production & b. tech. production and industrial engg. curriculum & syllabus

SCHOOL OF MECHANICAL AND BUILDING SCIENCES

CURRICULUM

B. Tech. PRODUCTION AND INDUSTRIAL ENGINEERING Breakup of Courses Sl. No Category Total number of Credits

1 University Core 33 2 University Elective 6 3 Programme Core 128 4 Programme Elective 15

Minimum Total Number of Credits 182 Breakup of Category Category Number of Credits % Recommended % Engineering 121 69.5 64 Humanities 14 8.0 8 Management 12 7.0 8 Sciences 27 15.5 20 Sub Total 174 University Elective 6 Co/Extra-Curricular Activity 2

TOTAL 182 100 100

CURRICULUM

University Core Course

Code Course Title L T P C Category Version

Course

Prerequisite

ENG101 English for Engineers I 2 0 2 3 Humanities 1.0 VIT EPT

(or) ENG001

ENG102 English for Engineers II 2 0 2 3 Humanities 1.0 ENG101

CHY101 Engineering Chemistry 3 0 2 4 Science 1.0 -

CHY104 Environmental Studies 3 0 0 3 Science 1.0 -

FRE101/

GER101/

JAP101/

CHI101

Foreign Language 2 0 0 2 Humanities 1.0 -

MAT101 Multivariable Calculus and Differential

Equations 3 1 0 4 Science 1.0 -

ITE101 Problem Solving Using C 2 0 2 3 Engineering 1.0 -

PHY101 Modern Physics 3 0 2 4 Science 1.0 -

HUM121 Ethics and Values 2 0 2 3 Management 1.0 -

MEE498 Comprehensive Examination - - - 2 Engineering 1.0 -

XXX497 Co/Extra-Curricular Activity - - - 2 - 1.0

33

University Electives

Course Title L T P C University Elective - I - - - 3

University Elective - II - - - 3

6

Programme Core

Course Code Course Title L T P C Category Version

Course Prerequisite

MAT104 Probability and Statistics 3 1 0 4 Science 1.0 MAT101

MAT105 Differential and Difference Equations 3 1 0 4 Science 1.0 MAT101

MEE107 Engineering Drawing I 0 0 4 2 Engineering 1.0 -

MEE108 Engineering Drawing II 0 0 4 2 Engineering 1.0 MEE107

MEE102 Workshop Practice I 0 0 2 1 Engineering 1.0 -

MEE104 Workshop Practice II 0 0 2 1 Engineering 1.0 MEE102

EEE101 Basic Electrical & Electronics Engineering 3 0 2 4 Engineering 1.0 -

MEE109 Material Science and Metallurgy 3 0 2 4 Science 1.0 -

MEE207 Computer Aided Machine Drawing 0 0 4 2 Engineering 1.0 MEE108

MEE245 Theory of Metal Joining 3 0 2 4 Engineering 1.0 -

MEE246 Theory of Metal Casting 3 0 2 4 Engineering 1.0 -

MEE247 Theory of Metal Cutting 2 1 2 4 Engineering 1.0 MEE104

MEE248 Mechanics of Solids and Fluids 2 1 2 4 Engineering 1.0 -

MEE386 CNC Machines and Programming 3 0 2 4 Engineering 1.0 MEE247

MEE249 Theory of Metal Forming 3 0 2 4 Engineering 1.0 MEE109

MEE250 Thermodynamics and Heat Transfer 2 1 2 4 Engineering 1.0

MEE251 Engineering Metrology 2 1 2 4 Engineering 1.0

MEE308 Industrial Engineering and Management 3 0 0 3 Management 1.0

MEE307 CAD/CAM 2 0 4 4 Engineering 1.0 MEE207

MEE432 Tool Design 2 1 0 3 Engineering 1.0 MEE247

MEE252 Simulation Modeling And Analysis 3 0 2 4 Engineering 1.0 MAT104

MEE387 Manufacturing Automation 3 0 2 4 Engineering 1.0 MEE245 & MEE246

MEE354 Kinematics and Dynamics of Machines 2 1 2 4 Engineering 1.0 MEE248

MEE253 Reliability, Maintenance and Safety Engineering 3 0 0 3 Engineering 1.0 MAT104

MEE254 Statistical Quality Control 3 0 2 4 Engineering 1.0 MAT104

MEE437 Operations Research 2 1 0 3 Management 1.0 MAT104

MEE434 Production Planning and Control 3 0 0 3 Engineering 1.0 MEE308

MEE446 Optimization Techniques 2 1 2 4 Engineering 1.0 MEE437

MEE447 Total Quality Management 3 0 0 3 Management 1.0 MEE308

MEE255 Industrial Economics 3 0 0 3 Management 1.0

MEE399 Industrial Internship - - - 2 Engineering 1.0

MEE256 Industrial Engineering Project - - - 2 Engineering 1.0 MEE 387

HUM101 Psychology and Sociology 3 0 0 3 Humanities 1.0 MEE499 Project Work - - - 20 Engineering 1.0

Programme Electives (Credits to be earned: 15)

Course Code Course Title L T P C Category Version

Course Prerequisite

MEE338 Design of Composite Materials 2 1 0 3 Engineering 1.0 MEE109

MEE388 Advanced Metal Forming 2 1 0 3 Engineering 1.0 MEE249

MEE448 Project Management and Control 2 1 0 3 Management 1.0 MEE308

MEE350 Facilities and Process Planning 3 0 0 3 Engineering 1.0 MEE308

MEE389 Micro and Nano Machining 3 0 0 3 Engineering 1.0 MEE247

MEE351 Rapid Manufacturing Technologies 3 0 0 3 Engineering 1.0 MEE246 &

MEE249

MEE390 Design of Machine Tool Structure 3 0 0 3 Engineering 1.0 MEE247

MEE449 Advanced Manufacturing Management 3 0 0 3 Engineering 1.0 MEE308 &

MEE447

MEE450 Enterprise Resource Planning 3 0 2 4 Engineering 1.0 MEE308 & MEE434 MEE213 Robotics 3 0 0 3 Engineering 1.0 -

MEE451 Agile Manufacturing 3 0 0 3 Engineering 1.0 MEE434 & MEE447

MEE452 Logistics & Supply Chain Management 3 0 0 3 Management 1.0 MEE308 &

MEE437

MEE435 Lean Enterprises and New Manufacturing Technology 3 0 0 3 Engineering 1.0 MEE308

MEE340 Product Design for Manufacturing 2 1 0 3 Engineering 1.0 MEE245,

MEE246 & MEE247

MEE107 ENGINEERING DRAWING I 0 0 4 2 Pre requisite - Objectives 1. To create awareness and emphasize the need for Engineering Graphics in

all the branches of engineering. 2. To follow basic drawing standards and conventions. 3. To develop skills in three-dimensional visualization of engineering component.

Expected Outcomes

1. On completion of this course, the students will be able to Prepare drawings as per standards (BIS). 2. Solve specific geometrical problems in plane geometry involving lines, plane figures and special Curves. 3. Produce orthographic projection of engineering components working from pictorial drawings.

Unit I Introduction to Engineering Drawing: Principles of Engineering Graphics and their Significance, Drawing Instruments and their Use, Dimensioning principles, Conventions in Drawing Curves Used in Engineering Practice & their Constructions: Conic Sections including the Rectangular Hyperbola- General method only. Unit II Drawing of Projections or Views: Principles of Orthographic Projections, Conventions, Projection of Points in all quadrants and Projection of Lines (first angle projection) inclined to both planes, True lengths, Traces. Unit III Projections of Planes: Projections of regular Planes in simple position, inclined to both the planes, Auxiliary planes and views Unit IV Projection of Solids: Projection of Solids in simple position, inclined to both the planes, Auxiliary views. Unit V Sections and Sectional Views: Right Regular Solids- Prism, Cylinder, Pyramid, Cone. Auxiliary views for true shape of sections. Text Books 1. Engineering Drawing, N.D. Bhat / Charotar. 2. Engineering Drawing and Graphics, Venugopal K, New Age International. References 1. Engineering drawing- P.J. Shah. / S. Chand. 2. Engineering Drawing- Narayana and Kannaiah / Scitech Publishers. 3. Engineering Drawing- Johle / Tata Mc Graw Hill Mode of Evaluation

MEE108 ENGINEERING DRAWING II 0 0 4 2 Pre requisite MEE107 Objectives 1. To prepare sectional views of solids.

2. To draw the development of surfaces and estimate the sheet metal requirement. 3. To develop skills in three-dimensional visualization of engineering components. 4. To provide students with the basic knowledge and skills in producing Engineering Graphics and with the capability to read and interpret engineering drawings. 5. To develop an understanding of solid modelling using the SolidWorks software.

Expected Outcomes

1. On completion of this course, the students will be able to Prepare sectional views of solids. 2. Estimate the sheet metal requirement for fabrication. 3. Draw isometric drawings of combined solids and simple components. 4. Prepare solid modelling of machine components using the Solidworks software.

Unit I Introduction to CAD Practice of some figures using CAD Unit II Development and Interpenetration of Solids Development of Surfaces of Right Regular Solids- Prisms, Cylinder, Pyramid, Cone and their parts. Unit III Transformation of Projections Conversion of Isometric Views to Orthographic views, Conventions. Unit IV Isometric Projections Principles of Isometric Projection, Isometric scale, Isometric views, Isometric Projection of Objects. Unit V Perspective Projections Perspective View- Points, Lines, Plane Figures and Simple Solids. Vanishing Point Methods (General Method only). Text Books 1. Engineering Drawing, N.D. Bhat / Charotar. 2. Engineering Drawing and Graphics, Venugopal / Newage International. References 1. Engineering drawing- P.J. Shah. / S. Chand. 2. Engineering Drawing- Narayana and Kannaiah / Scitech Publishers. 3. Engineering Drawing- Johle / Tata Mcgraw Hill. Mode of Evaluation

Quiz/Assignment/ Seminar/Written Examination

Note: 50 % Manual Practice and 50% CAD Practice

MEE102 WORKSHOP PRACTICE-I 0 0 2 1 Pre requisite - Objectives 1. To train the students in metal joining process like welding, soldering, etc.

2. To impart skill in fabricating simple components using sheet metal. 3. To cultivate safety aspects in handling of tools and equipment.

Expected Outcomes

On completion of this course, the students will be able to 1. Welding and soldering operations. 2. Fabrication of simple sheet metal parts.

Unit I Welding Shop 1. Instruction of BI standards and reading of welding drawings. 2. Butt Joint 3. Lap Joint 4. TIG Welding 5. MIG Welding Unit II Sheet Metal Shop 1. Making of Cube 2. Making of Cone using development of surface. 3. Making of control panel using development of surface. Unit III Soldering Shop 1. Soldering and desoldering of Resistor in PCB. 2. Soldering and desoldering of IC in PCB. 3. Soldering and desoldering of Capacitor in PCB. Unit IV Bosch Tools Demonstration of all BOSCH TOOLS Text Books Workshop Manual prepared by VIT staff Mode of Evaluation

Tutorials / Class Tests / Lab Exam

MEE104 WORKSHOP PRACTICE - II 0 0 2 1 Pre requisite MEE102 Objectives 1. To train the students in safety handling of tools, equipment and

machineries. 2. To carry out exercise in metal removal process by using drilling and lathe machines. 3. To train students in plumbing operation and techniques. 4. To expose the student in house wiring. 5. To train students in basic carpentry exercise using modern Bosch Tools.

Expected Outcomes

On completion of this course, the students will be able to 1. Basic operation in drilling and lathe. 2. Plumbing and simple house wiring. 3. Basic wooden components

Unit I Machine Shop 1. Drilling and Countersinking using Drilling machine 2. Drilling and Tapping 3. Lathe Exercise - Facing operation 4. Lathe Exercise - Straight turning and Chamfering Unit II Plumbing Shop 1. L Joint 2. T - Joint Unit III House Wiring Shop 1. Single point wiring 2. Staircase wiring Unit IV Bosch Tools Exercises 1. Planning & Polishing operation 2. Sawing operation 3. Profile cutting 4. Making of rectangular slot Text Books Workshop Manual prepared by VIT staff Mode of Evaluation

Tutorials / Class Tests / Lab Exam

EEE101 BASIC ELECTRICAL AND ELECTRONICS

ENGINEERING 3 0 2 4

Pre requisite Knowledge in +2 level physics Objectives To impart knowledge on the working principles in electrical and electronics

engineering Expected Outcomes

The students will gain knowledge in the underlying principle of electrical and electronics engineering

Unit I Elementary Circuit Analysis Ohm's Law, KCL, KVL, Node Voltage Analysis, Mesh Current, Thevenin's & Norton's Equivalent, Maximum Power Transfer and Superposition Theorem, VI characteristics for capacitors and inductors. Unit II Analysis of DC & AC circuits Steady state DC analysis, Introduction to AC circuits and concept of phasors for constant frequency sinusoidal sources. Steady State AC analysis of a series circuit, series and parallel combinations of complex impedances, AC power calculations.- single phase and three phase systems. Unit III Digital Systems Basic Logic Circuit Concepts, Representation of Numerical Data in Binary Form- Combinatorial Logic Circuits, Synthesis of Logic Circuits, Computer Organization, Memory Types Unit IV Power Semiconductor devices Operating mechanism of power devices including diodes, Zener diode BJTs, MOSFETs, IGBTs, forward and reverse characteristics, Break down characteristics and their applications. Unit V Electromechanics Magnetic Fields and Circuits, Self and Mutual Inductance, Ideal and Real Transformers. Principles of Rotating Machines- DC Machines, 3-phase Induction Motors, Synchronous Machines. Text Books 1. Allan R. Hambley Electrical Engineering-Principles & Applications by, Pearson Education, First Impression, 2008. 2. Basic Electrical Engineering second edition by Kothari D. P and Nagrath I. J., Tata MacGraw Hills, 2002. 3. Theory and Problem of Basic Electrical Engineering by Kothari D. P and Nagrath. I. J. Prentice Hall of India New Delhi - 1998. 4. R. A. DeCarlo and Pen-Min Lin, 'Linear Circuit Analysis', 2/e, Oxford University Press, New Delhi, 2001. 5. 5. Batarseh, Power Electronics Circuits, Wiley, 2003. References 1. W. H. Hayt, J.E. Kemmerly and S. M. Durbin, 'Engineering Circuit Analysis', 6/e, Tata McGraw Hill, New Delhi, 2002. 2. 2. A. Ramakalyan, 'Linear Circuits', Oxford University Press, New Delhi, 2005. Mode of Evaluation

Sessional Written CAT- I & II , Quizzes, Assignments/ other tests, Final - Written Term End Examination (TEM)

MEE109 MATERIAL SCIENCE AND METALLURGY 3 0 2 4 Pre requisite - Objectives 1. To provide the basic knowledge needed to explore the discipline of

materials science and engineering. 2. To develop the knowledge of how the structure of materials is described technically, including crystallography, microstructure, defects, and phase diagrams. 3. To develop the knowledge of how the properties of materials are described technically and how material failure is analyzed. 4. To introduce the concepts of structure-property relationships. 5. To develop knowledge in various class of materials and their applications.

Expected Outcomes

Student will be able to 1. Understand how materials are formed and their classification based on atomic arrangement. 2. Describe the mechanical behaviour of metallic systems and its importance. 3. Evaluate system for fatigue failures. 4. Gain knowledge on different class of materials and their applications. 5. Evaluate the failure mode of the materials and to know the steps to be taken to prevent the failures.

Unit-I Engineering materials: classification, requirements, properties and selection of engineering materials. Crystal structure; crystal systems, atomic packing, stacking sequence, Miller indices of crystallographic planes and directions, inter planar spacing- BCC, FCC and HCP systems, X-ray diffraction, Crystal imperfections; point defects, line defects- edge and screw dislocations, interaction between dislocations, Frank-Reed source, surface defects, volume defects. Experimental techniques for metallographic studies, optical microscopy, electron microscopy (SEM and TEM), specimen preparation, etching, common etchants, grain size, grain size measurement, ASTM grain size number Unit II Solidification of metals- cooling curves, nucleation-homogeneous and heterogeneous nucleation, supercooling, critical radius-grain growth, dendritic pattern, equiaxed and columnar grains, grain boundary-grain boundary effects-solidification and structure of castings-coring, homogenization. Alloys- solid solutions-interstitial, substitutional ordered and disordered solid solutions, Hume-Rothery rules, intermetallic compounds, phase diagrams; -construction from cooling curves, lever rule- equilibrium diagrams of binary alloys, isomorphous (Cu-Ni), Eutectic (Bi-Cd, Pb-Sn) detailed study of Fe-C systems.Diffusion; mechanisms of diffusion-Fick's laws of diffusion-applications Unit III Deformation of metals; cold working, hot working, annealing of a cold worked article-recovery, recrystallisation and grain growth, elastic and plastic deformations;mechanisms of plastic deformation, deformation by slip- slip systems- slip planes and slip directions, critical resolved shear stress-deformation by twinning. Strengthening mechanisms; work hardening, solid solution hardening, dispersion hardening, precipitation hardening, grain boundary strengthening. Unit IV

Heat treatment of steels; stress relieving, annealing, normalising, hardening, TTT diagram, tempering, hardenability, Jominy test. Surface hardening; flame hardening, induction hardening, Case hardening; carburising, nitriding, cyaniding, etc.. Metallic Coatings, hard facing, metal cladding, anodising, diffusion coatings. Unit V Ferrous alloys; steels-alloy steels, tool steels, stainless steels, effect of alloying elements on properties of steels, cast irons-classification, structure, properties, applications Non-ferrous alloys: Al and Al alloys, Cu and Cu alloys, Mg and Mg alloys, Zn and Zn alloys-major types, composition, properties and applications.Non-metallic materials; thermoplastics, thermosetting plastics, elastomers, composites, ceramics, glasses .Recent developments in materials science; smart materials, shape memory alloys, functionally graded materials, piezo-electric materials. Text Books 1. Callister W. D., Materials Science and Engineering: An Introduction, 2010, John Wiley & Sons Inc. References 1. Avner S. H., Introduction to Physical Metallurgy, McGraw Hill 2. Van Vlack L. H., Elements of Materials Science, Addison Wesley 3. Shackelford J. F., Materials Science for Engineers, Prentice-Hall 4. Higgins R. A., Engineering Metallurgy Part I, Applied Physical Metallurgy, ELBS 5. Raghavan V., Material Science and Engineering, Prentice-Hall of India 6. Reed Hill, Physical Metallurgy Principles, Affiliated East-West Press 7. Jastrzebiski, Nature and Properties of Engineering Materials, John Wiley 8. Smith, Science of Engineering Materials, Prentice-Hall Mode of Evaluation

PBL/Quiz/Assignment/ Seminar/Written Examination

Lab Experiments: Experiments 1. Metallographic sample preparation 2. Phase diagram determination 3. Microstructures of plain carbon steel 4. Microstructures of cast iron 5. Heat treatment of plain carbon steels 6. Hardness measurement 7. Phase analysis and porosity determination using image analysis soft ware 8. Microstructure of non-ferrous alloys 9. Determination of grain size 10. NDT testing using ultrasonic flaw detector 11. Stress analysis using XRD pattern 12. Creep Test References Lab Manual Prepared by VIT Staff Mode of Evaluation Experiments/Record work/Oral/ Practical Examination

MEE207 COMPUTER AIDED MACHINE DRAWING 0 0 4 2 Pre requisite MEE108 Objectives 1. To introduce students to the basics and standards of engineering

drawing related to machines and components. 2. To teach students technical skills regarding assembly, production and part drawings. 3. To familiarize students with various limits, fits and tolerances. 4. To help students gain knowledge about standard CAD packages on modeling and drafting.

Expected Outcomes

Student will be able to 1. Acquire the knowledge of various standards and specifications about standard machine components. 2. Make drawings of assemblies with the help of part drawings given. 3. Ability to select, configure and synthesize mechancial components into assemblies. 4. Apply the knowledge of fits and tolerances for various applciaitons. 5. Able to model components of their choice using CAD software. 6. Get exposure to advanced CAD packages.

Unit I Drawing Standards Code of Practice for Engineering Drawing - BIS specifications Conventional representation Welding symbols - riveted joints - keys - fasteners Reference to hand book for the selection of standard components like bolts - nuts - screws - keys etc. Unit II Limits, Fits and Tolerances Limits - Fits and tolerances Allocation of fits for various mating parts Tolerance data sheet Tolerance table preparation Geometric tolerance. Unit III Computer Aided Assembly and Detailed Drawing Solid modeling of simple and intricate machine and automobile components Surface modelling of automobile body and Appliances(electrical and domestic) - Preparation of assembled and detailed drawings of I.C.Engine components viz: Cylinder head - Piston - Connecting rod and Crankshaft assembly - Carburettor - Fuel pump etc., Text Books Bhatt, N.D., (1999), Machine Drawing , Published by R.C.Patel, Chartstar Book Stall, Anand, India. References 1. James Barclay, Brian Griffiths, (2003), Engineering Drawing for Manufature. 2. Cecil Jensen, Jay Helsel and Donald D. Voisinet, (2000), Computer-aided engineering drawing, McGraw-Hill: New York 3. Sidheswar, N., Kanniah, P. and Sastry, V.V.S., (2005), Machine Drawing . Mode of Evaluation

Experiments/Record work/Oral/ Practical Examination

MEE245 THEORY OF METAL JOINING 3 0 2 4 Prerequisite - Objectives: 1. To understand the basic principles of welding

2. To know the various types of advanced joining processes 3. To know about welding defects and remedial measures for it

Expected Outcome:

Student will be able to 1. Develop welding techniques for various alloys 2. Develop welding application concepts 3. Develop mechanized welding techniques 4. Develop welding electrodes

Unit I Power sources Classification of welding processes - heat sources, power sources, arc characteristics, V-I relationship, different types of electrodes, ingredients and function of electrode coverings, types of weld joints. Unit II Fusion welding processes Shielded metal arc welding, gas welding, TIG welding, MIG welding, Submerged arc welding processes Unit III Solid state welding processes Resistance, friction, friction stir, ultrasonic, induction pressure, diffusion welding processes, explosive welding. Unit IV Special welding processes Electron beam, laser beam welding, plasma arc processes; advantages, limitations, Introduction to Robotic welding, underwater welding. Unit V Welding metallurgy Weld thermal cycles and their effects, effects of pre and post weld heat treatments, concept of HAZ, concept of weldability and its assessment. Welding of different materials, defects in welds, their causes and remedies. Text Books Cornu. J.,(2004)"Advanced Welding Systems"-Volumes I, II and III, JAICO Publishers. References 1. Lancaster L.F, (1996) The Physics of Welding, Pergamon Press. 2. Welding Handbook (Section I) American Welding Society1999 3. Parmer R.S, (2005) Welding processes, Khanna publishers. 4. Srinivasan N.K, (2004) Welding Engineering, Khanna publishers. 5. Rao P.N (1998)"Manufacturing Technology (Foundry, Forming and Welding) II Edition", Tata McGraw Hill Pub. Co. Ltd,. New Delhi. Mode of Evaluation Quiz/Assignment/ Seminar/Written Examination

Lab: List of Experiments: 1. Joint using manual Arc welding 2. Butt joint using TIG welding 3. Fillet joint using MIG welding 4. Metal cutting by Oxy-Acetylene gas 5. Friction welding for aluminum metal 6. Pipe joint welding 7. Making of a joint by Gas welding using filler material 8. Laser welding demonstration 9. Stud welding in Are welding 10. Brazing experiment

MEE246 THEORY OF METAL CASTING 3 0 2 4 Prerequisite - Objectives: 1.To understand the basic principles of metal casting

2. To know the various types of melting practices 3. To broaden the understanding of casting design principles 4. To know about casting defects and remedial measures

Expected Outcome:

Student will be able to 1. Design of gates and risers in castings 2. Develop various alloys for different applications 3. Develop suitable casting techniques for specific applications

Unit I Molding practices Introduction to casting and foundry industry; basic principles of casting processes; sequence in foundry operations; patterns; molding practice; ingredients of molding sand and core sand, sand testing; different molding processes Unit II Melting furnaces Types of furnaces used in foundry; furnaces for melting; melting practice for steel, cast iron, aluminum alloys, copper alloys and magnesium alloys; safety considerations; fluxing, degassing and inoculation. Unit III Special Casting techniques Investment casting , Shell molding ,die casting, centrifugal casting, plaster mould casting, magnetic casting, squeeze casting, full mould process, strip casting, CO2 molding Unit IV Gating and risering Concept of solidification, directional solidification, role of chilling, principles of gating and risering systems: types and design calculations. Unit V Foundry Defects and Automation Defects in castings and its remedies. Energy saving and quality control in foundries; Cleaning and inspection of castings; Foundry automations-moulding machines-automation of sand plant, moulding and fettling sections of foundry Dust and fume control. Text Books JAIN, P.L., Principles of Foundry Technology, Tata McGraw Hill, 2009. References 1. Wulff B., Taylor H. F., Fleming M. C., Foundry Engineering, Wiley Eastern, 1999, 2. Jain P. L., Principles of Foundry Technology, 3rd Edition, Tata McGraw Hill, 2000 3. Srinivasan N. K., Foundry Technology, Khanna Publications, 2001. Mode of Evaluation Quiz/Assignment/ Seminar/Written Examination

Lab: List of Experiments: 1. Green sand moulding using single piece pattern. 2. Green sand moulding using two piece pattern. 3. Determination of Grain fineness number of dry sand. 4. Finding shear strength of moulding sand 5. Finding compressive strength of grand sand 6. Determination of permeability of green sand 7. Finding splitting strength of a core sand 8. Casting of Aluminium metal by stir casting method 9. Making of a core for a pattern 10. Simple design of a pattern.

MEE247 THEORY OF METAL CUTTING 2 1 2 4 Pre requisite MEE104 Objectives 1. To teach the mechanics of chip formation, tool material and tool life.

2. To give an exposure to students on the modern (nontraditional) machining processes.

Expected Outcomes

On completion of the course the students will be able to: 1. Mechanism of chip formation in different materials. 2. Estimate the tool life for different tool materials. 3. Select the appropriate tool material and design for the given cutting conditions 4. Understand the principles and applications of various modern machining processes

Unit I INTRODUCTION Importance of material removal, elements of metal machining, fundamenta1 mechanism of metal deformation in cutting. Geometry & design of single point tool, geometry & design of milling cutters, geometry of drills, broachers. Unit II MECHANICS OF CHIP FORMATION Orthogonal & oblique cutting, mechanism of chip formation, shear plane angle, shear stress and strain, principa1 chip types, mechanics of machining, forces in cutting of metals, stress on tool, stress distribution, Basic requirement of cutting force measuring technique, Dynamometers for measuring forces in turning, milling and drilling. Unit III HEAT FLOW IN METAL CUTTING and Tool Life Introduction, heat in chip formation, heat at tool work interface, heat at tool chip interface, heat in absence of flow zone, method of tool temperature measurement, temperature distribution in tool. Definition, evaluation of machinability, tool life, Taylors equation, tool failure, variab1es affecting the tool life causes of tool failures, economics in metal machining. Unit IV CUTTING TOOL MATERIAL and Cutting Fluid Requirement of tool material, effect of alloying elements in properties of tool steel, common tool materia1, carbon stee1 , high speed steels, co-cast alloys, carbide too1s, ceramic too1s, diamond, design & performance of tool material. Function & requirement of cutting fluid, type of cutting fluid as gas, water & oil based solutions, chemical coolants, method of, application of cutting fluid - Minimum quantity lubrication. Unit V Modern machining processes Principles, process characteristics and application of ECM, EDM, USM, AJM, EBM, LBM, PAM, etc., capability analysis. Micro/nano machining. Text Books 1. Geoffrey Boothroyd and W. A. Knight, Fundamentals of Machining and Machine Tools, Marcel Dekkel Inc. References 1. Amitabh Ghosh and Asok Kumar Mallik, Manufacturing Science, Affiliated East West Press Pvt. Ltd. 2. Amitabha Battacharyya, Metal Cutting, Theory and Practice, New Central Book Agency. 3. Serope Kalpakjian and Steven R. Schmid, Manufacturing Engineering and

Technology, Pearson Education. 4. M. C. Shaw, Metal Cutting Principles, CBs Publishers. Mode of Evaluation

Assignment/Seminar/Quiz/CAT/Term end examination

List of Lab Exercises 1. Experiments on Lathe to establish the cutting speed, feed and depth of cut on cutting forces. 2. Measurement of flank wear using Tool Makers microscope and plotting the effect of turning parameters on average flank wear. 3. Effect of cutting speed, feed and depth of cut on average surface roughness for a given work and tool material during turning process. 4. Measurement of cutting tool temperature in turning and plotting effect of turning parameters on average temperature. 5. Machining slots using shaping and slotting machines 6. Gear cutting using milling and gear hobbing machines. 7. Surface grinding and measurement of surface roughness for different feed rate. 8. Grinding of single point cutting tool as per given specifications (to check the tool angles). 9. Ram electrical discharge machinng 10. Wire electrical discharge machining

MEE248 MECHANICS OF SOLIDS AND FLUIDS 2 1 2 4 Pre requisite - Objectives 1. To develop the relationship between the loads applied to a non-rigid body

and the internal stresses and deformations induced in the body. 2. To study the general state of stresses and strains in a given loaded member and the magnitude and direction of the principal stresses. 3. To introduce and explain basic fundamentals of Fluid Mechanics. 4. To learn fluid properties and hydrostatic law to understand the importance of flow measurement and its applications in Industries.

Expected Outcomes

1. Apply concepts of strength of materials to obtain solutions to real time Engineering problems. 2. To find frictional losses in a pipe when there is a flow between two places.

Unit I Definition/derivation of normal stress, shear stress, and normal strain and shear strain Stress-strain diagram- Elastic constants Poissons ratio relationship between elastic constants and Poissons ratio Generalised Hooks law Uniaxial deformation. Unit II Biaxial state of stress Stress at a point stresses on inclined planes Principal stresses and Principal strains and Mohrs circle of stress, Theories of failure - Fundamentals of theory of elasticity Yield criteria and plasticity. Unit III Solid Mechanics applications Thin shells, torsion, bending, buckling. Unit IV Fluid properties Hydrostatic forces on plane inclined and curved surfaces buoyancy centre of buoyancy metacentre. Types of flows - Streamline and Velocity potential lines- Euler and Bernoullis equations and their applications moment of momentum Momentum and Energy correction factors Impulse Momentum equation-Navier-Stokes Equations-Applications. Unit V Flow through pipes Open Channels and Measurement pipe flow: Darcys law Minor losses Multi reservoir problems pipe network design Moodys diagram Hagen Poiseuille equation Turbulent flow. Text Books 1. P.N.Modi and S.M.Seth (2011), Hydraulics and Fluid Mechanics including Hydraulic Machines, Standard Book House, Naisarak, Delhi. References 1. Timoshenko, S.P. and Young, D.H., (2000), Strength of Materials, East West Press Ltd. 2. R.K. Bansal, (2000), Strength of Materials, Laxmi Publications. 3. Vijay Gupta and S.K.Gupta, (1999), Fluid Mechanics and Applications, New-Age International Ltd. 4. D.S. Kumar,(2004), Fluid Mechanics and Fluid Power Engineering, Katson Publishing House, Delhi. 5. Rowland Richards, (2000), Principles of Solid Mechanics, CRC Press. Mode of Evaluation


MECHANICS OF SOLIDS AND FLUIDS LAB Objectives: 1. To provide students an opportunity to learn how to measure hardness of materials and analyze how heat treatment affects hardening. 2. To study the influence of flexural strength on deflection of a beam. 3. To teach students about flow measuring devices such as orifice meter and venture. 4. To help the students acquire knowledge about flow through pipes. Expected Outcome: 1. To get practical knowledge on the measurement of hardness, strength and stiffness. 2. To acquire hands on experience in pipe flow and flow measurement. Experiments 1. Evaluation of Engineering Stress / Strain Diagram on Steel rod, Thin and Twisted Bars under tension. 2. Compression test on Bricks, Concrete blocks. 3. Deflection test Verification of Maxwell theorem. 4. Comparison of hardness values of Steel, Copper and Aluminium using Brinell and Rockwell hardness measuring machines. 5. Estimation of Spring Constant under Tension and Compression. 6. Flow through Orifice 7. Flow through Mouth Piece 8. Flow through Triangular Notch 9. Flow through Venturimeter 10. Flow through Pipes References Lab manual prepared by VIT faculty Mode of Evaluation: Experiments/Record work/Oral/ Practical Examination

MEE386 CNC MACHINES AND PROGRAMMING 3 0 2 4 Pre requisite MEE247 Objectives 1. To understand the working principle of CNC Machines.

2. To learn the programming of CNC Machines. 3. To understand the various types and applications of CNC Machines.

Expected Outcomes

Student will be able to 1. Understand the importance of CNC Machines and its working principle. 2. Write programs (G codes and M codes) for the given components. 3. Understand the capabilities and applications of CNC Machines.

Unit I Introduction to NC and CNC Conventional Machines NC Machines Basic components of NC machines CNC machines - classification of CNC machines, Need, benefits and limitations. Unit II Construction of CNC Machines Constructional features of CNC machines- Machine Structure Slide ways- Spindle Drive Units Feedback control Feedback devices Tools and work holding devices Trouble Shooting - Mechanical, Electrical& Pneumatics - Common Faults and Remedies. Unit III Manual Part Programming Manual part Programming Coordinate systems, Adaptive Control, G codes, M codes, Part Programming Point to Point Straight line Curved path - Simple programming for CNC Lathe CNC Milling machines. Unit IV Advanced Part Programming Canned cycles- Drill Dwell- Peck drill- Bore- Non standard fixed cycles, Subroutines and Macros. Unit V CNC Programming by CAD/CAM CAD Modelling of 3D components- CAM Preparatory commands, transformations, subroutines, canned cycles Verification tools - CNC program generation from CAD model- CNC controller and motion control in CNC system, Applications of CNC - Recent advances in CNC machines. Text Books 1. Mikell P. Groover and Emory W. Zimmers, CAD/CAM Computer Aided Design and Manufacturing, Prentice Hall Edition, 2004. References 1. M.Adithan and B.S. Pabla CNC Machines New age international Publishers 2007. 2. J.S.Narang CNC Machines and AutomationsDhanpat Rai & Co 2013. Mode of Evaluation


CNC PROGRAMMING LAB

CAM EXPERIMENTS 1. Manual part programming using G and M codes for Turning, Step turning, Taper turning, multiple turning, Facing, Multiple facing, thread cutting and radius turning on cylindrical components. 2. CNC Milling program involving linear motion and circular interpolation. 3. CNC Milling program involving contour motion and canned cycles. 4. CNC Milling program involving Pocket milling 5. CNC code generation using any CAM software. 6. Simulation of machining operations using any CAM software. 7. Route sheet generation using CAM software. 8. Programming and practice on CNC lathe and CNC milling Machines References: Lab Manual prepared by VIT faculty Mode of Evaluation: Experiments/Record work/Oral/ Practical Examination

MEE249 THEORY OF METAL FORMING 3 0 2 4 Pre requisite MEE109 Objectives 1. To understand the basic principles of Metal Forming Theory

2. To know the various types of forming processes 3. To know about advanced metal forming methods

Expected Outcomes

Student will be able to 1. Choose forming techniques for various applications 2. Estimate power requirement for forming processes 3. Calculate the forming limit for various processes

Unit I Theory of Plasticity Theory of Plasticity - stress tensor hydrostatic & deviator components of stress flow curve true stress strain yielding criteria yield locus octahedral shear stress and shear strains invariants of stress strain slip line field theory plastic deformations of crystals. Unit II Plastic Forming of Metals-Forging Basics of plastic forming & forging- mechanics of metal working temperature in metal working strain rate effects friction and lubrication deformation zone geometry. Forging process classification equipment calculation of forging loads forging defects residual stresses. Unit III Plastic Forming of Metals-Rolling and Extrusion Rolling and Extrusion classification -rolling mills - rolling of bars & shapes rolling forces analysis of rolling defects in rolling- theories of hot & cold rolling torque power estimation. Extrusion: classification-equipment deformation lubrication and defects analysis hydrostatic extrusion tube extrusion. Unit IV Plastic Forming of Metals- Drawing and Sheet metal forming Drawing & Sheet Metal Forming- rod & wire drawing equipment analysis deep drawing tube drawing analysis, residual stresses sheet metal forming methods shearing and blanking bending stretch forming deep drawing forming limit criteria defects - Stretch forming press brake forming explosive forming. Unit V Unconventional Forming Methods Electro hydraulic forming magnetic pulse forming super plastic forming electro forming fine blanking P/M forging-Isothermal forging HERF. Text Books 1. George E Dieter, Mechanical Metallurgy, Tata McGraw Hill, 2007 References 1. B L Juneja, Fundamentals of Metal Forming Processes, New Age International. 2. John A Schey, Introduction to Manufacturing Process, Allied, ND. 3. ASM, Hand book: Forming and Forging. Mode of Evaluation


MEE250 THERMODYNAMICS AND HEAT TRANSFER 2 1 2 4 Pre requisite - Objectives 1. To cover basic principles of thermodynamics and heat transfer.

2. To study real-world engineering examples to give students a feel for how thermal sciences are applied in engineering practice. 3. To develop an intuitive understanding of thermal sciences by emphasizing the physics and physical arguments.

Expected Outcomes

Upon completion of this course, students should be: 1. Master the basic principles of the thermal energy sciences, including thermodynamics, fluid dynamics and heat transfer. 2. Able to handle energy-related problems and practice. 3. Able to develop Energy saving Consciousness.

Unit I Thermodynamic Systems, Properties, State, Processes and Cycles. Zeroth Law of Thermodynamics, First Law of Thermodynamics, Concept of Heat and Work, First Law applied to closed and open systems, Steady flow energy equation. Unit II Second law of thermodynamics, Different Statements and their equivalence, Reversible and irreversible processes, Carnot cycle, Carnot theorem and their corollaries, Entropy, T ds Equations, Thermodynamic property relations, Maxwells relations, Clapyron Equation, Specific heats Joule Thompson coefficient. Unit III Basic modes of heat transfer, General heat conduction Equation in Cartesian cylindrical and spherical coordinates, Initial and boundary conditions, Steady state heat transfer in simple geometries with and without heat generation. Introduction to unsteady state heat transfer Extended surfaces. Heat exchangers, LMTD and NTU methods of calculations in heat exchanger analysis. Unit IV Convective heat transfer, Newtons law, Hydrodynamic and thermal boundary layer, External and internal flow heat transfer under fully developed laminar flow. Natural convection from vertical plates, Empirical relations in convective heat transfer. Unit V Introduction to boiling and condensation, Radiation Heat transfer, Fundamental laws of radiation, Radiation heat exchange between bodies of simple geometry. Shape factor, Electric network analogy in radiation heat transfer. Text Books 1. Yunus A. Cengel, Introduction to Thermodynamics and Heat Transfer, 2nd Edition McGraw-Hill, 2008. References 1. P.K. Nag, Engineering Thermodynamics, Third Edition, Tata McGraw Hill, New Delhi, 2005.. 2. P. K. Nag, Heat Transfer, Tata McGraw Hill , New Delhi, 2003. 3. Y.A. Cengel, M. A. Boles, Thermodynamics an Engineering Approach, Fourth Edition, Tata McGraw Hill, New Delhi, 2003. 4. J.P., Holman, Heat Transfer, Ninth Edition, Tata McGraw Hill, New Delhi, 2005. Mode of Evaluation


MEE251 ENGINEERING METROLOGY 2 1 2 4 Pre requisite - Objectives 1. To help students acquire knowledge about Measurements and Measuring

procedures. 2. To teach various measuring standards and various measuring instruments used in industries. 3. To explain the different instruments used for linear and angular measurements, surface finish etc.

Expected Outcomes

1. Have good knowledge of Measuring procedures and Measuring Instruments.

Unit I Systems of limits and fits: Introduction, normal size, tolerance limits, deviations, allowance, fits and their types unilateral and bilateral tolerance system, hole and shaft basis systems interchangeability and selective assembly. Indian standard Institution system British standard system, International Standard system for plain ad screwed work. Unit II Linear Measurement: Length standard, line and end standard, slip gauges calibration of the slip gauges, Dial indicator, micrometers. Measurement of Angles And Tapers: Different methods Bevel protractor angle slip gauges spirit levels sine bar Sine plate, rollers and spheres used to determine the tapers. Limit Gauges: Taylors principle Design of go and No go gauges, plug ring, snap, gap, taper, profile and position gauges. Unit III Optical Measuring Instruments: Tool makers microscope and its uses collimators, optical projector optical flats and their uses, interferometer. Flat Surface Measurement: Measurement of flat surfaces instruments used straight edges surface plates optical flat and auto collimator. Unit IV Surface Roughness Measurement : Differences between surface roughness and surface waviness-Numerical assessment of surface finish CLA,R, R.M.S Values Rz values, Rz value, Methods of measurement of surface finish-profilograph. Taly surf, ISI symbols for indication of surface finish. Measurement Through Comparators: Comparators Mechanical, Electrical and Electronic Comparators, pneumatic comparators and their uses in mass production. Unit V Screw Thread Measurement: Element of measurement errors in screw threads measurement of effective diameter, angle of thread and thread pitch, profile thread gauges. Gear Measurement: Gear measuring instruments, Gear tooth profile measurement. Measurement of diameter, pitch pressure angle and tooth thickness. Machine Tool Alignment Tests: Requirements of Machine Tool Alignment Tests, Alignment tests on lathe, milling, drilling machine tools. Text Books 1. Jain R. K., Engineering Metrology, Khanna Publications, 2010. References 1. Gupta. I.C., Engineering Metrology, Dhanpat Rai and Sons, 1997. Mode of Evaluation PBL/Quiz/Assignment/ Seminar/Written Examination

METROLOGY LAB Objectives 1. To enable the students understand the uses of basic metrology

instruments. 2. To train students on identifying metrolgy intruments for a given compononent for inspection.

Expected Outcome

Student will be able to 1. Acquire knowledge about inspection. 2. Calibrate basic metrology instruments used in machine shop. 3. Measure linear, angular and form features of a components.

Experiments 1. Calibration of the following instruments: i. Calibration of Micrometer ii. Calibration of Mechanical Comparator ii. Calibration of Vernier Caliper iv. Calibration of Dial Gauge 2. Measurement of taper angle using i. Bevel Protractor ii. Dial Gauge iii. Sine-Bar 3. Alignment tests: i. Parallelism of the spindle ii. Circularity & Concentricity of the spindle 4. Gear parameters Measurement i. Diameter, pitch/module ii. Pitch circle diameter iii. Pressure angle iv. Tooth thickness 5. Measurement of small components (Gear) by Profile Projectors 6. Tool Wear Measurement using Toolmakers Microscope References Lab Manual prepared by VIT faculty Mode of Evaluation Experiments/Record work/Oral/ Practical Examination

MEE308 INDUSTRIAL ENGINEERING AND MANAGEMENT 3 0 0 3 Pre requisite - Objectives 1. To enable the students understand the demand forecasting techniques and

costing. 2. To provide students an insight into the concepts of industrial engineering and organization. 3. To familiarize the students with principles of work-study and Ergonomics. 4. To introduce students to various aspects of plant design and materials planning.

Expected Outcomes

Student will be able to 1. Conduct market research, demand forecasting and costing 2. Demonstrate the knowledge of designing plants and controlling production. 3. Optimize the resources of an organization and improve productivity.

Unit I Demand Forecasting and Elements of Cost Macro and micro economics - Demand and supply Factors influencing demand Elasticity of demand Demand forecasting Time series - Exponential smoothing casual forecast - Delphi method Correlation and Regression - Barometric method Long run and Short run forecast. Elements of cost Determination of Material cost - Labour cost - Expenses Types of cost Cost of production - Over head expenses Problems. Unit II Industrial Organisation Introduction to Industrial Engineering Concepts - History and Development of Industrial engineering Roles of Industrial Engineer Applications Productivity Factors affecting productivity Increasing productivity of resources Kinds of productivity measures. Unit III Work Design Introduction to work study Method study Time study stopwatch time study Standard data - Method Time Measurement (M-T-M) Work sampling Ergonomics. Unit IV Plant Layout and Group Technology Plant location - Factors - Plant layout - Types - Layout design process Computerized Layout Planning Construction and Improvement algorithms -ALDEP - CORELAP and CRAFT. Group technology-Problem definition - Production flow analysis - Heuristic methods of grouping by machine matrices Flexible Manufacturing System - FMS work stations-Material handling and Storage system-Cellular Manufacturing System. Unit V Production Planning and Control Types of productions, Production cycle-Process planning, Forecasting, Loading, Scheduling, Dispatching, Routing- Simple problems. Materials Planning ABC analysis Incoming materials control Kanban system Just in time. MRP systems- Master Production Schedule Bill of Materials MRP calculations - MRP II. Text Books 1. Buffa E.S., (2009), Modern Production / Operational Management, John Wiley & Sons. References 1. Nigel Slack, Stuart Chambers, Robert Johnston., (2010)Operation Managenment, Pearson Education

2. R.Danreid & Sanders., (2009), Operations Management, John Wiley & Sons. 3. Panneerselvam. R. (2006), Production/Operations Management, Prentice Hall of India Pvt Ltd. Mode of Evaluation


MEE307 CAD/CAM 2 0 4 4 Pre requisite MEE207 Objectives 1. To understand the basics of CAD/CAM.

2. To gain exposure over the concepts of computer graphics. 3. To learn about the geometric issues concerned to the manufacturing and its related areas. 4. To understand the latest advances in the manufacturing perspectives.

Expected Outcomes

Student will be able to 1. Understand the importance of CAD/CAM principles in the Product development. 2. Develop programs related to manufacturing using codes. 3. Analyze the importance of networking in manufacturing environment.

Unit I Computer Hardware Product Development Cycle Introduction to CAD/CAM Graphics I/O Devices - Bresenhams Algorithm and DDA, Graphics software, Clipping, Hidden line/surface removal, Color models Lighting and shading - Graphics Standards Neutral File formats IGES, STEP Unit II Principles of Computer Graphics Geometric Modeling Wireframe, Surface and Solid Parametric representation of curves & surfaces - CSG and B-Rep- World/device coordinate representations, 2D and 3D geometric transformations, Matrix representation, translation, scaling, shearing, rotation and reflection, composite transformations, concatenation. Unit III CNC Machine Tools Introduction to NC, CNC, DNC- Manual part Programming Computer Assisted Part Programming Examples using NC codes- Adaptive Control Canned cycles and subroutines CAD / CAM approach to NC part programming APT language, machining from 3D models. Unit IV Group Technology, CAPP and FMS Introduction to part families-parts classification and cooling group technology machine cells-benefits of group technology Process Planning CAPP & types of CAPP Flexible manufacturing systems (FMS) the FMS concept-transfer systems head changing FMS Introduction to Rapid prototyping, Knowledge Based Engineering. Unit V CIM CIM wheel CIM Database- CIM-OSI Model Networking Standards in CIM Environment Network structure Network architecture TCP/IP, MAP Virtual Reality, Augmented Reality- Artificial Intelligence and Expert system in CIM. Text Books 1. Ibrahim Zeid and R. Sivasubramaniam, CAD/CAM: Principles and Applications 3rd Edition, Tata McGraw Hill, India, 2010. References 1. Mikell P. Groover, Automation, Production Systems and Computer Integrated Manufacturing, Pearson Education, 2007 2. James A. Rehg, Henry W. Kraebber, Computer Integrated Manufacturing, Pearson Education. 2007 3. Donald Hearn and M.Pauline Baker Computer Graphics with OpenGL Prentice Hall, International, 2010 Mode of Evaluation Quiz/Assignment/ Seminar/Written Examination

MEE307L CAD/CAM LAB CAD EXPERIMENTS 1. Structural analysis of Trusses 2. Structural analysis of Beams 3. Structural analysis of Frames 4. Plane stress/Plane strain analysis 5. Model analysis of different structures 6. Steady state thermal analysis 7. Transient thermal analysis 8. Flow analysis 9. Thermo-mechanical analysis CAM EXPERIMENTS 1. Manual part programming using G and M codes for Turning, Step turning, Taper turning, multiple turning, Facing, Multiple facing, thread cutting and radius turning on cylindrical components. 2. CNC Milling program involving linear motion and circular interpolation. 3. CNC Milling program involving contour motion and canned cycles. 4. CNC Milling program involving Pocket milling 5. Diagnosis and trouble shooting in CNC machine 6. CNC code generation using any CAM software. 7. Simulation of machining operations using any CAM software. 8. Route sheet generation using CAM software. 9. Study and practical demonstration on Wire-Cut EDM, 10. Study and practical demonstration on Coordinate measuring machine, 11. Study and practical demonstration on Vertical Machining center and Horizontal Machining center 12. Study on Rapid Prototyping Technologies, Student shall submit team work in the form of project /assignments with neat documentation. Reference Books: Lab Manual prepared by VIT faculty Mode of Evaluation: Experiments/Record work/Oral/ Practical Examination

MEE432 TOOL DESIGN 2 1 0 3 Pre requisite MEE247 or (MEE217 & MEE302) Objectives 1. To teach students the fundamentals of work holding devices.

2. To enable the students design tools, dies, jigs and fixtures. 3. To teach students to analyze and optimize an existing jig and fixture. 4. To expose students to design of dies for press work and forging.

Expected Outcomes

Student will be able to 1. Identify the importance of work holding device. 2. Design jigs and fixtures. 3. Calculate the required specifications of a press for required operations. 4. Design tools and dies for required operations.

Unit I Design of Cutting Tools Metal cutting process - Selection of tool materials - Design of single point and multipoint cutting tool - Form tools, Drills, Milling cutters, broaches and chip breakers Problems on design of single point cutting tools only. Unit II Locating and Clamping Methods Basic Principles of Location - Locating methods and devices - Principles of clamping - Mechanical, Pneumatic and Hydraulic actuation - Clamping force analysis Design problems. Unit III Design of Jigs Types of drill jigs - General considerations in the design of drill jigs - Drill bushings - Types, methods of construction - Simple designs of Plate, Channel, Boxes, Post, Angle plate, Turnovers and Pot Jigs. Unit IV Design of Fixtures Design principles - Types of fixtures - Fixtures for machine tools: Lathe, Milling, Boring, Broaching and grinding - Assembly fixtures - Inspection and Welding fixtures. Unit V Design of Dies Press tools - Fundamentals of die-cutting operations - Cutting action in punch and die operations - Die clearance - Blanking and Piercing Die construction Pilots - Strippers and Pressure Pads - Press work materials - Strip layout - Design of simple progressive and compound die sets - Forging Die Flow lines, parting lines, open and close die forging; Materials for die block. Text Books 1. Donaldson C., Lecain G.H. and Goold V.C. (2007), Tool Design, 3rd edition, Tata McGraw- Hill Publishing Company Ltd., New Delhi. References 1. Joshi P. H., (2004) Jigs and Fixtures, 2nd Edition, Tata McGraw-Hill Publishing Company Ltd., New Delhi. 2. Edward G. Hoffman (2004) Jigs and Fixtures Design, Thomson - Delmar Learning Series, Singapore. 3. Jeff Lantrip, David A. Smith and John G. Nee, (2003) Fundamentals of Tool Design, 5th Edition, Society of Manufacturing Engineers. Mode of Evaluation


MEE252 SIMULATION MODELING AND ANALYSIS 3 0 2 4 Pre requisite MAT104 Objectives 1. To introduce modeling, optimization and simulation, as it applies to the study

and analysis of manufacturing systems for decision support. 2. To expose students to a wide range of applications for simulation methods and models, and to integrate them with their introduction to operations management.

Expected Outcomes

Student will be able to 1. Develop the practical skills necessary to design, implement and analyze discrete-event simulation systems. 2. Cover the basic theory underlying discrete-event simulation methodologies, in order to enable a critical understanding of simulation output in managerial environments and build the foundations necessary to quickly adapt to future advances in simulation technology.

Unit I Introduction to System Simulation Introduction to system simulation Applications Discrete and Continuous simulation Simulation models Simulation procedure Simulation Examples General Principles. Unit II Random Numbers/Variates Random number generation-Testing of Random numbers Techniques for generating random numbers- Random Variate Generation Inverse transform techniques-Acceptance - Rejection techniques- Special properties. Unit III Analysis of Simulation Data Input modeling Data collection Identifying the distribution with data- Parameter estimation - Goodness of fit tests Fitting a non-stationery Poisson`s process- Selecting input models without data-Multi Variate and Time Series Input Models- Model Building Verification, Validation and Calibration of Simulation Models Output analysis Comparison and Evaluation of Alternative System designs. Unit IV Simulation Languages Need for simulation Languages Comparisons & Selection of Languages GPSS ARENA - EXTEND Study of any one of the languages Unit V Applications Simulation of Manufacturing and Material Handling systems Simulation of Computer Systems Simulation of Computer Networks. Text Books 1. Jerry banks, John S Carson, Barry L Nelson and David M Nicol, Discrete Event System Simulation, 4th edition, Pearson Education Asia, 2006. References 1. Averill M. Law and W David Kelton, Simulation Modeling and Analysis, 3rd Edition, McGraw Hill, 2000. 2. W David Kelton, Randoll P Sadowski and Debroah A Sasowski, Simulation with ARENA, McGraw Hill, 2002. Mode of Evaluation


SIMULATION LABORATORY OBJECTIVE: To give hands on experience with reference to computer based discrete system simulation experiments List of Experiments: 1. Random Number Generation Mid Square, Constant Multiplier, Congruential 2. Random variates Generation Exponential, Poisson, Normal, Binomial 3. Testing of Random variates Chi-Square, KS, Run 4. Monte Carlo Simulation Random Walk Problem 5. Queuing Models Single, Multi Server 6. Other IE oriented models Inventory, Replacement, Production system etc 7-10 Use of Simulation Language/Package

MEE387 MANUFACTURING AUTOMATION 3 0 2 4 Pre requisite MEE245 and MEE246 Objectives 1. To learn the concepts of automation systems in manufacturing sector.

2. To be aware of the operations machine tool drive systems. 3. To explore the robotics application in manufacturing. 4. 4. To be aware of intelligent machining operations.

Expected Outcomes

Student will be able to 1. Indentify the basic components required for manufacturing systems automation. 2. Appreciate the functions of sensors, drive systems and controllers used in machine tools. 3. Intend an automated material handling and inspection systems with robotics. 4. Realize methods for intelligent control of machine tools.

Unit I Automation in manufacturing operations Concepts of manufacturing systems and production processes. Automation in production systems and their classification. Product/production relationships, production concepts and mathematical models and costs of manufacturing operations. Unit II Automatic control in manufacturing Automated systems functions, levels, continuous and discrete controls, sensors and actuators. Machine tool drives- components, feedback, position control, and active damping of feed drives. Programmable logic controllers architecture, programming with ladder logic diagrams and applications. Human-machine and Man-machine interfaces Control of electro-hydraulic and electro-pneumatic systems. Unit III Numerical control and robotics NC and CNC units Part programming Direct Numerical control Adaptive control. Robot anatomy specifications end effectors applications in manufacturing. Flexible manufacturing systems. Automated inspection systems. Unit IV Automated material handling and inspection systems Automated guided vehicle systems Automated storage and retrieval systems Automatic data capture - Bar coding technology. Automated inspection systems. Unit V Sensor assisted machining Intelligent machine module - hardware and software architecture, applications. Adaptive control of forces in machining control algorithm, generalized predictive control, In-process detection of tool failure. Vibration control- modal testing of machine structures. In-process monitoring systems. Text Books 1. Mikell P.Groover, Automation, Production Systems and Computer Integrated Manufacturing, Princice HI, 2003. References 1. Yusuf Altintas, Manufacturing Automation, Cambridge University Press, 2nd Edition, 2012. 2. Beno Benhabib, Manufacturing Design, Production, Automation and Integration, Taylor-Fancis Publications, 2005. 3. Mikell P.Groover, Emory W. Zimmers, Jr., CAD/CAM: Computer - Aided Design and Manufacturing, PHI, 2007. Mode of Evaluation

Assignments, seminars, projects, reports and written examination.

Manufacturing automation laboratory experiments: 1. Study of programmable controllers and programming. 2. Interfacing programmable logic controllers with sensors and actuators. 3. Design of HMI/MMI for machine tool control. 4. Design of electro hydraulic and pneumatic systems for machine tools. 5. Measurement of tool forces and temperature using sensors. 6. Control of stepper and servomotors. 7. Study of modular automation production systems. 8. Working with vision inspection systems.

MEE354 KINEMATICS & DYNAMICS OF MACHINERY 2 1 2 4 Pre requisite MEE248 or MEE202 Objectives 1. To provide students an understanding of different types of mechanisms.

2. To teach students how to analyze cam-follower motion and gear train configurations. 3. To help students gain knowledge in solving problems related to gyroscopic effect on vehicles, ships and planes 4. To teach students the balancing procedures for rotating and reciprocating masses, rotors and engines. 5. To teach students the fundamentals of free and forced vibrations.

Expected Outcomes

Student will be able to 1. Demonstrate an understanding of the concepts of various mechanisms and pairs. 2. Analyze and solve problems associated with mechanisms. 3. Solve problems related to cam-followers and gear trains. 4. Demonstrate an understanding of principle of gears. 5. Calculate gyroscopic couple effect on various vehicles.

Unit I Introduction to Mechanisms Introduction to mechanisms Links - Pairs - Chains - Mobility - Degree of freedom Grueblers and Kutzbach criterion Kinematics inversions- Grashoffs Law. Determination of velocity andacceleration - simple mechanisms Relative motion method. Introduction to synthesis of mechanism. Inertia force analysis of slider crack mechanism- Kleins construction. Unit II Friction Friction in screw and nut Pivot and collar Thrust bearing Plate and disc clutches Belt (flat and V) and rope drives. Ratio of tensions Effect of centrifugal and initial tension Condition for maximum power transmission Open and crossed belt drive. Gyroscopic forces and couple Gyroscopic effects on the movement of air planes and ships - Stability of two wheel drive and four wheel drive and space vehicles - Gyroscope stabilization. Unit III Cam and Gears Types of Cams and Followers - Applications Displacement - Velocity and Acceleration and construction of cam profiles for Uniform velocity - Uniform acceleration and retardation Simple Harmonic Motion (SHM) - Cycloidal motions of followers Spur gear terminology and definitions -Types of gears- Fundamental law of toothed gearing Interference and under cutting Comparison of Involute and Cycloidal tooth forms.ear trains: Simple, compound gear trains and epicylic gear trains - Determination of speed and torque. Unit IV Balancing Static and Dynamic balancing of rotating masses in different planes Balancing of rotors -Balancing of machines - Partial balancing of reciprocating masses of inline 98 Unit V Vibrations Free, and damped vibrations of single degree of freedom systems - longitudinal transversetorsional Forced vibration harmonic excitation - Magnification factor - Vibration isolation and Transmissibility. Introduction to vibrations of multi-degree freedom systems. Text Books 1. S.S. Rattan, (1999), Theory of Machines, Tata McGraw Hill publishing companies Ltd.

References 1. J.S. Rao and R.V Dukkipati, (2000), Mechanism and Machine theory, Wiley- Eastern Ltd. New Delhi. 2. J.E. Shigley and J.J Unicker, (1999), Theory of Machines and Mechanics, McGraw Hill. 3. Thomson. W.T. (1995), Theory of Vibration with applications, Prentice Hall of India. 4. Dukkipati, Srinivas, (2005), Theory of mechanical vibrations, Prentice Hall of India. Mode of Evaluation

Assignment/ Seminar/Written Examination

MEE253 RELIABILITY, MAINTENANCE AND SAFETY

ENGINEERING 3 0 0 3

Pre requisite MAT104 Objectives 1. To train the students with the necessary knowledge and abilities to

support the implementation of Asset Reliability Improvement processes in their Plant and gain a working knowledge of Maintenance Strategy Review techniques focused upon Reliability Centered Maintenance (RCM). 2. To introduce the students to quantitative reliability and safety assessment methodologies that are commonly used by industries, consultants, and authorities to improve the safety of new developed and established infrastructures, production systems and products.

Expected Outcomes

At the end of the semester, students will be able 1. To develop, operate and maintain safe, reliable and maintenance friendly systems. 2. To find overall solutions on safety, reliability and maintainability challenges for industrial applications and public administration.

Unit I Reliability definition Reliability function Graphical representation a priori, a posteriori probabilities of survival. Component mortality Mortality curve Useful life Reliability mathematics - Failure Rate, Mean Time Between Failures (MTBF)-Mean Time To Failure (MTTF), Bathtub distribution, Down time, Repair time, Availability, Reliability Allocation, Mechanical Reliability. Unit II Series parallel configurations Redundant systems Standby systems K out of n redundancy Reliability of complex systems: RBD approach Bayes decomposition method Cut and tie sets Fault tree analysis Markov model Software reliability prediction and measurement. Unit III Maintenance and Maintenance Engineering Objectives, facts, Maintainability Terms and Definitions, Importance, Preventive Maintenance, Corrective Maintenance, Total Productive Maintenance, Reliability Centered Maintenance, Inventory Control in Maintenance. Unit IV Maintenance Planning & Condition Based Maintenance - on - load and Off-Level Monitoring- Maintenance of Mechanical and Electrical equipments. Unit V Safety - Importance - Fundamental Concepts and Terms- Workers Compensation - Product Liability - Hazards and their Control - Walking and Working Surfaces, Electrical Safety -Tools and Machines - Materials Handling. Fire Protection and Prevention -Explosions and Explosives - Radiation -Biohazards - Personal Protective Equipment - Managing Safety and Health. Text Books 1. Maintainability, Maintenance and Reliability for Engineers, B.S. Dhillon, CRC Press, 2006 References 1. Handbook of Reliability engineering - Hoang Pha, Springer Publication, 2003. 2. Engineering maintenance; a modern approach - B.S. Dhillon, CRC Press, 2002 3. Maintenance Fundamentals, R. Keith Mobley, II edition, Butterworth-Heinemann, 2004 4. Reliability Maintainability and Risk; Practical methods for engineers - David J Smith, Butterworth-Heinemann, New Delhi, 2001

5. Safety and Health for Engineers - Roger L. Brauer, John Wiley Sons, 2006 Mode of Evaluation


MEE254 STATISTICAL QUALITY CONTROL 3 0 2 4 Pre requisite MAT104 Objectives 1. Students become familiar with the notion of a state of statistical control in

process design and control. 2. Students learn control chart techniques for on-line continuous quality improvement. 3. Students learn the fundamentals of tolerancing and process capabilities. 4. Students learn the principles of Taguchi's loss function in quality.

Expected Outcomes

At the end of the course, students should 1. Learn formulations, models, and analytical procedures for the study of quality control; 2. Learn fundamental principles of statistical quality control techniques; 3. Be able to implement the quality engineering tools in industrial applications; and 4. Improve team working skills and data-collecting capability.

Unit I Quality Fundamentals Importance of quality, meaning of quality, quality dimensions, quality planning, quality control, SQC, Quality assurance, quality costs, economics of quality, quality and productivity, quality and reliability, quality loss function. Unit II Control Charts For Variables Process variation, Statistical basis, 3 sigma control limits, Rational sub-grouping, X ,R and S charts, Interpretation of charts, warning and modified control limits, operating characteristic curve for X chart, SPC -process capability analysis Cp, CPK, Cpm, Machine capability, Gauge capability. Unit III Control Charts For Attributes P, np, C, U and ku charts, demerits control chart, Multi variable chart, individual measurement charts moving average and moving range charts, quality control in service sector. Unit IV Acceptance Sampling Need for Acceptance sampling, economics of sampling, sample selection, single and Double sampling O.C. curves, Average outgoing quality (AOQ), Average sample number (ASN), Average total inspection (ATI), Multiple and sequential sampling, sampling plans military standards, Dodge Roming, IS 2500. Unit V Introduction To Iso And Six Sigma Introduction to ISO-9000 Systems, Elements of ISO-9000, Elements of ISO 9001-2008 system: Introduction, scope, quality management system, management responsibility, resource management, product realization, measurement, analysis and improvement - Introduction to Six Sigma - application of Six Sigma approach to various industrial situations. Text Books 1. Douglus C.Montgomery, Introduction to Statistical Quality Control, John Wiley & Sons, 2004. References 1. Statistical Quality Control, Eugene L. Grant and Richard S. Leaven Worth, TMH, Seventh Edition, 2000. 2. Quality Control. Dale H. Besterfield, Pearson Education Asia, Seventh Edition,2004. 3. Introduction to Statistical Quality Control, 6th Edition, Douglas C. Montgomery, Prentice-Hall, Inc., 2005. Mode of Evaluation Quiz/Assignment/ Seminar/Written Examination

QUALITY CONTROL LABORATORY

Objective:

The main objective is to enable the students to learn how to set up and use control charts for individual measurements and to master them with the construction and analysis of Control Charts. List of Experiments:

1. Statistical Process Control: Control Charts - Variable control Charts and R Charts

2. Process Capability Analysis; Attribute control Charts P- Chart, C-chart, np chart;

3. Acceptance sampling: Operating Characteristics curve;

4. Probability Distributions: Normal Distribution, Rectangular Distribution.

5. Design of Experiments Software:

6. Reliability Software: Introduction and Practice on Reliasoft

MEE437 OPERATIONS RESEARCH 2 1 0 3 Pre requisite MAT104 Objectives 1. To provide students the knowledge of optimization techniques and

approaches. 2. To enable the students apply mathematical, computational and communication skills needed for the practical utility of Operations Research. 3. To teach students about networking, inventory, queuing, decision and replacement models. 4. To introduce students to research methods and current trends in Operations Research.

Expected Outcomes

Student will be able to 1. Apply operations research techniques like L.P.P, scheduling and sequencing in industrial optimization problems. 2. Solve transportation problems using various OR methods. 3. Illustrate the use of OR tools in a wide range of applications in industries. 4. Analyze various OR models like Inventory, Queing, Replacement, Simulation, Decision etc and apply them for optimization. 5. Gain knowledge on current topics and advanced techniques of Operations Research for industrial solutions.

Unit I Linear Models Introduction to Operations Research Linear Programming - Mathematical Formulation Graphical method Simplex method Duality Two Phase Simplex method Transportation problems Northwest Corner method Vogels Approximation method MODI method Assignment problems Applications. Unit II Sequencing and Networks Sequencing Problem with N jobs and 2 machines - 3 machines and M machines. Network models Basic Concepts Construction of Networks Project Network CPM and PERT - Critical Path Scheduling Crashing of Network. Unit III Inventory Models Inventory models Various Costs and ConceptsEOQDeterministic inventory models Production models Stochastic Inventory models Buffer stock. Unit IV Queuing Models Queuing models Poisson arrivals and Exponential service times Single channel models and Multi channel models. Simulation Basic concepts Advantages and Disadvantages Random number generation Monte-Carlo Simulation Simulation models. Unit V Decision Models Decision models Game theory Two person zero sum game Graphic solution - Property of dominance Algebraic solution. Replacement models Items that deteriorate with time - When money value changes Items that fail completely Individual replacement and Group replacement. Text Books 1. Hamdy Taha, (2009), Operations Research: An Introduction, Pearson Education Inc. References 1. Hira D S and Gupta P K, (2007), Operations Research,S.Chand & Sons. 2. Panneerselvan. R. (2006), Operation Research, Prentice Hall of India Pvt Ltd 3. Kanti Swarup, Gupta P.K., and Manmohan, (2004), Operations Research, S.Chand & sons. Mode of Evaluation Quiz/Assignment/ Seminar/Written Examination

MEE434 PRODUCTION PLANNING AND CONTROL 3 0 0 3 Pre requisite MEE308 Objectives 1. To get clear idea about various types of production like job, batch and

continuous. 2. To find out the sales forecasting, various types of demands and different methods. 3. To acquire knowledge in product planning and process planning, value analysis and value engineering and bread even analysis. 4. To learn about various types of controls toward inventory planning. 5. To be familiar in operation scheduling, ie loading, scheduling and routing etc.

Expected Outcomes

Student will be able to 1. Identify and suggest correct type of production planning technique. 2. Analyze the concepts of production planning and Control and implement in crucial areas of the industry.

Unit I PPC performance PPC Requirements, Benefits, Factors influencing PPC performance, 3 types of decisions 3 Phases of PPC Aggregate and Disaggregate Planning Master Production Schedule (MPS) Techniques & Hour Glass Principle Bill of Material (BOM) structuring. Unit II MRP Material Requirements Planning (MRP) System Inputs, Outputs, Benefits, Technical issues MRP system nervousness Manufacturing Resources Planning (MRP II) Resource Planning - Final assembly scheduling. Unit III Capacity management Capacity Planning using overall factors (CPOF) Capacity Bills Resource Profiles Capacity requirements planning (CRP) I/O Control - Shop floor control Basic concepts, Gantt Chart, Priority sequencing rules and Finite Loading Inventory models. Unit IV Shop floor control Shop floor control Just in time (JIT) Key elements, techniques JIT & PPC Pull & Push Systems Kanban system Types, number of kanban calculations, Design, advantages and disadvantages Unit V ERP System ERP systems Components, Modules, Implementation, advantages and disadvantages - Technical aspects of SAP - Supply Chain Management (SCM) Components, stages, Decision phases Supply chain macro processes in a firm. Text Books 1. Vollmann, T.E., Berry, W.L., Whybark, D.C., and Jacobs, F.R., (2005), Manufacturing Planning and Control for Supply Chain Management (5th ed.), Irwin. References 2. Curran, T. and Keller, G.,(2009), SAP R/3 Business Blueprint Prentice-Hall. 3. Sipper D, Bulfin, R.L,(2007), Production Planning,Control,and Integration,McGraw Hill. 4. S.K. Mukhopadhyay (2009), Production planning and control Text and Cases, PHI Ltd. Mode of Evaluation


MEE446 OPTIMIZATION TECHNIQUES 2 1 2 4 Pre requisite MEE437 Objectives 1. Some of the Operations Research techniques which are not covered in the

first level course are dealt with. Expected Outcomes

Student will be able: 1. To formulate a wide range of management problems that can be solved to optimality by classical combinatorial optimization techniques and the knowledge of alternative solution approaches such as metaheuristics that can find nearly optimal solutions.

Unit I Multi Criteria Models Data Envelopment Analysis, Multicriteria Decision Problems- Goal Programming, Analytic Hierarchy Process Unit II Non Linear Models -I Types of Non-linear programming problems, unconstrained optimization, Linearly Constrained Optimization, Quadratic Programming, Convex Programming. Unit III Non Linear Models Ii KKT conditions for constrained optimization, Separable programming, Non-convex programming, Geometric programming. Unit IV Markov Processes Markov Processes, Neural network based optimization. Unit V Metaheuristics Metaheuristics - Genetic Algorithms, Simulated Annealing, Ant Colony Optimization. Text Books 1. Singiresu S Rao, Engineering Optimization, John Wiley & Sons, 2009 References 1. Kalyanmoy Deb, Optimization for Engineering Design, PHI,2000. 2. David R. Anderson, et al , An Introduction to Management Science Quantitative approaches to Decision Making, Thomson,2003. 3. Fred Glover et al., Handbook of Metaheuristics, Kluwer,2003. 4. Hillier and Liberman, Introduction to Operations Research, TMH, 2000 Mode of Evaluation

OPTIMIZATION TECHNIQUES LAB OBJECTIVE: To give adequate exposure to applications of software packages in the areas of

Operations Research and Optimization process.

Simple Operations Research Programs

1. Initial Solution of TP,

2. Inventory Price Break Models

Optimization Package (TORA /LINDO)

3. LP Models

4. Transportation

5. Assignment

6. Maximal flow

7. Minimal spanning tree

8. Shortest route

9. Network scheduling

MEE447 TOTAL QUALITY MANAGEMENT 3 0 0 3 Pre requisite MEE308 Objectives 1. To provide comprehensive knowledge about the principles, practices, tools

and techniques of Total quality management. Expected Outcomes

Student will be able to 1. To understand the various principles, practices of TQM to achieve quality. 2. To learn the various statistical approaches for Quality control. 3. To understand the TQM tools for continuous process improvement. 4. To learn the importance of ISO and Quality systems

Unit I Introduction Introduction - Need for quality - Evolution of quality - Definition of quality - Dimensions of manufacturing and service quality - Basic concepts of TQM - Definition of TQM TQM Framework - Contributions of Deming, Juran and Crosby Barriers to TQM. Unit II Tqm Principles Leadership Strategic quality planning, Quality statements - Customer focus Customer orientation, Customer satisfaction, Customer complaints, Customer retention - Employee involvement Motivation, Empowerment, Team and Teamwork, Recognition and Reward, Performance appraisal - Continuous process improvement Supplier partnership Partnering, Supplier selection, Supplier Rating. Unit III Tqm Tools & Techniques I The seven traditional tools of quality New management tools Six-sigma: Concepts, methodology, applications to manufacturing, service sector including IT Bench marking Reason to bench mark, Bench marking process FMEA Stages, Types. Unit IV Tqm Tools & Techniques Ii Quality circles Quality Function Deployment (QFD) Taguchi quality loss function TPM Concepts, improvement needs Cost of Quality Performance measures. Unit V Implementation Of Tqm Steps, KAIZEN, 5S, JIT, POKAYOKE, I - Introduction to Robust Design, Taguchi Principles and Design, Case studies. Text Books 1. Dale H.Besterfiled, et at., Total Quality Management, Pearson Education Asia, Third Edition, Indian Reprint (2006). References 1. James R. Evans and William M. Lindsay, The Management and Control of Quality, (6th Edition), South-Western (Thomson Learning), 2005. 2. Oakland, J.S. TQM Text with Cases, Butterworth Heinemann Ltd., Oxford, Third Edition (2003). 3. Suganthi,L and Anand Samuel, Total Quality Management, Prentice Hall (India) Pvt. Ltd. (2006) Mode of Evaluation


MEE255 INDUSTRIAL ECONOMICS 3 0 0 3 Pre requisite - Objectives 1. To familiarize students with a broad range of the methods and models

applied by economists in the analysis of firms and industries. 2. To ensure that students who take the course will, by working extensively with theoretical models, acquire analytical skills that are transferable to other kinds of intellectual problems.

Expected Outcomes

Upon completion of the course students should: 1. Be able to solve analytically problems relating to industrial economics. 2. Be familiar with the functioning of different experimental market institutions and the key results of these experiments. 3. Demonstrate understanding of verbal, graphical, mathematical and econometric representation of economic ideas and analysis, including the relationship between them.

Unit I The scope of Industrial Economics and its History. Industrial efficiency: Concepts and Measurement. Meaning of the concept. The Determinants of efficiency levels. Some efficiency conditions in the theory of production, Efficiency and decision making process. The organisational fOlDl and alternative motives of the fimt. Types of organisational fOlDl. Business Motives. Unit II Demand Analysis - The Theory of Demand. The elasticity concept. Demand for the Products of Individual firms in an Industry. Demand forecasting. The cost theory and optimum size of the firm. The theory of cost and production. The efficiency and size of the firm. Unit III The Elements of Market Structure - Some concepts - standard forms of Market structure - The concept of workable competiton. The conceptual frame work of the study of Industrial Economics. Market stroctw"e and Innovation. The process of innovation, concepts and Relationships, Measuremerit of innovation activities - The Theory of technological innovation. Diffusion of New Technology. Unit IV Industrial Finance and Accounting - The need for finance - types of Finance - sources of finance - contribution of various sources finance in Indian situation. Choice of Funding: Internal VB External sources. An evaluation of Indian Industrial policy. The ways and means of Government regulation of Industry. Unit V Labour productivity concept of labour productivity and its measurement - the determinants of labour productivity - Risk and Decision Making Technological Change in Global Economy Locating the Firm in a global economy Taxes and Decision Making. Text Books 1. R.R. Barthwal (2007) - Industrial Economics, New Age International.. References 1. Bhagawati and P. Desai, India: planning for Industrialisation 2. W. Stewart, Industrial Economics: An applied approach (Macmillan) 3. Rogar Clark - Industrial Economics Blackwall- Oxford.

4. P.J. Devons et al. An introduction to Industrial Economics.(Allen and Wlwin.). Mode of Evaluation


HUM101 PSYCHOLOGY / SOCIOLOGY 3 0 0 3 Pre requisite - Objectives 1. Developed with the idea of making the students acquainted with the basic

concepts of Psychology as well as Sociology so as to equip them to be better social beings. 2. To help students broaden their view of society beyond their own immediate experience and understand how and why their own experience may be similar or different to the experience of other.

Expected Outcomes

Unit I Psychology Science of Psychology Meaning Objectives Schools of Psychology Psycho analysis Behaviorism Humanism Sensation and perception, Emotion and motivation. Cognitive abilities and Intelligence Personality. Unit II Applications of Psychology Memory Building and Mind Mapping Stress Management Career Planning and Management Ergonomics Cybernetics Case Studies Unit III Social Psychology Nature and Scope Social Psychology and Related disciplines Cultivation and development of human values social changes urbanization westernisation social problems social unrest action child labour gender injustice. Unit IV Attitudes and Behavior Impression Management Team Work and its success Assertive behaviour Developing positive attitude Case studies. Unit V Sociology Definition of Sociology subject matter society definition and characteristics social structure social groups social institution culture cultural diversity socialization social rules norms and values Case studies. Text Books 1. Clifford T. Morgan, Richard A. King, John R. Weisz, John Schopler Introduction to Psychology, Tata McGraw Hill Edition 7th Edition, 2008. 2. John J. Makionis Sociology, Pearson Education, 10th Editiion, 2008. References 1. John J Makionis Sociology- Pearson Education in South Asia : New Delhi 2006. 2. Edward E. Smith, Susan Nolen, Hoeksema, Barba Fredickson, Geoffrey R. Lottus Introduction to Psychology, Atkinson & Hilgards 14th Edition, 2008. 3. Shelley E. Taylor, Letitia Anne Peplan, David O. Sears, Social Psychology Pearson Education, 12th Editiion, 2008. Mode of Evaluation

Written Examinations and any of these: Term Paper, Mini Projects, Quiz, Group Discussion, Case Study Analysis, Seminar, Assignments etc.

MEE338 DESIGN OF COMPOSITE MATERIALS 2 1 0 3 Pre requisite MEE109 or MEE203 & MEE214 Objectives 1. To enable the students understand the properties and design of composite

materials 2. To familiarize the students with the manufacturing methods for

composites 3. To teach the practical requirements associated with joining and

manufacturing Expected Outcomes

Student will be able to 1. Design and manufacture composite materials for various applications. 2. Conduct mechanical testing of composite structures and analyse failure

modes. 3. Synthesize structures for environmental effects. 4. Analyze economic aspects of using composites. 5. Understand the relevance and limitations of the destructive and

nondestructive test methods used for composites. 6. Demonstrate the ability to use appropriate design and analysis tools and

techniques. Unit I Introduction Definitions: Composites, Reinforcements and matrices, Types of reinforcements, Types of matrices, Types of composites, Carbon Fibre composites, Properties of composites in comparison with standard materials, Applications of metal, ceramic and polymer matrix composites. Unit II Manufacturing methods Hand and spray lay-up, press molding, injection molding, resin injection, RRIM, filament winding, pultrusion, centrifugal casting and prepregs. Fibre/Matrix Interface, Theories of adhesion; absorption and wetting, interdiffusion, electrostatic, chemical, mechanical. Measurement of interface strength. Characterization of systems; carbon fibre/epoxy, glass fibre/polyester, etc. Influence of interface on mechanical properties of composite. Unit III Mechanical Properties Stiffness and Strength: Geometrical aspects volume and weight fraction. Unidirectional continuous fibre, discontinuous fibers, Short fiber systems, woven reinforcements length and orientation distributions. Mechanical Testing: Determination of stiffness and strengths of unidirectional composites; tension, compression, flexure and shear. Fracture: Typical fracture processes; effect of transverse ply. Review of fracture mechanics methods and application to composites. Impact: Typical impact damage; role of fibre, matrix and interface. Low and high speed impact test methods. Fatigue: Behavior of notched and unnotched specimens. Tension testing of composites. Fatigue damage Effect of matrix and fibre properties. Implications for component design. Environmental Effects: Influence of moisture and other contaminants on fibre, matrix, interface and effect on mechanical properties. Stress corrosion cracking. Influence of high and low temperatures. Unit IV Laminates Plate S

production & b. tech. production and industrial engg. curriculum & syllabus

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