambridge 6. Introduction to Fourier Analysis and Wavelets, Mark A. Pinsky, American Mathematical
Society 7. Perturbation Methods, E.J. Hinch, Cambridge texts in applied mathematics 8. Advanced Mathematical Methods for Scientists and Engineers: Asymptotic Methods and
Perturbation Theory, Carl M. Bender and Steven A. Orszag, Springer
ME3995: Summer Internship at Purdue (3 Credits)
ME4325: Elective Project / CoreElective (3 Credits; Both Fractal and Non-Fractal)
ME4425: Project 3 (8th Sem) (3 Credits)
ME4705: Honour's 3 (Project Stage-1) (3 Credits)
ME4805: Honour's 4 (Project Stage-2) (3 Credits)
ME5915: M.Tech (3-year) Thesis (Semester-1) (Will vary for each student (total = 30) Credits)
ME5925: M.Tech (3-year) Thesis (Semester-2) (Will vary for each student (total = 30) Credits)
ME5935: Dual Degree Thesis (Stage-1) (5 Credits)
ME5945: Dual Degree Thesis (Stage-2) (18 Credits)
ME5955: Dual Degree Thesis (Stage-3) (22 Credits)
ME6005: M.Tech. Project (Stage-1) (14 Credits)
ME6505: M.Tech. Project (Stage-2) (16 Credits)
ME6915: M.Tech (3-year) Thesis (Semester-3) (Will vary for each student (total = 30) Credits)
ME6925: M.Tech (3-year) Thesis (Semester-4) (Will vary for each student (total = 30) Credits)
ME7915: M.Tech (3-year) Thesis (Semester-5) (Will vary for each student (total = 30) Credits)
ME7925: M.Tech (3-year) Thesis (Semester-6) (Will vary for each student (total = 30) Credits)