UG Course Structure for Mechanical Engineering (2016- 2017) · 2018. 4. 12. · UG Course Structure for Mechanical Engineering (2016-2017) UG -CRC Code Course Code Course Name L ±

UG Course Structure for Mechanical Engineering (2016-2017)

Cat. Deviation Programme Components MEC Recommended

(V Years)

Min Max

HU 0 Humanities and Social Science* 44 41 50

IS 0 Science* 67 62 84

IE 0 Institute Requirement Engineering/ Pharmacy* 59 41 60

EP 0 Engineering Drawing (Manual and Computer Aided), Manufacturing

Practices and Practice course of Department/ School* 21 20 24

LM -2 Language and Management* 18 20 24

DC/ MC 0 Department/Programme Core (Includes Stream Courses) 126 105 155

DE/ BE 0 Department/Programme Elective (Includes Stream Courses) 45 30 60

OE

0

Open Elective (Interdisciplinary Stream courses from Science/ Engineering/Pharmacy)(Room for Minor with some additional Credits)

36

35

80

DP 0 Project/ Industrial visit/ Training 30 20 50

DT 0 Dissertation 0 0 0

Total (UG) 446 430 460

Total (Hons.) 466 450 480

L: Lecture Hours, T: Tutorials Hours, P: Practical Or Laboratory Hours, C: Credits

List of Streams in Mechanical Engineering

Machine Design

Thermal and Fluid Engineering

Production Engineering

Industrial Management

One course to be selected, for respective stream in corresponding semester, on recommendation of DUGC

Stream - 1

Machine Design

UG PT. III (V sem.)

ME 312 Vibrations 3 0 0 9

ME 313 Materials for Tribological Applications 3 0 0 9

ME 314 Mechatronics 3 0 0 9

UG PT. III (VI sem.)

ME 323 Composite Materials 3 0 0 9

ME 324 Biomaterials 3 0 0 9

ME 325 Smart materials and structures 3 0 0 9

UG PT. IV (VII sem.)

ME 412 Fracture Mechanics 3 0 0 9

ME 413 Experimental Mechanics & NDT 3 0 0 9

ME 511 Optimization for Engineering Design 3 0 0 9

ME 512 Computer-aided Design 3 0 0 9

ME513 Theory of elasticity 3 0 0 9

ME 514 Theory of vibrations 3 0 0 9

ME 515 Advanced composite materials 3 0 0 9

ME 516 Mechanics of fracture and fatigue 3 0 0 9

ME 517 Vehicle Dynamics 3 0 0 9

UG PT. IV (VIII sem.)

ME 411 Finite Element Method 3 0 0 9

ME 421 Control Systems Engineering 3 0 0 9

ME 525 Tribology 3 0 0 9

ME 526 Impact Dynamics and Crashworthiness 3 0 0 9

ME 527 Theory of Plasticity 3 0 0 9

Stream-2

Thermal and Fluid Engineering

UG PT. III (V sem.) ME 331 Combustion Technology 3 0 0 9

ME 332 Thermal Management of Electronic System 3 0 0 9

UG PT. III (VI sem.) ME 342 Refrigeration & Air-conditioning 3 0 0 9

ME 343 Non-Conventional Energy Resources 3 0 0 9


ME 432 Automobile Engineering 3 0 0 9

ME 433 Computational Fluid Dynamics 3 0 0 9

ME 531 Advanced Thermodynamics 3 0 0 9

ME 533 Advanced Heat & Mass Transfer 3 0 0 9


ME 441 Internal Combustion Engine 3 0 0 9

ME 442 Bio Transport Mechanism 3 0 0 9

ME 443 Power Generation 3 0 0 9

ME 444 Wind Power Meteorology 3 0 0 9

ME 445 Applied CFD 3 0 0 9

Stream-3

Production Engineering

UG PT. III (V sem.) ME 352 Mechanical Behaviour of Engineering Materials 3 0 0 9

ME 353 Lasers in Manufacturing Technology 3 0 0 9

UG PT. III (VI sem.) ME 361 Tribology of Manufacturing Processes 3 0 0 9

ME 362 Modeling & Simulation of Manufacturing systems 3 0 0 9

UG PT. IV (VII

sem.)

ME 453 Manufacturing Systems 3 0 0 9

ME 454 Rapid Design & Manufacturing 3 0 0 9

ME 559 Casting and Welding 3 0 0 9


ME 451 Unconventional Machining Processes 3 0 0 9

ME 452 Theory of Abrasive Machining 3 0 0 9

ME 583 Simulation for Decision making 3 0 0 9

ME 461 Robotics 3 0 0 9

Stream-4

Industrial Management

UG PT. III (V sem.) ME 579 Engineering Economics (DE1) 3 0 0 9

ME 574 Production Planning and Control (DE1) 3 0 0 9

UG PT. III (VI sem.) ME 587 Forecasting and Time Series Analysis (DE2) 3 0 0 9

ME 485 Operations Research (DE2) 3 0 0 9


ME 472 Industrial Management (DE3) 3 0 0 9

ME 573 Supply Chain Management(DE3) 3 0 0 9

ME 453 Manufacturing Systems(DE3) 3 0 0 9

UG PT.IV(VIII sem.)

ME 582 Total Quality Management (DE4) 3 0 0 9

ME 583 Simulation for Decision Making(DE4) 3 0 0 9

ME 584 Marketing Management (DE4) 3 0 0 9

ME 581 Management Information System (DE5) 3 0 0 9

ME 585 Design of Production System(DE5) 3 0 0 9

ME 563 Green Manufacturing(DE5) 3 0 0 9

UG Course Structure for Mechanical Engineering (2016-2017)

UG-CRC Code Course

Code Course Name L–T–P Credits

Mechanical Engineering : 4-Year B.Tech. I-Semester

IH.H101.14 H101 Universal Human Values - I: Self and Family 1 1 0 5

GY.PR101.14 PE101 Elementary Physical Education 0 1 3 5

GY.CP101.14 CP101 Creative Practices # 0 1 3 5

Total 1 3 6 15

LM.HL101.14 HL101 Basic English* 2 0 1 7

Total 3 3 7 22

#Creative Practices course to be announced by Dean Academic Office

UG-CRC Code Course

Code Course Name L–T–P Credits

Mechanical Engineering : 4-Year B.Tech. I-Semester

IS.PHY 101.14 PHY 101 Physics I 3 1 2 13

IS.MA 101.14 MA 101 Engineering Maths I 3 1 0 11

IS.CY 101.14 CY 101 Chemistry -I 2 1 2 10

IE. ME 131.15 ME 131 Engineering Thermodynamics 3 1 0 11

EP.ME 151.16 ME 151 Manufacturing Practice I 0 0 3 3

EP.ME 111.16 ME 111 Engineering Drawing 1 0 3 6

Total Credits in the Semester 12 4 10 54

Mechanical Engineering : 4-Year B.Tech. II-Semester

IS.MA 102.14 MA 102 Engineering Maths II 3 1 0 11

IE.CSO 101.14 CSO 101 Computer Programming 3 1 2 13

IE.CMO 102.14 CMO 102 Engineering Mechanics 3 1 0 11

DC.ME 221.15 ME 221 Measurements and Controls 3 0 0 9

EP.ME 161.16 ME 161 Manufacturing Practice II 0 0 3 3

EP.ME 222.15 ME 222 Machine Drawing 0 0 3 3

IH.H105.14

HU/LM Philosophy*

2

1

0

8 IH.H106.14 Education and Self*


* The students have to choose one course from H105 & H106.

Mechanical Engineering : 4-Year B.Tech. III-Semester

IE.EO 101.14 EO 101 Fundamentals of Electrical Engineering 3 1 2 13

IE. ME 112.14 ME 112 Strength of Materials 3 1 0 11

DC.ME 231.15 ME 231 Fluid Mechanics and Fluid Machinery 3 0 2 11

DC.ME 251.15 ME 251 Manufacturing Technology 3 0 2 11

DP.ME 291.15 ME 291 Exploratory Project 0 0 5 5

IH.H103.14

HU/LM History & civilization*

2

1

0

8 IH.H104.14 Development of Societies*


*Students have to choose one course from H103 and H104.

Mechanical Engineering : 4-Year B.Tech. IV-Semester

IS.MA 201.14 MA 201 Numerical Techniques 3 1 0 11

DC.ME 223.15 ME 223 Theory of Machines 3 0 2 11

DC.ME 224.15 ME 224 Mechanics of Deformable Solids 3 0 2 11

DC.ME 241.15 ME 241 Heat and Mass Transfer 3 0 2 11

DC.ME 261.15 ME 261 Metal Machining & Machine Tools 3 0 2 11

IH.H102.14 HU/LM Universal Human Value – II 1 2 0 5


Section-BC Mechanical Engineering : 4-Year B.Tech. V-Semester

IS.MA 202.14 MA 202 Probability and Statistics 3 1 0 11

DC.ME 311.15 ME 311 Fundamentals of Machine Design 3 0 3 12

DC.ME 351.15 ME 351 Tool Design and Metrology 3 0 2 11

OE - 1 OE - 1 Open Elective I 3 0 0 9

DE1 DE - 1 Department Elective 1 (Design/ Thermal/Production/Industrial) 3 0 0 9

HU/LM HU/LM Humanities / Language & Management course^^ 3 0 0 9

Total Credits in Semester 18 1 5 61

DP ME391S Stream Project 0 0 10 10

Total (Hons. Students) 11 0 5 71

^^Course to be selected such that recommended HU & LM programme component get satisfied separately.

Department Elective -1 Courses

UG-CRC Code Course

Code Subject

DE.ME 312.15 ME 312 Vibrations 3 0 0 9

DE.ME 313.15 ME 313 Materials for Tribological Applications 3 0 0 9

DE.ME.314.15 ME 314 Mechatronics 3 0 0 9

DE.ME 331.15 ME 331 Combustion Technology 3 0 0 9

DE.ME 332.15 ME 332 Thermal Management of Electronic System 3 0 0 9

DE.ME 352.15 ME 352 Mechanical Behaviour of Engineering Materials 3 0 0 9

DE.ME 353.18 ME 353 Lasers in Manufacturing Technology 3 0 0 9

DE.ME 579.15 ME 579 Engineering Economics 3 0 0 9

DE.ME 574.15 ME 574 Production Planning and Control 3 0 0 9

Section-BC Mechanical Engineering : 4-Year B.Tech. VI-Semester

DC.ME 321.15 ME 321 Design of Machine Elements 3 0 2 11

DC.ME 341.15 ME 341 Energy Conversion Systems 3 0 2 11

EP.ME.322.15 ME 322 Computational Mechanics 0 0 3 3

OE - 2 OE - 2 Open Elective - 2 3 0 0 9

DE2

DE - 2 Department Elective (DE)-2

(Thermal/Design/Manufacturing/Industrial)

3

0

0

9


DP.ME392/S.15 ME392/ ME392S

Stream or UG Project 0 0 10 10



Department Elective-2 Courses

UG-CRC Code Course

Code Subject

DE.ME 323.15 ME 323 Composite Materials 3 0 0 9

DE.ME 324.15 ME 324 Biomaterials 3 0 0 9

DE.ME.325.15 ME 325 Smart Materials and Structures 3 0 0 9

DE.ME 342.15 ME 342 Refrigeration & Air-conditioning 3 0 0 9

DE.ME 343.15 ME 343 Non-Conventional Energy Resources 3 0 0 9

DE.ME 361.15 ME 361 Tribology of Manufacturing Processes 3 0 0 9

DE.ME 362.18 ME 362 Modeling & Simulation of Manufacturing systems 3 0 0 9

DE.ME 587.15 ME 587 Forecasting and Time Series Analysis 3 0 0 9

DE.ME 485.16 ME 485 Operations Research 3 0 0 9

Section-BC Mechanical Engineering : 4-Year B.Tech. Summer Semester

DP.ME.497.15 ME 497 Industrial Training/ Project/Training 0 0 0 5

Total 0 0 0 5

To be evaluated in in seventh semester for out station training

Section-BC Mechanical Engineering : 4-Year B.Tech. VII-Semester


DC.ME.431.15 ME 431 Turbomachines 2 0 0 6

DE - 3

DE - 3

Department Elective(DE)-3 (Thermal/Design/Manufacturing/Industrial)

3

0

0

9

DP.ME.492/S.15 ME 492/ ME 492S

Stream or UG Project

0

0

10

10


Total (Non-Hons. Students) 11 0 10 43


Department Elective-3 Courses

UG-CRC Code Course

Code Subject

DE.ME 412.15 ME 412 Fracture Mechanics 3 0 0 9

DE.ME 413.15 ME 413 Experimental Mechanics & NDT 3 0 0 9

DE.ME 511.15 ME 511 Optimization for Engineering Design 3 0 0 9

DE.ME 512.15 ME 512 Computer-aided Design 3 0 0 9

DE.ME 513.15 ME513 Theory of elasticity 3 0 0 9

DE.ME 514.15 ME 514 Theory of vibrations 3 0 0 9

DE.ME 515.15 ME 515 Advanced composite materials 3 0 0 9

DE.ME 516.15 ME 516 Mechanics of fracture and fatigue 3 0 0 9

DE.ME.517.15 ME 517 Vehicle Dynamics 3 0 0 9

DE.ME 432.15 ME 432 Automobile Engineering 3 0 0 9

DE.ME 433.15 ME 433 Computational Fluid Dynamics 3 0 0 9

DE.ME 453.15 ME 453 Manufacturing Systems 3 0 0 9

DE.ME 454.15 ME 454 Rapid Design & Manufacturing 3 0 0 9

DE.ME 472.15 ME 472 Industrial Management 3 0 0 9

DE.ME 573.15 ME 573 Supply Chain Management 3 0 0 9

DE.ME 453.15 ME 453 Manufacturing Systems 3 0 0 9

Section-BC Mechanical Engineering : 4-Year B.Tech. VIII-Semester


DE - 4 DE - 4 Department Elective(DE) - 4 3 0 0 9

DE - 5 DE - 5 Department Elective(DE) - 5 3 0 0 9

EP.ME 401.16 ME 401 Mechanical Engineering Lab 0 0 3 3


Total Credits in Semester 12 0 3 39

DP.ME.493S.15 ME 492S Stream Project 0 0 10 10

Total (Hons. Students) 12 0 13 49


Department Elective - 4 Courses

UG-CRC Code Course

Code Subject

DE.ME 411.15 ME 411 Finite Element Method 3 0 0 9

DE.ME 526.15 ME 526 Impact Dynamics and Crashworthiness 3 0 0 9

DE.ME 527.15 ME 527 Theory of Plasticity 3 0 0 9

DE.ME 441.16 ME 441 Internal Combustion Engine 3 0 0 9

DE.ME 442.15 ME 442 Bio Transport Mechanism 3 0 0 9

DE.ME 451.15 ME 451 Unconventional Machining Processes 3 0 0 9

DE.ME 452.15 ME 452 Theory of Abrasive Machining 3 0 0 9

DE.ME 461.15 ME 461 Robotics 3 0 0 9

DE.ME 583.15 ME 583 Simulation for Decision Making 3 0 0 9

DE.ME 582.15 ME 582 Total Quality Management 3 0 0 9

DE.ME 584.15 ME 584 Marketing Management 3 0 0 9

Department Elective - 5 Courses

UG-CRC Code Course

Code Subject

DE.ME 421.15 ME 421 Control Systems Engineering 3 0 0 9

DE.ME 525.15 ME 525 Tribology 3 0 0 9

DE.ME 443.15 ME 443 Power Generation 3 0 0 9

DE.ME 444.15 ME 444 Wind Power Meteorology 3 0 0 9

DE.ME 445.16 ME 445 Applied CFD 3 0 0 9

DE.ME 461.15 ME 461 Robotics 3 0 0 9

DE.ME 581.15 ME 581 Management Information System 3 0 0 9

DE.ME 585.15 ME 585 Design of Production System 3 0 0 9

DE.ME 563.15 ME 563 Green Manufacturing 3 0 0 9

Detailed Syllabi of Courses

MEASUREMENTS AND CONTROLS

1. GENERAL

1.1. TITLE:: Measurements and Controls 1.2. COURSE NUMBER:: DC.ME.221.15

1.3. CREDITS:: 3-0-2 (11 Credits)

1.4. SEMESTER -OFFERED:: II

1.5. PREREQUSITE: None

1.6. Syllabus Committee Member: Dr.A.P.Harsha, Dr. N.Malik

2. OBJECTIVE

This course gives basic overview about the concepts in measurement and controls. The course

would help in knowing with different sensors and transducers and to understand measurement

technique. Course also covers various standards and calibration methods used in the industries. This

course demonstrate the ability to design and conduct experiments, interpret and analyze data, and

report the results.

3. COURSE CONTENT

UNIT I: (4 Lectures)

Mechanical Measurements

Generalized Measuring system, Static performance characteristics, static calibration, linearity,

static sensitivity, accuracy, precision, repeatability, hysteresis, threshold, resolution and

readability. Sources of errors, error analysis, propagation of uncertainties.

UNIT II: (6 Lectures) Dynamic Performance characteristics, Input types, instrument types, zero, first, and

second order instruments

UNIT III: (12 Lectures)

Measurements and methods applications

Measurement of force and Torque – elastic transducers, Measurement of High and low

pressure Measurement of sound, Measurement of Temperature : thermocouples, thermopiles,

thermistors, Flow measuring devices – turbine meter, electromagnetic and ultrasonic flow

meter

UNIT IV: (9 Lectures) Classical Control: Laplace Transformation, Block diagram and its reduction, Time

response, Root Locus Analysis, Routh Stability, , Frequency response, Bode, Polar, Nyquist,

Nichols charts, Nyquist stability, Compensation: Lead, Lag, Lead-Lag, PID controller

UNIT V: (5 Lectures) Modern Control

Modern Control State space method, Signal Flow Graph (SFG)

State Transition Matrix, Stability, Steady state error

UNIT VI: (3 Lectures)

Advanced Control: Digital control, z-transformation, Digital transformation, Stability, Performance plot, Root

Locus, Compensation, PID controller, Robust control, Concept of system sensitivity,

Sensitivity function, Perturbation: additive, multiplicative, Robust stability, Uncertain system

and its stability, Robust PID controller

UNIT VII: (3 Lectures)

Examples: Mechanical, Fluid: Pneumatic and Hydraulic, Thermal, Electrical, Electronics, Aerospace,

Process engineering

4. READINGS

4.1. TEXTBOOK 4.1.1. Measurement systems application and Design by E.O.Doeblin, TaTa McGraw Hill

Publishers,

4.1.2. Instrumentation Measurement and Analysis, by B.C.Nakara, K.K.Choudhry, TaTa

McGraw

4.1.3. Modern Control Engineering by K. Ogata, Pearson Education

4.1.4. Modern Control Systems by R. C. Dorf, Pearson Education

4.1.5. Control System Engineering by I. J. Nagrath, New Age International

4.1.6. Control Systems Engineering by N. S. Nise, John Wiley and Sons

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: Yes

5.3 PROJECT: No

6. ASSESSEMENT :

6.2 HA : 5 %

6.2 QUIZZES- HA : 5 %

6.3 PERIODICAL EXAMINATION : 30 %

6.4 PROJECT/ LAB : 20 %

6.5 FINAL EXAM : 40 %

7. OUTCOME OF THE COURSE Acquire knowledge and hands-on competence in applying the concepts of measurement and

controls in development of mechanical instrument systems. Demonstrate creativeness in designing

new components and processes in the field of engineering. The skill acquired is useful for

mechanical engineering design, analysis and application.

8. EXPECTED ENROLMENT IN THE COURSE: 130

9. DEPARTMENTS OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD BE OF

INTEREST :

10. ANY OTHER REMARKS::

MACHINE DRAWING

GENERAL

10.1. TITLE:: Machine Drawing 10.2. COURSE NUMBER:: EP.ME.222.15

10.3. CREDITS::1-0-3 (06credits)

10.4. SEMESTER -OFFERED:: II


10.6. Syllabus Committee Member: Prof S.K.Sinha, Sri. S. K. Shah

OBJECTIVE: To acquaint the students with the design drafting of machine elements

COURSE CONTENT

Unit I

Sectional view Introduction, cutting plane, type of sectional views-full section, half section, partial or broken

section, sectioning conventions-spokes, web, rib, shaft, pipes, different types of holes, hatching or

section lines, conventions of section lines for different metals and materials.

Unit II

Screwed Fasteners

Drawing hexagonal nut and square nut, hexagonal headed bolt, square headed bolt and washer.

Unit III

Assembly Drawing

Preparation of assembly drawing and the following assemblies from its disassembled views:

Cotter joint- Sleeve & Cotter Joint, Spigot and Cotter joint, Pin Joint or Knuckle joint, Bearing-

Bushed bearing, Plummer block, Coupling-Flange coupling, Flexible coupling

Valves-Steam stop valve, Blow-off cock, Lever safety valve

READINGS

4.1. TEXTBOOK

4.1.1 Machine Drawing, N.D. Bhatt, Charotar Book Stall, Anand

4.1.1.2 A Text Book of Machine Drawing, P.S.Gill, S.K.Kataria, Delhi

5. OTHER SESSION

5.1 TUTORIALS : No

5.2 LABORATORY : Yes 5.3 PROJECT : No

6. ASSESSEMENT :

6.2 HA : 5 %


6.3 PERIODICAL EXAMINATION : No



7. OUTCOME OF THE COURSE

After studying this course, the student shall be able to understand the drawings of mechanical

components and their assemblies along with their utility for design and development of mechanical

system.



INTEREST :

10. ANY OTHER REMARKS: :

MECHANICAL ENGINEERING LAB

GENERAL

1.1. TITLE:: Mechanical Engineering Lab

1.2. COURSE NUMBER::

EP.ME.401.16

1.3. CREDITS::0-0-3 (03 credits)

1.4. SEMESTER -OFFERED:: VIII


1.6. Syllabus Committee Member: Prof S K Sharma, Prof A K Agrawal, Dr. P Bhardwaj, Dr C

Samuel, Prof A P Harsha

OBJECTIVE: To make familiar with advanced application areas of Mechanical Engineering

COURSE CONTENT

List of Experiments

1. Using statistical packages in drawing charts for Quality Control

2 (a): Endurance study using ergomedic cycle.

(b): Endurance study using tread mill

3. Studying the working of a Flexible Manufacturing System

4. Measurement of cutting force by mechanical dynamometer on lathe machine

5. Temperature Measurement using RTD, thermometer and thermocouple

6. Viscosity Measurement using Redwood Viscometer

7. Measurement of strain using bridge circuit

8. Measurement of stress using photo-elasticity technique

9. Study of vibration parameters

10. Low velocity Impact response of standardized specimens

STRENGTH OF MATERIALS

1. GENERAL

1.1. TITLE:: Strength of Materials

1.2. *COURSE NUMBER::IE. ME 112.14

1.3. CREDITS:: 3-1-0(11 Credits)

1.4. *SEMESTER -OFFERED:: III

1.5. Prerequisite: None 1.6. Syllabus Committee Member: Prof. J. P. Dwivedi,Prof. V. P. Singh, Dr. D. Khan, Dr. R. K.

Gautam

2. OBJECTIVE::

Strength of materials is a subjectthat deals with the behavior, load carrying capacity

(strength),rigidity and stability of isolated members such as bars, shafts, beams, arches, slabs, columns

etc. The individual elements may form a part of structures, machines, automobiles, spacecrafts, towers

or antenna dishes. Engineering students are expected to be trained in this subject in a systematic way,

and to learn the rudiments of the theory as a part of the curriculum.

3. COURSE CONTENT

UNIT I: ANALYSIS OF STRESS (9 Lectures)

Three-dimensional stress analysis: Physical Interpretation of stress at a point, State of

stress at a point, Stress equilibrium equation in Cartesian coordinates, Stress transformation,

Principal stresses for a general state of stress, Stress invariants, Hydrostatic and pure shear

states, Octahedral stresses,Plane Stress, Mohr‗s stress circle.

UNIT II: ANALYSIS OF STRAIN (7Lectures)

Deformation and rigid body rotation, Deformation in the neighborhood of a point,

Three dimensional strain system, State of strain at a point, Physical interpretation of strain

terms, Strain transformation, Strain invariants, Principal strains, Plane state of strain, Mohr‗s

strain circle.

UNIT III:STRESS-STRAIN RELATIONSHIP (4Lectures) Generalized Hooke‗s Law, Constitutive equations, Relationship between elastic

constants, Mechanical properties of solids.

UNIT IV: SHEAR FORCE AND BENDING MOMENT (2Lectures)

Shear force and bending moment diagrams in different kinds of beams, Relationship

between load, shear force and bending moment.

UNIT V: BENDING OF BEAMS (6Lectures) Normal and shear stresses, Composite beams, initially curved beams, bending beyond

elastic limit.

UNIT VI: DEFLECTION OF BEAMS (7Lectures)

Double integration method, Area moment method, Macaulay‗s method, Conjugate beam method and method of superposition, Leaf spring.

UNIT VII: TORSION (5Lectures)

Solid and hollow shafts, Torsion beyond elastic limit, Closed coiled helical springs.

UNIT VIII: THEORIES OF FAILURE (2Lectures) Different theories of failure,

Significance of the theories of failure.

UNIT X: THIN-WALLED PRESSURE VESSELS (3Lectures)

Stresses in thin cylinders, Strain and change in volume, Thin spherical shell.

4. READINGS

4.1. TEXTBOOK::

4.1.1. Title: Engineering Mechanics of Solids Author: E. P. Popov

4.1.2. Introduction to Solid Mechanics Author: I. H. Shames and J. M. Pitarresi

4.1.3. Title: Elements of Strength of Materials Author:Timoshenko

4.1.4. Title:Mechanics of Materials Author: Gere and Timoshenko

4.1.5. Title: Mechanics of Materials: Author: Gere

4.2. REFERENCE BOOKS::

4.2.1. An Introduction to the Mechanics of Solids: Crandall and Dahl

4.2.2. Advanced Mechanics of Solids: L. S. Srinath

4.2.3. Mechanics of Deformable Solids: I. H. Shames

5. OTHER SESSION

5.1 TUTORIALS : Yes

5.2 LABORATORY : No

5.3 PROJECT : No

6. ASSESSEMENT :

6.2 HA : 5 %



6.4 PROJECT/ LAB : No


7. OUTCOME OF THE COURSE::

It is expected that after studying this course the students would be in a good position to

handle the design of machine elements. As well they would be fit to study advanced level courses

of this subject like, Advanced Mechanics of Solids, Theory of Elasticity, Theory of Plasticity,

Continuum Mechanics etc.



INTEREST :


THEORY OF MACHINES

1. GENERAL 1.1 TITLE: Theory of Machines

1.2 COURSE NUMBER: DC.ME223.15

1.3 CREDITS: 3-0-2(11 Credits)

1.4 SEMESTER OFFERED: IV

1.5 PREREQUSITE: None

1.6 Syllabus Committee Members: Prof. K.S.Tripathi (Convener), Dr. Amit Tyagi

2. OBJECTIVE: The major objective of this course is to provide the students the necessary tools to synthesize

a system which means scientifically arriving at the critical shapes and dimensions of the bodies

constituting the system. The techniques of kinematic and dynamic analysis must be learned to make an

optimal synthesis. Kinematic and dynamic analysis of various mechanisms is presented in the course.

3. COURSE CONTENT::


Mechanisms and machines, kinematic pairs, elements, chains and inversions,

equivalent linkages.

UNIT II : (5 Lectures) Kinematic analysis of plane mechanisms by graphical and analytical methods, velocity and

acceleration images.

UNIT III : (4 Lectures)

Kinematic synthesis of plane mechanisms, degrees of freedom, Grubler‘s criterion, Grashoff‘s

criterion.

UNIT IV : (4 Lectures) Types of cams and followers, selection of motion, displacement diagrams, cam profile

determination.

UNIT V : (5 Lectures)

Gear terminology, law of gearing, tooth forms, interference and undercutting, gear trains.

UNIT VI : (2 Lectures)

Universal joint kinematics, automobile steering mechanisms.

UNIT VII : (5 Lectures) Force analysis of mechanisms, dynamically equivalent systems, dynamics of reciprocating

engines, turning moment diagrams and flywheels.

UNIT VIII : (3 Lectures)

Types and characteristics of centrifugal governors.

UNIT IX : (5 Lectures)

Balancing of rotating and reciprocating masses.

UNIT X : (3 Lectures)

Gyroscopes and their applications in mechanical systems.

4. READINGS

4.1 TEXT BOOKS 4.1.1. A Ghosh and A K Mallik. Theory of Mechanisms and Machines. East- West Press (P) Ltd.

New Delhi.

4.1.2. J E Shighley and J J Vicker (Jr). Theory of Machines and Mechanisms. Mc Graw Hill

International.

4.1.3. S S Rattan. Theory of Machines. Tata Mc Graw Hill.

4.1.4. J S Rao and R V Dukkipati. Mechanism and Machine Theory. New Age International (P) Ltd

New Delhi.

5. OTHER SESSION

5.1 TUTORIALS : No

5.2 LABORATORY : Yes

5.3 PROJECT : No

6. ASSESSEMENT :

6.1HA : 5 %





7. OUTCOME OF THE COURSE:

During the course many machines and mechanisms will be introduced to the students.

On successful completion of the course the students will be able to analyze various

mechanisms from a point of view of degrees of freedom, transmission of forces and will be

ready to take advanced courses. Students will also be able to resolve the balancing problems of

modern high speed machinery.



INTEREST :


List of experiments in Theory of Machines ( DC.ME.223.15)

1. Study of various types of links, pairs and mechanisms.

2. To study the Quick return mechanism and measure the ratio of time in return stroke to that of in

forward stroke.

3. To study the Hook's Joint and verify the velocity ratio for a Hook's Joint.

4. Generation of gear tooth profile.

5. To verify the velocity ratio of an Epicyclic gear train.

6. To calculate the Coriolis component of acceleration.

7. To obtain the balancing masses and their positions for unbalanced rotating masses.

9. Balancing of forces and couples due to reciprocating masses.

10. To verify the principle of gyroscopic couple.

11. Study on control of mechanical parameters using PID controller.

MECHANICS OF DEFORMABLE SOLIDS

1. GENERAL

1.1 TITLE:: Mechanics of Deformable Solids 1.2 COURSE NUMBER::DC.ME 224.15

1.3 CREDITS:: 3-0-2(11 Credits)

1.4 SEMESTER OFFERED:: IV

1.5 PREREQUISITES:: Strength of Materials

1.6 Syllabus Committee Members: Prof V P Singh (Convener), Prof J P Dwivedi, Dr P Mani,

Dr R K Gautam, Dr D Khan

2. OBJECTIVE:

The contents of this course will help the students to analyze and solve a variety of strength

related design problems encountered in practice. Students will go through the exhaustive

treatment of stress and strain analysis, torsion of multiple cell sections and shaft, applications of

various strain energy theorems, etc. The students are expected to appreciate this subject as a

prerequisite for a good design engineer.

3. COURSE CONTENT

UNIT I: (6 Lectures) Analysis of stress and strain: Three dimensional stress equilibrium equation in polar

coordinate. Three dimensional Mohr‘s stress circle. Stress function. Strain components in polar

coordinate. Compatibility equations and St Venant‘s principle.

UNIT II: (7 Lectures)

Axisymmetric problems: Thick cylinders and rotating discs of uniform and variable

thickness. Beams on elastic foundation.


Stability of Equilibruim: Buckling of columns and strut. Beam column

equation.Energy methods for buckling problems.

UNIT IV: (6 Lectures)

Flexural loading: Unsymmetrical bending. Shear centre and stresses in thin walled

open sections.

UNIT V: (7 Lectures)

Energy methods: Displacement methods, force methods and impact loading.

Castgliano‘s theorems.

UNIT VI: (2 Lectures) Combined loading: Combined centric and flexural loads. Combined centric, torsional

and flexural loads.

UNIT VII: (4 Lectures) Torsion: Torsion of general prismatic and rectangular bars. Torsion of thin-walled

sections. Open-coiled helical spring.

UNIT VIII: (2 Lectures)

Statically indeterminate beam: Integration method, area-moment method,

superposition method and energy method.

UNIT XI: (2 Lectures)

Material medelling: Elasto-plastic, visco-elastic and visco-plastic methods.

4. READINGS

4.1 TEXTBOOKS

4.1.1. Advanced Mechanics of Solids, by LS Srinath 4.1.2. Introduction to Solid Mechanics, by IH Shames & JM Pitarresi

4.1.3. An Introduction to Mechanics of Solids, by Crandall & Dahl

4.1.4. Mechanics of Materials, by Beer, Johnston and DeWolf

4.1.5. Strength of Materials, by GH Ryder

5. OTHER SESSION

5.1 TUTORIALS : No

5.2 LABORATORY : Yes

5.3 PROJECT : No

6. ASSESSEMENT :

6.2 HA : 5 %






This is a second-level course addressed to the students. This course requires a good

understanding of ‗Strength of Materials‘ taught in earlier semester. The students get

acquainted with the new theories and principles which are the mandatory tools for design

engineer. They come across the three pillars of solid mechanics, namely equilibrium,

constitutive laws and compability. Castigliano‘s theorems have been presented which are

used specially in the problems of beam and torsion. Bending of beams on elastic foundation

under different boundary conditions has been explained in a very simplified manner. In

addition to the topics on beam columns, energy methods have been suggested for buckling

problems. Contents of this course have important role in dealing with the other advanced

courses like fracture mechanics, theory of elasticity, theory of plasticity, etc.



INTEREST :


List of Experiments in Mechanics of Deformable Solids (DC.ME 224.15)

1. Performing Tensile Test of Mild steel by Universal Testing Machine (UTM).

2. Performing Uniaxial Test of Cast Iron by Universal Testing Machine (UTM).

3. Determination of materials Hardness by following methods:

a) Vickers

b) Brinell

c) Rockwell

4. Performing Impact Test of different materials by Izod & Charpy Impact Test.

5. To analyze axial, radial and tangential stress distribution of Thin & Thick Cylinder at different

pressure.

6. To determine Young‘s Modulus of different materials by bending method.

7. To determine modulus of rigidity ‗G‘ for the Helical Spring materials.

8. Determination of proof load and curve plotting between load and deflection of a Leaf Spring.

9. Performing Torsion Test for the Cast Iron test specimen.

10. Performing Compression and Tensile test of different material using Universal Testing

Machine (UTM).

11. To perform Creep test of different materials.

12. Determination of deformation for Straight Beams.

13. Determination of deformation for Bars under Bending or Torsion.

14. Performing Fatigue Test for cyclic loading of given material.

15. To determine deformation of Curved-Axis Beams for the given material.

16. To perform Unsymmetrical bending of given material.

17. Determination the Buckling Behaviors of Bars.

ME-231: FLUID MECHANICS & FLUID MACHINERY

1. GENERAL

1. 1TITLE: Fluid Mechanics and Fluid Machinery

1.2 *COURSE NUMBER: DC.ME 231.15


1.4 *SEMESTER -OFFERED: ODD

2. DC-2

1.5 PRE-REQUISITES: Thermodynamics

2. OBJECTIVE:: To provide basic knowledge of fluid mechanics

3. COURSE TOPICS::

Unit 1(13Lectures)

Introduction: Properties and types of fluids, Fundamentals of fluid statics and kinematics,

Velocity potential and stream function (5 lectures)

Fluid Statics and Kinematics: Submerged surfaces, Buoyancy and stability, Uniform Transnational

Acceleration and Uniform Rotation of bodies with fluids. (8 lectures)

Unit 2(11Lectures)

Potential flow: Source, Sink, Doublet, Superposition (3

lectures)

Fluid Dynamics: Equations of Motion and Energy and their applications. Flow through pipes,

Viscous Flow (Poiseuille and Couette Flows), Flow measurements (8 lectures)

Unit 3(15Lectures) Dimensional Analysis: Rayleigh and Buckingham Pi- Theorem. Geometric, Kinematic and

Dynamic similarities. Model Testing. (5 lectures)

Introduction to Boundary Layer: Boundary layer thicknesses, Characteristics of Boundary Layer,

Boundary Layer Equations, Momentum Integral Equation and its solution. (6 lectures)

Introduction to Fluid Machinery : Classification, Euler equation, velocity triangles, components

of turbomachines (4 lectures)

4. Reading:

1. Fox & MacDonald, Fluid Mechanics

2. Som and Biswas, Fluid Mechanics and Machines

3. F M White, Fluid Mechanics

5. Other Sessions:-

Lecture[3]; Practical [2]

6.Assessment:- Homework[5%],

Assignment [5%],

Periodical Exams[30%],

Final [60%]


8. *EXPECTED ENROLLMENT FOR THE COURSE:: Knowledgeable in Fluid Mechanics

9. *DEPARTMENTS OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD BE OF

INTEREST::

Chemical and Civil Engineering may be interested to opt for it.

10. *ANY OTHER REMARKS::

List of experiments for ME-231

1. Determination of liquid viscosity

2. Demonstration of various methods of flow measurement

3. Variation of Lift and drag coefficient with angle of attack for a symmetric airfoil.

4. Performance characteristic of constant speed centrifugal pump

5. Performance characteristic of variable speed forward/backward curved computerized

centrifugal pump

6. Performance characteristic of impulse turbine (Pelton wheel)

7. Demonstration of Bernoulli‘s Theorem

8. Determination of friction factor in case of laminar and turbulent flow.

ME-241- HEAT AND MASS TRANSFER

1. GENERAl

1. 1TITLE: Heat and Mass Transfer

1.2 *COURSE NUMBER: DC.ME 241.15


1.4 *SEMESTER -OFFERED::EVEN

1.5 PRE-REQUISITE:: Fluid Mechanics & Fluid Machinary, Engineering Thermodynamics

2. Objective: To provide basic knowledge about heat and mass transfer processes and mechanism

3. Course Topics:

Unit 1 (10 lectures)

Conduction: Thermal conduction in solids, Fourier‘s law, three and two dimensional

equations, conduction through planes, composite walls, cylinders and spheres, fins. Two dimensional

steady state heat conduction, Transient two/three dimensional heat conduction and lumped parameter

analysis, transient heat conduction through semi-infinite slab without resistance.

Unit 2(13 lectures)

Convection: Forced convection through boundary layer on flat plate, Momentum and energy

equations, hydrodynamic and thermal boundary layers, Temperature distribution solution,

Dimensionless numbers. Introduction to similarity and integral solution for heat transfer problems

Natural convention mechanism, determination of heat transfer coefficient from a vertical flat plate,

free convection for other geometries, mixed convection.

Unit 3 (6 lectures)

Radiation: Physical mechanism of energy transport in thermal radiation, laws of radiation,

black body radiation, radiation characteristics of non black surfaces Kirchoff‘s law, view factor, view

factor algebra, radiation exchange, electric circuit analogy, radiation shields, the radiation heat transfer

coefficient, gas radiation, green house effect.


Heat Exchangers: Introduction, classification of heat exchangers, the overall heat transfer

coefficient, fouling factor, typical temperature distribution, fouling, Log mean temperature difference

and NTU method and appropriate treatment design considerations for heat exchangers.

Boiling and Condensation: Regimes of boiling, bubble size consideration, bubble growth and

collapse, critical bubble, Rohsenow‘s correlation. Nusselt theory of condensation, effect of operational

parameters, concept of heat pipe.

Mass Transfer: Introduction to mass transfer, Fick‘s law

4. Readings:

1. Theodore L. Bergman, Adrienne S. Lavine, Frank P. Incropera, David P. DeWitt. April 2011,

©2011. Fundamentals of Heat and Mass Transfer, 7th Edition. Wiley publication

2. Heat Transfer, S.P.Sukhatme

3. Heat Transfer,F.Kreith

4. Heat Transfer, J.P Holman

5. Other Sessions:-Lecture[3]; Practical [2]

6.Assessment:- Homework[5%], Assignment [5%], Periodical Exams[30%], Final [60%]

7. OUTCOME OF THE COURSE:: Knowledgeable in Heat & Mass Transfer

8. *EXPECTED ENROLLMENT FOR THE COURSE::


INTEREST::

Chemical Engineering may be interested to opt for it.


List of experiments for ME-241

1. Determination of force convection heat transfer coefficient

2. Determination of free convection heat transfer coefficient

3. Pool boiling experiment

4. Determination of Stefan Boltzman constant

5. Performance characteristics of finned tube heat exchanger

6. Performance characteristics of shell & tube heat exchanger

7. Horizontal and vertical tube condenser

8. Vapour compression test rig using refrigerant mixture

9. Air-conditioning test rig

10. Study of cross-sectional models of various refrigerant compressor

11. Performance testing of vortex tube refrigeration system

MANUFACTURING TECHNOLOGY

1. GENERAL

1.1 TITLE : : Manufacturing Technology

1.2 COURSE NUMBER DC.ME 251.15

1.3 CREDITS : : 3-0-0 (9 Credits)

1.4 SEMESTER- OFFERED : : Odd Semester

2. OBJECTIVE : :

The objective of the course is to impart the basic understanding of fundamental aspects

of the manufacturing processes like casting, joining (welding, brazing, soldering), metal

forming (bulk deformation processes e.g., rolling, forging, extrusion, wire and rod drawing,

tube drawing, deep drawing), sheet metal forming and powder metallurgy. through which a

raw material can be converted into a usable product.

3. COURSE CONTENT :

Unit 1 (2 Lectures)

Introduction to Manufacturing

Unit 2 (12 Lectures)

Foundry: Fundamentals of Metal casting,Types of casting, Special casting methods,

Casting design considerations, casting defects, Moulding machines, Cleaning and conditioning

of casting, Melting furnaces, Foundry mechanization.


Welding Processes: Advanced welding processes and applications, Welding defects,

inspections and testing, Design considerations.

Unit 4 (4 Lectures)

Powder Metal Forming: Powder production and properties, Compaction and sintering,

Applications.

Unit 5 (9 Lectures)

Bulk Deformation Processes: Fundamentals of metal forming, Rolling, Forging,

Extrusion, Drawing and applications.

4. READINGS : :

4.1 TEXT BOOKS : :

1. Title:DeGarmos Materials and Processes in Manufacturing‖ Author: J T Black and Ronald

R. Koheser

2. Title:Manufacturing Engineering and Processes for Engineering Materials Author:

SeropeKalpakjian and Steven R Schmidt

4.2 REFERENCE BOOKS : :

1. Title: Manufacturing Engineering and Technology Author: SeropeKalpakjian and

Steven R Schmidt

2. Title: Fundamentals of Modern Manufacturing: Materials, Processes, and Systems

Author :M. P. Groover.

3.Ttile: Manufacturing Technology Vol. 1: Foundry, Forming and Welding Vol. 1

Authour: P N Rao

4. Title: Manufacturing Science Author: Amitabh Ghosh and A K mallick

5. OTHER SESSION

5.1 TUTORIALS :

5.2 LABORATORY :

5.3 PROJECT : :

6. ASSESSEMENT : :

6.1 HA : : 10

6.2 QUIZZES- HA : : 10

6.3 PERIODICAL EXAMINATION : : 30

6.4 PROJECT/ LAB : :

6.5 FINAL EXAM : : 50

7. OUTCOME OF THE COURSE : :

After the completion of course students are expected to be able to take up challenging

jobs in relation to exploring technically and economically viable solutions to a wide variety of

problems in product design and manufacturing.

8. EXPECTED ENROLMENT IN THE COURSE : : 125


INTEREST :

10. ANY OTHER REMARKS : :

list of experiments Manufacturing Technology (DC.ME 251.15)

S.No Experiment

1. Study of construction and working of Melting Furnace and metal pouring

2. CO2 molding Process

3.

Sand Testing

(a)Permeability Test

(b)Strength Test

(c)Hardness Test

4.

Practice of

(a)Resistance Welding

(b)MIG Welding

(c)TIG Welding

5. Study of Microstructure of Cast and welded parts

6. a) Preparation of powdered metal products.

b) HIP/CIP

7. Wire drawing

8. Rolling

9. Hot Forging

10. Extrusion

METAL MACHINING AND MACHINE TOOLS

1. GENERAL

1.1 TITLE : Metal Machining and Machine Tools

1.2 COURSE NUMBER : DC.ME 261.15


1.4 SEMESTER- OFFERED : EVEN

2. OBJECTIVE : :

To make the students learn about different machining processes and their applications.

Also to inculcate the principles and working methods of various machine tools.

3. COURSE CONTENT :


Machine Tools: Classification, Types and Working Operation of Lathe, Shaper,

Planer, Slotter, Milling, Drilling, Grinding, Gear Hobbing, etc.

Unit 2 (10 lectures) Metal Machining: Introduction to Single-Point and Multi-Point Cutting Tools, Tool

Materials, Tool Geometry, Mechanism of Chip Formation


Mechanics of Orthogonal Cutting, Thermal Aspects, Cutting Fluids, Tool Wear, Tool

Life and Machinability, Economics of Machining.

Unit 4 (5 lectures) Introduction to Unconventional Manufacturing Processes:

EDM, ECM, AJM, USM, LBM etc.

4. READINGS : :

4.1 TEXT BOOKS : :

1. Machining and Machine Tools by A.B. Chattopadhyay, Wiley India Pvt. Ltd.

2. Metal Cutting Principles by M.C.Shaw, CBS Publishers and Distributors

3. Advanced Machining Processes by V.K.Jain, Allied Publishers Pvt. Ltd.


1. Fundamentals of Metal Machining and Machine Tools by Geoffrey Boothroyd, McGraw-

Hill

5. OTHER SESSION

5.1 TUTORIALS :

5.2 LABORATORY :

5.3 PROJECT :

6. ASSESSEMENT :

6.1 HA :

6.2 QUIZZES- HA :

6.3 PERIODICAL EXAMINATION : 30

6.4 PROJECT/ LAB : 20

6.5 FINAL EXAM : 50


It is anticipated that after completion of the course, a student would be in a position to decide

about the machining process required for a specific component manufacturing. Also, student

can learn about different aspects of machine tools.

8. EXPECTED ENROLMENT IN THE COURSE : 130


INTEREST :


list of experiments Metal Machining & Machine Tools (DC.ME 261.15)

S.No Experiment

1. Fabrication of a Spur Gear on Shaper and Gear Hobbing Machine.

2. a. Fabrication of a typical job on Lathe.

b. Study of different type of chips by their production.

3.

a. Fabrication of a typical job involving milling, drilling and grinding operations

b. To study the effect of grinding process parameters on grinding forces and specific grinding

energy.

4. Study the construction and working of an EDM machine by producing a small component on

it.

5. Working of AJM machine/LBM/AWJM(Any One)

6.

a. To study the effect of coated and uncoated turning tool on machinability.

b. To study the effect of cutting velocity, feed rate and depth of cut on cutting forces upon

turning operation.

c. To study the effect of machining process parameters on machining zone temperature.

7.

1. To study the effect of cutting parameters on surface finish, cutting forces, type of

chip formation & chip thickness ratio for a given tool geometry and work piece -tool material

combination.

2. To study the type of tool wear under a given set of cutting condition.

8. Micro & Nano Machining

FUNDAMENTALS OF MACHINE DESIGN

1. GENERAL

1.1. TITLE::Fundamentals of Machine Design

1.2. COURSE NUMBER:: DC.ME.311.15


1.4. SEMESTER -OFFERED:: V(ODD)

1.5. PREREQUSITE: Strength of Materials

1.6. Syllabus Committee Member: Dr A.P.Harsha

2. OBJECTIVE This course deals fundamentals of machine design, including analysis and design of

mechanical components. It covers various design aspects of machine elements under static and

fatigue loadings.

3. COURSE CONTENT

UNIT I: (6 Lectures) Introduction to Design of Mechanical system, Design process, and Design cycle. Safety

in mechanical design, use of standards and code in design- Indian and International standards,

Manufacturing considerations in Design

UNIT II: (4Lectures)

Types of loading- static, cyclic and impact, theories of failure


Design of fasteners - welded, riveted, and threaded fasteners


Design of power screws, Design of keys and splines


Friction drives, Design of couplings, brakes, and clutches


Design of cotter and knuckle joints


Flexible machine elements, Design of belt and rope drives

4. READINGS

4.1. TEXTBOOK 4.2. Fundamentals of Machine Elements by Hamrock, Schmid and Jacobson, Mc-Graw Hill

International Edition

4.3. Design of Machine Elements by M.F.Spots and others, Pearson Education, New Delhi

4.4. Design of Machine Elements by V B Bhandari, The TaTa McGraw-Hill Publishing Company

Ltd., New Delhi

4.5. Mechanical Engineering Design by J Shigley and others, The TaTa McGraw-Hill Publishing

Company Ltd., New Delhi

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: Yes

5.3 PROJECT: No

6. ASSESSEMENT :

6.3 HA : 5 %



6.4 PROJECT/ LAB: 20 %

6.5 FINAL EXAM: 40 %

OUTCOME OF THE COURSE

Upon successful completion of this course, the student will have satisfactorily accomplished

the goals and objectives listed in this course content.



INTEREST :


PRACTICAL CLASS

During the lab sessions, the student may work at his /her desk or on the board in small groups,

solving problems assigned by the course convener. They will also design and draw the various simple

components.

VIBRATIONS

1. GENERAL 1.1 TITLE: Vibrations

1.2 COURSE NUMBER: BE.ME312.15

1.3 CREDITS: 3-0-0( 9 Credits)

1.4 SEMESTER OFFERED: V(ODD)


1.6 SYLLABUS COMMITTEE MEMBERS: Prof. K.S.Tripathi (Convener), Prof. V.P.Singh, Dr.

Amit Tyagi

2. OBJECTIVE: The objective of this course is to familiarize the students with the fundamental concepts of

vibration so that on one hand they have mastery of applying them to the practical engineering

problems and on the other hand prepared to take on advanced courses in the area.

3. COURSE CONTENT


Free and forced vibration of single degree freedom systems, transient vibrations

UNIT II : (6 Lectures)

Two degree freedom systems, vibration absorbers and dampers.

UNIT III : (7 Lectures) Multi degree freedom systems, influence coefficient and matrix methods, multimass torsional

systems, Holzers method, modal analysis

UNIT IV : (6 Lectures)

Transverse vibration of beams and rods, energy methods.

UNIT V : (4 Lectures)

Whirling of shafts, stresses in shafts due to vibration.

UNIT VI : (4 Lectures)

Introduction to self induced vibration in mechanical systems.

UNIT VII : (6 Lectures)

Condition monitoring of machinery through vibration and noise measurement.

4. READINGS

4.1 TEXT BOOKS 4.1.1 Title: Theory of Vibration with Applications.

Author: W.T.Thomson.

4.1.2.Title: Introductory course on Theory and Practice of Mechanical Vibrations.

Author: J. S. Rao & K. Gupta (Wiley Eastern Ltd. )

4.1.3. Title: Mechanical Vibrations. Theory and Applications.

Author: Francis S. Tse, Ivan E. Morse& Rolland T. Hinkle (CBS Publishers ).

5. OTHER SESSION

5.1 TUTORIALS: No

5.3 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT:

6.1 HA : 5 %



6.4 PROJECT/ LAB: None

6.5 FINAL EXAMS: 60 %

7. OUTCOME OF THE COURSE: It is expected that after studying this course the students would feel much comfortable to

handle advanced courses like Advanced Vibrations, Nonlinear Vibrations, Vibration and Shock

Isolation, Rotor Dynamics etc.



INTEREST :


MATERIALS FOR TRIBOLOGICAL APPLICATIONS

1. GENERAL

1.1. TITLE:: Materials for tribological applications

1.2. COURSE NUMBER:: BE.ME.313.15

1.3. CREDITS::3-0-0 (11 Credits)

1.4. SEMESTER -OFFERED:: V(ODD)



2. OBJECTIVE Design of surfaces in contact is a critical problem for mechanical engineering. A material

for Tribological applications is an interdisciplinary course which deals with fundamentals of

surface contact, friction, wear and lubrication. Topics include engineering surfaces, popular

surface contact theories, and major modes of friction, wear, lubrication and adhesion. Special

materials for tribological applications will be discussed.

3. COURSE CONTENT


Introduction to friction: types, laws

UNIT II: (5 Lectures) Classification of wear ; theories of adhesive, abrasive, surface fatigue, fretting wear,

erosive wear, cavitation wear and corrosive wear

UNIT III: (3Lectures)

Wear of machine components such as gears, plain bearings and rolling element

bearings

UNIT IV: (6 Lectures) Tribologically relevant properties of materials: friction materials and their application

in clutch and brake linings. Anti-friction / plain bearing materials.


Wear resistant materials, surface treatments and coatings for wear resistant applications


Materials for specific applications such as cutting tools, gears, seals, rolling elements

bearings and piston ring /cylinder liners etc

UNIT VII: (5 Lectures) Introduction to lubricants, types of requirement, mineral oils. Lubricant additives and

their role. Greases, solid lubricants, evaluation and testing of lubricants, standards on

lubricants and greases.


Selection of lubricants, lubricating oil discarding criteria. Environment problems

relating to lubricants. Tribotesting techniques of different material pairs

4. READINGS 4.1. TEXTBOOK

4.1.1. Materials for Tribology by W.A. Glaeser, Columbus, OH, USA, Elsevier publication.

4.1.2. Tribology, Principles and Design Applications, by Arnell et al.

4.1.3. Principles and Applications of Tribology, by B. Bhushan

4.1.4. Fluid Film Lubrication, By B. Hamrock

4.1.5. Tribology, by I.M. Hutchings

4.1.6. Engineering Tribology, by G. Stachowiak and A.W. Batchelor

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT:

6.1 HA: 5 %

6.2 QUIZZES- HA: 5 %

6.3 PERIODICAL EXAMINATION: 30 %




By the end of the course student should: Have knowledge of surface topography and know

how to model a rough engineering surface.Have a clear overall picture about the basics of

tribology and related sciences, theoretical background about processes in tribological system,

mechanisms and forms of interaction of friction surfaces.Understand Hertz contact and rough

surface contact.Be familiar with adhesion theories and the effect of adhesion on friction and

wear.Have a mastery of the friction/lubrication mechanisms and know how to apply them to the

practical engineering problem.Know the methods to reduce the friction for engineering surface.

Tribologically relevant properties required for various mechanical application.



INTEREST :

10. ANY OTHER REMARKS:

DESIGN OF MACHINE ELEMENTS

10.1. TITLE:: Design of Machine Elements

10.2. COURSE NUMBER:: DC.ME 321.15


10.4. SEMESTER -OFFERED:: VI


10.6. Syllabus Committee Member: Dr. Rajesh Kumar, Dr. Nilanjan Mallik, Dr. R. K. Gautam,

Mr. P.C. Mani

2. OBJECTIVE This course mainly considers the design of power transmission elements: gear, shaft and

bearing. The objective of the course is to discuss the critical design parameters so that a smooth

and reliable power transmission occurs even under severe operating conditions. To achieve it the

surface failure theories, lubrication, and fatigue failure theories are also discussed.

3. COURSE CONTENT

UNIT I (8 lecture)

Gears-General Introduction to gear drives. Mathematical modeling of gear tooth profiles.

Fundamental laws of involute curves, contact ratio, interference, gear tooth failures and its

remedies.

UNIT II (10lecture)

Design of Spur, Helical, Bevel and Worm gears

UNIT III (8 lecture)

Fatigue failure theories, design of shaft and axle

UNIT V (6 lecture)

Rolling contact bearings Bearing types, Standard dimensions of the bearing, Stribeck equation, reliability and life, Selection

of bearing for variable loading.

UNIT IV (8 lecture)

Sliding contact bearings Different regimes of lubrication, generalized Reynolds equation and its solution, bearing

characteristics number, design of hydrodynamic and hydrostatic bearings.

4. READINGS

4.1. TEXTBOOK

4.1.1. Design of Machine Elements by Spots M F and Shoup T E, Pearson Education

4.1.2. Machine Design An Integrated Approach by Norton Robert L, 2nd

Edition, Pearson

Education

4.1.3. Design of Machine Elements by Bhandari V B, The Tata McGraw-Hill 4.1.4. Mechanical Engineering Design by Shigley J and others, The Tata McGraw-Hill

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: Yes

5.3 PROJECT: No

6. ASSESSEMENT:

6.1 HA : 5 %






Knowledge of an integrated approach in designing the power transmission elements



INTEREST :


Practical Classes:

Students will solve developed assignment problems using drawing tools, and computer programming

so that it improves understanding about gear, shaft and bearing design.

COMPUTATIONAL MECHANICS

1. GENERAL

1.1 TITLE:: Computational Mechanics

1.2 COURSE NUMBER:: EP.ME.322.15


1.4 SEMESTER -OFFERED:: VI


1.6 Syllabus Committee Member: Dr. S. K. Panda, Dr. P. Ghosh, Dr. D. Khan

2. OBJECTIVE

The course intend to develop computational skills for numerical simulation of model problems

in the field of solid mechanics, fluid mechanics and biomechanics

3. COURSE CONTENT

(i). Stress and Deformation analysis of Solid model using FE softwares

(ii). Problem of fluid structure interaction

(iii) Solving model Poission‘s Equation for fluid flow problem using Fluent

(iv) Crash behavior of model car

(v) Analysis of 3-D model of human body parts using Mimics and Any Body

4. READINGS 4.1 Software Tutorial

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: Yes

5.3 PROJECT: No

6.ASSESSEMENT:

6.1 HA : 5 %


6.3 PERIODICAL EXAMINATION:




The student who has undergone this course is expected to appropriately model his/her research

problem using various computational software tools.



INTEREST :


Practical Classes:

Students will solve developed assignment problems using drawing tools, and computer programming

so that it improves understanding about gear, shaft and bearing design.

1. GENERAL

1.1. TITLE:: Composite Materials

COMPOSITE MATERIALS

1.2. COURSE NUMBER:: BE.ME 323.15




1.6. Syllabus Committee Member: Dr V.K.Srivastava, Dr S.K.Panda

2. OBJECTIVE

The main objective of this course is to introduce the light weight structural materials for the

application in automobile, transportation, aerospace and domestic. Monolithic metals and their

alloys cannot always meet the demands of today‘s advanced technologies. Only by combining

several materials can one meet the performance requirements.

3. COURSE CONTENT

Unit-1: ( 5 Lectures) Introduction: Manufacturing of composites. Definition of Composites, Types of Composites and

their applications, Smart Composites, Usefulness of Composites.

Unit-2: (15 Lectures)

Micromechanical Analysis: Strength of Materials approach, Method of Cells, Energy approach,

Voigt upper bound and Reuss lower bound, Concentric cylinder approach, variational approach:

Hshin-Shtrkman, Eshelby Tensors, Green‘s functions


Macromechanical Analysis: Analysis of laminated composite structures, ABD matrix, Analytical

solutions: Navier and Levy solutions, Finite element analysis of laminated composite structures:

Layerwise theories.


Thermal, Hygroscopic and Piezoelectric effects

4. READINGS

4.1. TEXTBOOK

4.1.1. Mechanics of Composite Materials by R. M. Jones

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT:

6.1 HA : 5 %






Composite material course will offer the complete knowledge about mechanical behaviour of two

phase materials, like fiber composite, particulate composite and nano-composite.



INTEREST :


BIOMATERIALS

1. GENERAL

1.1. TITLE:: Biomaterials






2. OBJECTIVE Introduce the field of biomaterials in medicine and their use in specific implant designs

focusing on: material and implant requirements, structure-property relationships for synthetic

and biological materials, and static and dynamics properties of biomaterials.

The primary objectives of the course are:Understand biology and physiology, and apply math,

science and engineering to solve the problems at the interface of engineering and biology;

Knowledge of contemporary issues; Evaluate design considerations, experimental techniques

and data interpretation; Understand professional and ethical responsibility; Use techniques,

skills and tools necessary for engineering practice.

3. COURSE CONTENT


Introducing length scales relevant for materials science and engineering


Properties of Biomaterials: Physics and General Concepts


Classes of Materials Used in Medicine


Biomaterials Degradation in the Biological Environment


Physical and Mechanical Properties of Biomaterials


Biocompatibility


Selected Applications of Biomaterials


Special Considerations for Implants, Devices and Biomaterials

4. READINGS

4.1. TEXTBOOK

4.1.1. Biomaterials Science: An introduction to materials in Medicine. Buddy D. Ratner et al.

2012, 3rd

edition (textbook is not required for this class).

5. OTHER SESSION

5.4 TUTORIALS: No

5.5 LABORATORY: No

5.6 PROJECT: No

6. ASSESSEMENT:

6.1 HA : 5 %




6.5 FINAL EXAMS: 60

7. OUTCOME OF THE COURSE Introduction to the field of biomaterials used in the design of medical devices, and to augment or

replace soft and hard tissues. Discussion of bulk properties, applications, and in vivo behaviour of

different classes of natural and synthetic biomaterials. Analysis of biological response and

biocompatibility, degradation and failure processes of implantable biomaterials/devices.



INTEREST :


SMART MATERIALS AND STRUCTURES

1. GENERAL

1.1. TITLE:: Smart materials and structures



1.4. SEMESTER -OFFERED:: VI and OE (Sem V)


1.6. Syllabus Committee Member: Dr. NilanjanMallik

2. OBJECTIVE Structures in the traditional context once simply meant a selection of the dimensions of the load

bearing components of a structure. Essentially conventional design and materials science were

integrated to obtain a structural design. Advanced research on materials science resulted in versatile

materials having sensing, actuating capabilities. Fiber optic materials, shape memory alloys,

piezoelectric materials, electrorheological fluid, magnetorheological fluid, nanomaterials etc. Such

materials opened the scope for designing a structure self-sensing, self-actuating, self-controlling, self-

powering and self-repairing. MEMS structures miniaturize the smart technologies involved in such

structures. With this background the main objectives of the course are to acquaint the students about

smart materials, their characterization and applications in developing/designing smart structures.

3. COURSE CONTENT

UNIT I: (4 Lectures) Introduction to smart structure, historical development, characteristics, examples; active

vibration damping system, active noise reduction system in automobile, aircraft, other vehicles

etc.


Smart materials, their characteristics and applications; electroresponsive materials,

thermoresponsive materials, optoresponsive materials, magnetoresponsive materials

UNIT III: (6 Lectures) Optical fiber sensor technology; Interferrometers, Structural Health Monitoring using optical

fiber sensors


Smart structures using piezoelectric materials; vibration damping, energy harvesting,

structural health monitoring

UNIT V: (6 Lectures) Smart structures using SMA materials; vibration damping, flapping mechanism, biomedical

applications


Smart structures using ER/MR fluids; vibration damping, smart bearing


Nanomaterials, characteristics and their applications as smart systems

4. READINGS

4.1. TEXT BOOKS : :

4.1.1. Title: Smart Structures Analysis and Design, Author: A. V. Srinivasan, D. M.

McFarland

4.2. REFERENCE BOOKS : :

4.2.1. Title: Smart Materials in Structural Health Monitoring, Control and Bio-Mechanics

,Editors: C. K. Soh, Y. Yang, S. Bhalla

4.2.2. Title: Smart Materials and Structures, Editors: P. L. Reece

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT:

6.1 HA : 5 %




6.5 FINAL EXAMS: 60


Students will be able to learn several smart materials, their characteristics and systems.

They will also be able to design smart systems for various applications. The course will

also help the students to do research on the field.



INTEREST :


Mechatronics

1. GENERAL

1.1. TITLE:: Mechatronics

1.2. *COURSE NUMBER:: OE.ME 314.15 1.3. CREDITS::3-1-0 - Credits - 11

1.4. *SEMESTER -OFFERED:: Even/Odd

1.5. PREREQUSITE: any subject on basic electronics, any subject on control, any subject on mathematical

modeling, any subject on computer programming

1.6. Syllabus Committee Member: Dr. Nilanjan Mallik

2. OBJECTIVE

In the increasingly competitive environment, mechatronics has become the key to industrial

prosperity. The rapid advancements in the fields of electronics engineering, information

technology and systems engineering have been responsible for evolving new concepts aimed at

developing highly sophisticated machine tools for enhanced productivity. Mechatronics is the

combination of electronics and computer technology to practical control applications in

mechanical systems. Mechatronics is an exhaustive coverage of various aspects from design to

testing high technology machines and systems. The objective of the course is to impart

knowledge to the learners on mechanical systems, electrical systems, electronics systems,

computer technologies, testing techniques and fault disgnosis techniques which are essential

components of a mechatronic systems.

3. COURSE CONTENT

UNIT I: (3 Lectures) Introduction to mechatronics, components, multidisciplinary nature, examples: camera, engine fuel

control system


Basics of Electronics; semiconductor technology, transformer, transistor, integrated circuits (ICs),

microcontrollers, circuits and programming

UNIT III: (6 Lectures) Basic Mechanical systems; structural components, measurements, hydraulic and pneumatic systems,

modeling techniques, controls


Electrical components; actuators, drives, dc motors, servo motors,


Case study - CNC machine; components, functioning, programming


Artificial intelligence for mechatronics systems, neural networks, fuzzy logic, genetic

algorithms

4. READINGS

4.1. TEXTBOOK

4.1.1. Title: Mechatronics, Author: H. M. T. Ltd.

4.1.2. Title: Mechatronics principles and applications, Author: G. Onwubolu

4.2. Reference books : :

4.2.1. Title: Mechatronics, Authors: C. W. de Silva

4.2.2. Title: Mechatronics for beginners: 21 projects for PIC microcontrollers, Editors: A. Imam

10. OTHER SESSION

5.4 TUTORIALS: YES

5.5 LABORATORY: No

5.6 PROJECT: No

11. ASSESSEMENT:

6.1 HA : 5 %




6.5 FINAL EXAMS: 60

12. OUTCOME OF THE COURSE Students will be able to design any systems with mechatronics perspective. They will be able to design

the circuit for the system also they will be able to program it to run the system. Also they will be able

to apply artificial intelligence algorithms to control the system.



INTEREST:

Electrical Engineering, Electronics Engineering, Civil Engineering, Mining Engineering, Bio-

medical Engineering


COMBUSTION TECHNOLOGY

1. GENERAL

1.1TITLE: Combustion technology

1.2 *COURSE NUMBER:: BE.ME 331.15


1.4 *SEMESTER -OFFERED:: ODD

1.5 PRE-REQUISITES:: Engg Thermodynamics (ME-103)

2. Objective:: To provide detailed knowledge about combustion mechanism

3. Course Topics::

UNIT-I : Thermo dynamics of reacting mixtures& chemical kinetics (12 Lectures)

Heat of formation, heat of reaction, adiabatic flame temperatures, entropy changes for reaction

mixtures, chemical equilibrium, equilibrium criteria, evaluation of equilibrium constants and

equilibrium compositions.

Law of mass action, order and molecularity of reaction, rate equation, activation energy,collision

theory of reaction rates, general theory of chain reactions.

UNIT-II : Ignition and flammability&flame propagation (14 Lectures)

Methods of ignition, theory of ignition, energy required for ignitions, limits of flammability, factors

affecting flammability limits, flame quenching, effects of variables in flame quenching. Factors

affecting flame speed, premixed and diffusion flames, physical structure and comparisons,

characteristics of laminar and turbulent flames, theory of laminar flame propagation, empirical

equations for laminar and turbulent flame velocities, flame length, flame length scales in turbulent

flow, lift off and blowout, flame regimes in turbulent premixed flames.

UNIT-III : Combustion applications (7 Lectures)

Gaseous burner flames, Droplet combustion, gas burners, stoves, burning of solids, one and two film

model of carbon burning, Combustion system in gas turbines and industrial furnaces.

UNIT-IV : Combustion pollutions and controls (6 Lectures)

Formation of Pollutants, measurement of exhaust emissions. NDIR, FID, CLA, measurement of

exhaust smoke, gas chromatography, pollution control devices.

4.Readings::

1.Introduction to Combustion, S.R.Turns

2.Fundamental in Combustion , R A Strehlow

3.Combustion , Jerzy Chomiak

4.Principles of combustion , Kenneth K Kuo

5. Internal Combustion Engine , H.N.Gupta

5. Other Sessions::

Lecture[3]; Tutorial [0]


7. OUTCOME OF THE COURSE:: Knowledgeable in Combustion



INTEREST::

Chemical Engineering may be interested to opt for it.

10. Any Other Remarks-

ME-332: THERMAL MANAGEMENT OF ELECTRONIC SYSTEMS

1. GENERAL

1. 1TITLE: Thermal Management of Electronic Systems




1.5 ME-231: Fluid Mechanics & Fluid Machinery, ME-241: Heat and Mass Transfer

2. OBJECTIVE: To provide elementary knowledge about the applications of thermal science for

electronics

3. COURSE TOPICS:

Unit 1 (5 lectures)

Revisiting the fundamentals of Heat Transfer.

Unit 2(5 lectures)

Thermal issues associated with electronic products life cycle.

Unit 3(12 lectures) Topics include: Passive, active, and hybrid thermal management techniques for electronic devices and

systems.

Unit 4(7 lectures)

Computational modeling approaches for various levels of system hierarchy.

Unit 5(10 lectures) Advanced thermal management concepts, including single phase and phase change liquid immersion,

heat pipes, and thermoelectrics.

4. Reading:

a) Heat Transfer (Thermal Management of Electronics) by Shabany

b) Cooling Techniques for Electronic equipment by D S Steinberg

c) Design and Analysis of Heat Sinks by A D Kraus

5. Other Sessions:- Lecture[3]; Tutorial [0]; Practical[0]

6. Assessment:- Homework[5%], Assignment [5%], Periodical Exams[30%], Final [60%]

7. OUTCOME OF THE COURSE:: become knowledgeable in electronics cooling



INTEREST::

Electrical and Electronics Engineering

10. Any Other Remarks

ME 341: ENERGY CONVERSION SYSTEMS

1. GENERAL

1. 1TITLE: Energy Conversion Systems

1.2 *COURSE NUMBER:: DC.ME 341.15


1.4 *SEMESTER -OFFERED:: EVEN

1.5 PRE- REQUISITE: ENGINEERING THERMODYNAMICS (ME 103)

2. OBJECTIVE:: To provide detailed knowledge about IC Engines and Power Plant.

3. COURSE TOPICS::

UNIT I: Thermodynamic Cycles for Energy Conversion (3

Lectures)

Gas power cycles, vapour power cycles, refrigeration cycles

UNIT I : Introduction & Fuels for SI and CI engine (5

Lectures) Basic Nomenclature, Engine classification, working principle of 2 stroke and 4 stroke, fuel air cycles

and actual cycles, valve and port timing diagram. Classification of fuels, fuel properties and fuel

rating, mixture requirements

UNIT II : Combustion in SI and CI Engine (5

Lectures) Stages of combustion in SI and CI engine,detonation,effect of engine design and operating variables

on engine detonation, combustion knock, effect of engine design and operating variables on engine

knock, comparison of knock in SI and CI engine.

UNIT III : Carburettor and Fuel Injection system & Engine friction and lubrication (5

Lectures) Types of carburettor, calculation of A/F ratio for simple carburettor, mixture requirements, injection

system in SI and CI engine, components of engine friction, friction mean effective pressure.

Lubrication principle, types of lubrication, properties of lubricant.

UNIT IV : Heat transfer and Cooling system & Engine Testing and performance (6

Lectures) Engine temperature distribution, gas temperature variation, air cooling and liquid cooling systems.

Measurement of indicated power, brake power, fuel consumption, air flow rate, speed, heat balance

sheet..

UNIT V : Introduction & Power Plant Thermodynamics (5

Lectures) History and present status of energy resources. Energy sources for modern plants. Power systems and

utility demand patterns. Economics of electric power production, Basic laws of thermodynamics.

Thermodynamic power cycles. Steam cycles for modern power plants.

UNIT VI : Fossil-Fueled Steam Power Plants & Combustion (8

Lectures) Solid, Liquid and gaseous fuel. Properties of fuels. Coal and coal cleaning and processing Introduction

to power plant systems and components. Fuel handling and preparation. Steam generator configuration

and analysis. Steam separation and purification. Natural convection systems. Steam generator control.

Air circulating and heating system. Water treatment systems. Cooling towers. Emission control

systems. Waste disposal, Principles of combustion. Combustion calculations. Theoretical and

actual flame temperatures. Combustion systems

UNIT VIII: Renewable Energy Sources (2

Lectures)

Basic concepts of renewable resources: solar, wind and biomass

4. READINGS 4.1 Text Books:

a) Fundamentals of Internal Combustion Engine:H.N.Gupta

b) Power Plant Engg: P.K.Nag

4.2 Reference Books: a) Internal Combustion Engine: J.B. Heywood

b) Internal Combustion Engine: V. Ganeshann c) Fundamentals in power plant Engg., R. Yadav

d) Steam and Its Use: Babcock

5. OTHER SESSIONS Lecture[3]; Practical [2]

6.ASSESSMENT:- Homework[5%], Assignment [5%], Periodical Exams[30%], Final [60%]

7. OUTCOME OF THE COURSE:: become knowledgeable in power generation systems



INTEREST::

10.*ANY OTHER REMARKS::

List of Experiments

1. Performance testing of single cylinder petrol engine

2. Performance testing of multi cylinder petrol engine

3. Performance testing of multi cylinder diesel engine

4. Performance testing of variable compression SI engine

5. Performance testing of variable compression CI engine

6. Emission testing of internal combustion engine

7. Study of cross sectional models of automobile parts

8. Performance characteristics of solar collector

9. Study on renewable energy based electricity generation system

ME-342: REFRIGERATION & AIR CONDITIONING

1. GENERAL

1.1 TITLE:: Refrigeration & Air Conditioning

1.2 *COURSE NUMBER: BE.ME-342.15


1.4 *SEMESTER -OFFERED: EVEN

1.5 PREREQUISITE: ME-103: Engineering Thermodynamics; ME-241: Heat and Mass Transfer

2. OBJECTIVE: To provide detailed knowledge about refrigeration and air-conditioning processes

3. COURSE CONTENT

Unit 1: Introduction (2 lectures)

Society needs, History of cold production, Refrigerant use-past, present & future, Reversed Carnot

cycle

Unit 2: Air Refrigeration System (6 lectures)

Limitation of reversed Carnot cycle, reversed brayton or bell Coleman cycle, application to aircraft

refrigeration, Ranque-Hilsh tube.

Unit 3: Vapor compression system (6 lectures)

Vapour compression cycle, pressure-enthalpy diagram and calculations, effect of operating condition

on performance, actual vapour compression cycle.

Unit 4: Multi pressure System (6 lectures) Multistage or compound compression with water and float, intercooling, multi-evaporator systems

with individual and multiple expansion valves, cascade system, solid carbon dioxide.

Unit 5: (4 lectures) Refrigerant – classification, nomenclature and properties, Introduction to Production of Low

Temperature

Unit 6: Vapour absorption System (5 lectures)

Modification to simple vapour absorption system, actual vapour absorption cycle, absorption system

calculation, lithium bromide water systems.

Unit 7: Air-conditioning (10 lectures) psychometric properties, psychometric chart, pschometery of air-conditioning process, summer and

winter air conditioning, Calculation of heating and cooling loads, design of air-conditioning systems,

air duct design, refrigeration and air-conditioning controls and equipment, cold storage system

4. READINGS

4.1 Text Books:

a) Refrigeration & Airconditioning, C P Arora

b) Refrigeration & Air Conditioning , R.C.Arora

4.2 Reference Books:

a) Refrigeration & Airconditioning, Stoecker & Jones

b) Heating, Ventilating & Airconditioning by McQuiston et al.

c) Fundamentals of Cryogenics Engineering by Mukhopadhyay

5. OTHER SESSIONS *TUTORIALS:: 0; *LABORATORY:: 0; *PROJECT:: 0

6. *ASSESSEMENT:

QUIZZES-HA:: 10%; PERIODICAL EXAMINATION: 40%; FINAL EXAM:: 50%

7. OUTCOME OF THE COURSE:: become knowledgeable in refrigeration & air-conditioning



INTEREST::

ME-343: NON- CONVENTIONAL ENERGY RESOURCES

1. GENERAL

1.1TITLE: Non- Conventional Energy Resources




1.5 Thermodynamics, Fluid Mechanics, Heat Transfer

2. OBJECTIVE: To provide elementary knowledge about various non conventional energy sources

3. Course Topics:

Unit 1 (7 lectures)

Solar Radiation: Direct and diffused radiation, Radiation measuring instrument

Unit 2(8 lectures)

Solar Collectors: Optics of Solar collectors, Flat plate collectors, Collector Design and performance,

Selective surface, Collector materials.

Unit 3 (6 lectures) Applications: Water heating, Steam generation, Space heating and cooling, Distillation, Drying, Solar

ponds.

Unit 4 (5 lectures)

Photo-Voltaic Conversion: Thermo-electric and thermo ionic solar cells, Performance

Unit 5(5 lectures)

Bio Energy: Photosynthesis Conversion of plant materials and waste to fuels.

Unit 6(5 lectures)

Wind Energy: Windmills, Blade design, Application.

Unit 7(3 Lectures)

Fuel cells : Types of fuel cells, performance and applications

4. Reading:

1. S.P. Sukhatme, Solar Energy, Tata Mcgrawhill

2. S. Ahmad, Wind Energy, PHI

3. H.S. Mukund, Clean Energy and Fuels from Biomass, Wiely

4. B.H. Khan, Renewable Energy, TMH

5. Other Sessions:-

Lecture[3]; Tutorial [0], Practical[0]


7. OUTCOME OF THE COURSE:: become knowledgeable in automobile



INTEREST::

Chemical Engineering


ME-342: REFRIGERATION & AIR CONDITIONING

1. GENERAL

1.1 TITLE:: Refrigeration & Air Conditioning

1.2 *COURSE NUMBER: BE.ME-342.15


1.4 *SEMESTER -OFFERED: EVEN

1.5 PREREQUISITE: ME-103: Engineering Thermodynamics; ME-241: Heat and Mass Transfer

2. OBJECTIVE: To provide detailed knowledge about refrigeration and air-conditioning processes

3. COURSE CONTENT

Unit 1: Introduction (2 lectures) Society needs, History of cold production, Refrigerant use-past, present & future, Reversed Carnot

cycle

Unit 2: Air Refrigeration System (6 lectures)

Limitation of reversed Carnot cycle, reversed brayton or bell Coleman cycle, application to aircraft

refrigeration, Ranque-Hilsh tube.

Unit 3: Vapor compression system (6 lectures) Vapour compression cycle, pressure-enthalpy diagram and calculations, effect of operating condition

on performance, actual vapour compression cycle.

Unit 4: Multi pressure System (6 lectures) Multistage or compound compression with water and float, intercooling, multi-evaporator systems

with individual and multiple expansion valves, cascade system, solid carbon dioxide.

Unit 5: (4 lectures)

Refrigerant – classification, nomenclature and properties, Introduction to Production of Low

Temperature

Unit 6: Vapour absorption System (5 lectures) Modification to simple vapour absorption system, actual vapour absorption cycle, absorption system

calculation, lithium bromide water systems.

Unit 7: Air-conditioning (10 lectures) psychometric properties, psychometric chart, pschometery of air-conditioning process, summer and

winter air conditioning, Calculation of heating and cooling loads, design of air-conditioning systems,

air duct design, refrigeration and air-conditioning controls and equipment, cold storage system

4. READINGS

4.1 Text Books:

a) Refrigeration & Airconditioning, C P Arora

b) Refrigeration & Air Conditioning , R.C.Arora

4.2 Reference Books:

a) Refrigeration & Airconditioning, Stoecker & Jones

b) Heating, Ventilating & Airconditioning by McQuiston et al.

c) Fundamentals of Cryogenics Engineering by Mukhopadhyay

5. OTHER SESSIONS *TUTORIALS:: 0; *LABORATORY:: 0; *PROJECT:: 0

6. *ASSESSEMENT:

QUIZZES-HA:: 10%; PERIODICAL EXAMINATION: 40%; FINAL EXAM:: 50%

7. OUTCOME OF THE COURSE:: become knowledgeable in refrigeration & air-conditioning



INTEREST::

ME-343: NON- CONVENTIONAL ENERGY RESOURCES

1. GENERAL

1.1TITLE: Non- Conventional Energy Resources




1.5 Thermodynamics, Fluid Mechanics, Heat Transfer

2. OBJECTIVE: To provide elementary knowledge about various non conventional energy sources

3. Course Topics:

Unit 1 (7 lectures)

Solar Radiation: Direct and diffused radiation, Radiation measuring instrument

Unit 2(8 lectures) Solar Collectors: Optics of Solar collectors, Flat plate collectors, Collector Design and performance,

Selective surface, Collector materials.

Unit 3 (6 lectures)

Applications: Water heating, Steam generation, Space heating and cooling, Distillation, Drying, Solar

ponds.

Unit 4 (5 lectures)

Photo-Voltaic Conversion: Thermo-electric and thermo ionic solar cells, Performance

Unit 5(5 lectures)

Bio Energy: Photosynthesis Conversion of plant materials and waste to fuels.

Unit 6(5 lectures)

Wind Energy: Windmills, Blade design, Application.

Unit 7(3 Lectures)

Fuel cells : Types of fuel cells, performance and applications

4. Reading:

1. S.P. Sukhatme, Solar Energy, Tata Mcgrawhill

2. S. Ahmad, Wind Energy, PHI

3. H.S. Mukund, Clean Energy and Fuels from Biomass, Wiely

4. B.H. Khan, Renewable Energy, TMH

5. Other Sessions:-






INTEREST::

Chemical Engineering


TOOL DESIGN AND METROLOGY

1. GENERAL

1.1 TITLE : Tool Design and Metrology

1.2 COURSE NUMBER : DC.ME 351.15


1.4 SEMESTER- OFFERED : Odd

2. OBJECTIVE : :

This course would inculcate the importance holding and locating in manufacturing and impart

the knowledge to design these tools. Also, it will provide the principles of different measurement

and calibration processes and their applications in manufacturing industries.

3. COURSE CONTENT :

Unit I (10 lectures)

Jigs and Fixtures: Economic Considerations, Types, General principles and design, Location

and Clamping, Jig Bushes.

Unit II (12 lectures)

Press Tools: Press Working Operation, Design of Punches and Dies for Shearing and Forming

operations, Constructional Details, Material Selection, Strip layout and Economics.

Unit III (8 lectures)

Metrology: Standards of Measurement, Limits and Fits and Gauge Design, Linear and

Angular Measurements

Unit IV (7 lectures)

Measurements of Flatness and Screw Threads, Measurement of Surface Finish

Unit V (4 lectures)

Comparators

4. READINGS : :

4.1 TEXT BOOKS : :

1. Jigs and Fixtures by P. H. Joshi, Tata McGraw Hill

2. Tool Design by Donaldson, LeCain, Goold, Tata McGraw Hill

3. Engineering Metrology by K. J. Hume, Macdonald

4. Metrology And Measurement by Anand K Bewoor and Vinay Kulkarni, Tata McGraw Hill


1. Jigs and Fixtures by H. E. Grant, Tata McGraw Hill

2. Fundamentals of Dimensional Metrology, by Harlow, Cengage Learning

5. OTHER SESSION

5.1 TUTORIALS :

5.2 LABORATORY :

5.3 PROJECT :

6. ASSESSEMENT :

6.1 HA :

6.2 QUIZZES :

6.3 PERIODICAL EXAMINATION :30

6.4 PROJECT/ LAB :20

6.5 FINAL EXAM : 50


It is anticipated that after completion of the course, a student would be in a position to design

various holding devices to suit the requirements of the manufacturing industry. Also, students

can appreciate the quality control and inspection activity in industries.



INTEREST :

10. ANY OTHER REMARKS :

list of experiments Tool Design and Metrology(DCME351.15)

S.No Experiment

1 a) Angle measurement by Sine Bar.

(b) Measurement of Internal diameter of a Ring by Four Ball Method.

2

(a) Measurement of effective diameter of threaded component by three wire

method(Digital Method)

(b) Measurement of deviation by Reed Type Mechanical Comparator

3 (a) To perform various press working operations.

4 (b) Determination of Surface finish of a surface by Talysurf

5 (a) Precision angle measurements

(b) Gauging by pneumatic comparator

6

Jig Design

Fixture Design

Die Design

MECHANICAL BEHAVIOR OF ENGINEERING MATERIALS

5. GENERAL

1 TITLE : : Mechanical Behavior of Engineering Materials

5.1 COURSE NUMBER : BE.ME 352.15


5.3 SEMESTER- OFFERED : ODD

6. OBJECTIVE : : The course is aimed at imparting the basic understanding of the plastic

deformation, strengthening and failure mechanisms of engineering materials and their

response to mechanical loading.

7. COURSE CONTENT : :

Unit I (5 Lectures) Introduction to Materials Selection and related factors such as design, processing and

economics, Introduction to mechanical testing, elastic behavior, and viscoelasticity, Elements of

plasticity, the flow curve, Strain hardening, Strain rate and temperature dependence of flow stress.

Unit II (12 Lectures)

Plastic deformation, slip in crystals, dislocations, and dislocation motion, Twins, strengthening

mechanisms, grain boundaries, solid solution strengthening, strengthening from fine particles and

strain hardening. Heat Treatment processes, annealing, normalizing, tempering, quenching, hardening,

surface hardening, age hardening, etc.


Fracture, types of fracture, brittle fracture, Griffith theory of brittle fracture of material, ductile

fracture, notch effects, Materials aspects

Fatigue, the S-N curve, low cycle fatigue, structural features, surface effects, and metallurgical

variables.

Creep, the creep curve, stress rupture test, structural changes, creep mechanisms, and

superplasticity, Embrittlement, residual stresses.

Unit IV (6 Lectures)

Properties and Applications; Properties and applications of Engineering materials like steels

(Plain carbon, HSLA, Micro-alloyed, Tool and Die steels), Cast Iron, Brass, Bronze, Al base alloys, Ni

and Ti base alloys

Unit V (5 Lectures)

Introduction to mechanical behavior of Ceramics, polymeric materials (thermosets and

thermoplastics, elastomers), and composite materials.

8. READINGS : :

8.1 TEXT BOOKS : :

3. Title: Mechanical Metallurgy, Author: George E Dieter, 3rd Ed., McGraw Hill. 1988


1. Title: ―Mechanical Behavior of Materials‖, Author: Courtney, T.H., 2nd Ed., McGraw Hill.

1990

2. Title:: ―Materials Science and Engineering‖ Author: W D Callister Jr. John Willey, Latest

Ed.

3.Ttile: : Mechanical Behavior of Materials‖, Authors: Meyers, M.A. and Chawla, K.K.

Prentice Hall. 1999

5. OTHER SESSION

5.1 TUTORIALS : : NA

5.2 LABORATORY : : NA

5.3 PROJECT : : NA

6. ASSESSEMENT : :

6.1 HA : : 10

6.2 QUIZZES: 10


6.4 PROJECT/ LAB : : NA


7. OUTCOME OF THE COURSE : :. It is anticipated that after completing the course the student will

be able to select and tailor the materials based on the service requirements.



INTEREST :


TRIBOLOGY OF MANUFACTURING PROCESSES

1. GENERAL

1.1 TITLE : : Tribology of Manufacturing Processes



1.4 SEMESTER- OFFERED : EVEN

2. OBJECTIVE:: The course is aimed at imparting the basic understanding of the tribological

phenomena occurring in metal forming processes. It also aims to highlight some ethical and

societal concerns regarding the selection of materials, processes and lubricants that are

ecofriendly.


Unit I (9 Lectures)

Introduction to Tribology, Tribological issues in manufacturing processes, Fundamentals of

friction and wear, theories of friction, Types of wear

Unit II (9 Lectures)

Wear mechanisms in rolling, forging, extrusion, sheet metal forming and drawing operations.

Unit III (9 Lectures)

Properties and characteristics of lubricants and cutting fluids, role of lubricants in metal

forming, evaluation of lubricants for different metal forming processes, effect of additives on the

performance of lubricants

Unit IV (3 Lectures)

Environmental and societal issues, Energy conservation through better process design

Unit V (9 Lectures)

Surface treatments for improving tribological performance like shot peening, coating, texturing

etc. Materials and lubricants selection for forming process equipments, tools and dies.

4.1 READINGS : :

1. TEXT BOOKS : :

1, TITLE:: Tribology of Manufacturing Processes, , AUTHORS::. Eric FELDER and Pierre

MONTMITONNET, Proceedings of the 4th International Conference on Tribology in

Manufacturing Processes, Vol. 2, 2010.

2. TITLE:: Principles and Applications of Tribology, AUTHORS:: Bharat Bhushan, John Wiley,

1999.


1. TITLE:: Engineering Tribology, AUTHORS:: Gwidon W. Stachowiak and Andrew W.

Batchelor, Butterworth Heinemen, 1993.

5. OTHER SESSION

5.1 TUTORIALS : : NA

5.2 LABORATORY : : NA

5.3 PROJECT : : NA

6. ASSESSEMENT : :

6.1 HA : : 10

6.2 QUIZZES- HA : : 10


6.4 PROJECT/ LAB : : NA


7. OUTCOME OF THE COURSE : : It is anticipated that after completing the course the students will

be able to select the materials and lubricants that will effectively help in reducing friction between

mating parts based on the process requirements leading to energy savings because a lot of energy is

consumed in overcoming friction.



INTEREST : :


Engineering Economics

1. GENERAL

1.1 TITLE::Engineering Economics

1.2 COURSE NUMBER (if known):: BE.ME 479.15


1.4 SEMESTER-OFFERED:: V(ODD)

1.5 PRE-REQUISITES::The fundamental concepts of financial accounting and finance.

2. OBJECTIVE::Prepare engineering students to analyze cost/revenue data and carry out or make

economic analyses in the decision making process to justify or reject alternatives/projects on an

economic basis. This course gives the idea of time value of money, IRR, payback period,

inflation, depreciation, cost-benefit analysis etc. It will help students to evaluate public &

private projects etc.

3. COURSE TOPICS::

Unit I:Economics (6 Lectures) Supply and demand, microeconomics, opportunity cost, Elasticity, Market structures, How the

economy works, GNP, Inflation, Keynesian & monetarist theory

Unit II: Background & Tools of Engineering Economy (8Lectures)

Introduction, Cost concepts, economic concepts and accounting.

Unit III: Application of Engineering Economy(8Lectures) Application of money time relationship, Comparing alternatives, Project evaluation with

benefit-cost ratio method, Depreciation,

Unit IV:Economic analysis after taxes(9Lectures)

Depreciation methodsand income taxes ,Estimating cash flows, Inflation and price changes,.

Unit V: Special Topics in Engineering Economy(8Lectures)

Replacement analysis, Capital financing and allocation, Probability risk analysis.

4. READINGS

4.1 TEXT BOOK::

Fundamentals of Engineering Economics, Third edition, by ChanS. Park

4.2 *REFERENCE BOOKS::

Engineering Economic Analysis by Donald Newnan

5. OTHER SESSIONS

5.1 *TUTORIALS::No

5.2 *LABORATORY::No

5.3 *PROJECT::Yes

6. Assessment (indicative only)

6.1 HA:: [5% GRADE]

6.2 QUIZZES-HA:: [0% GRADE]

6.3 PERIODICAL EXAMS:: [30% GRADE]

6.4 *PROJECT:: [5% GRADE]

6.5 FINAL EXAM:: [60% GRADE]


Understanding of analysis of projects, Learn to compare alternatives, replacement analysis,

topics like inflation, worth calculation, depreciation etc.

8. *EXPECTED ENROLMENT FOR THE COURSE:: 50

9. *DEPARTMENTS OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD BE

OF INTEREST:: All Department

10. *ANY OTHER REMARKS:: No

FINITE ELEMENT METHOD

1. GENERAL

1.1. TITLE:: Finite Element Method

1.2. COURSE NUMBER::DE.ME 411.15


1.4. SEMESTER -OFFERED:: VII

1.5. Prerequisite: Strength of Materials

1.6. Syllabus Committee Member: Dr S. K. Panda

2. OBJECTIVE:: Solving real field problem has been made easy with the advent of Finite Element Method

(FEM). FEM as a numerical tool is applicable to almost all field of Engineering and Science,

hitherto either experimental set ups are much more prone to errors or such unrealistic

assumptions of Analytical methods.

3. COURSE CONTENT

UNIT I: COMPUTATIONAL MODELING(5 Lectures) Introduction to numerical methods, Physical Problems in Engineering, Three-dimensional

stress analysis: 3 D Solid, Plates, Beams, Truss, Computational modeling using FEM,

Commercial FEM software and applications, Simulation and Visualization.

UNIT II: MATRIX TECHNIQUES(5 Lectures)

Introduction concept of matrices, Solution of large systems of algebraic equations,

discretization of domain: Type of elements. Shape functions. Isoparametric elements.

UNIT III:VARIATIONAL METHODS (6 Lectures)

Variational formulation. Euler - Lagrange equation. Introduction to ‗‗delta operator and its

use for solution of heat conduction problems. Methods of weighted residual techniques-Weak

Formulation, Galerkin FE formulation, Rayleigh & Ritz FEM.

UNIT IV: FEM FOR TRUSSES, BEAMS AND FRAMES (7 Lectures) FEM analysis of One-dimensional problems:-Second order boundary value problem,

Applications in Solid, Fluid and Heat Transfer, Bending of Beams, Euler-Bernoulli Beam,

Truss/Frame analysis, 2D Problems

UNIT V: EIGENVALUE AND TIME DEPENDENT PROBLEMS (7 Lectures)

Eigen problems, Transient Dynamic Problems, Hamilton‘s Principle, Free vibration analysis

and methods of solution.

UNIT VI: NUMERICAL INTEGRATION AND APPLICATION (8 Lectures)

Numerical Integration and Computer Implementation-Natural Co-ordinates, Interpolation

Functions, Numerical Integration, Isoparametric Formulation, Computer Implementation,

Applications in two-dimensional problems-Plane Stress and plane Strain, Three Dimensional

Solid, Axi-symmetric Solid, Plate and Shell structures, Flow of Viscous Fluid, MATLAB

Application,

UNIT VII: Special Topics (5Lectures)

Stationary Singular elements, Quarter-Point Singular Elements, Moving singular elements,

Semi-infinite elements, Buckling analysis, Non-linear analysis

.

4. READINGS

TEXTBOOK::

REFERENCE BOOKS::

1. Finite Element Analysis: B. Izabo and I Babuska

2. The Finite Element Method for Solid and structural Mechanics: O.C. Zienkiewicz and R. L.

Taylor

3. Finite Element Procedures in Engineering Analysis: K. J. Bathe

4. An Introduction to Finite Element Method: J. N. Reddy

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT :

6.1 HA : 5 %






Numerical modeling and design of structures or classical problem of research interest can be

tackled



INTEREST:


FRACTURE MECHANICS

1. GENERAL

1.1. TITLE:: Fracture Mechanics

1.2. COURSE NUMBER::BE.ME 412.15



1.5. Prerequisite: Strength of Materials

1.6. Syllabus Committee Member: S. K. Panda

2. OBJECTIVE::

Studying the damage tolerance analysis of structures with pre-existing flaws.

3. COURSE CONTENT

UNIT I: FAILURE AND FRACTURE (7 Lectures) Basic theory of failure, Yield dominant behavior, Stress analysis of cracked bodies, Stress

intensity factor.Fracture: Basic modes of fracture, Griffith theory of brittle fracture, Irwin‘s

theory of fracture in elastic-plastic materials

UNIT II: FRACTURE TOUGHNESS EXPERIMENTATION (6 Lectures) Fracture toughness, Experimental determination of stress intensity factor and fracture

toughness for engineering materials.

UNIT III: MECHANISM OF FRACTURE AND CRACK GROWTH(5 Lectures)

Crack Propagation and Subcritical Crack Growth: Assessment/prediction of structural life

inspection technique for locating crack.

UNIT IV: LINEAR ELASTIC FRACTURE MECHANICS (10 Lectures)

Equation of Elasticity, Crack tip stress field, Energy Criterion, Collapse vs Fracture

UNIT V: ELASTIC PLASTIC FRACTURE MECHANICS (9 Lectures) J-integral, R-curves, Elastic-plastics fracture, Griffith energy criterion for crack growth of

stable and critical cracks.

UNIT VI: FATIGUE (5 Lectures)

LCF, SCF, Fatigue and Fracture, Paris Law, crack propagation rates.

4. READINGS

4.1. TEXTBOOK::

4.2. REFERENCE BOOKS::

4.2.1. Fracture Mechanics Fundamentals and applications: T. L. Anderson

4.2.2. Introduction to Fracture Mechanics: K. Hellan

4.2.3. Fundamentals of Fracture Mechanics: Knott J. F.

4.2.4. Elementary Engineering Fracture Mechanics: David Broek

4.2.5. Failure Fracture Fatigue: Dahlberg. T and Ekberg.A

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT :

6.2 HA : 5 %






Characterization of crack propagation behavior and analysis of fatigue crack growth.



INTEREST:


EXPERIMENTAL MECHANICS AND NON-DESTRUCTIVE TESTING

1. GENERAL

1.1. TITLE:: Experimental Mechanics and Non-destructive Testing


1.3. CREDITS::3-0-0(09 Credits)

1.4. SEMESTER -OFFERED:: VIII


1.6. Syllabus Committee Member: Dr.V.K.Srivastava, Dr.S.K.Panda

2. OBJECTIVE An experimental stress analyst must have a though understanding of stress, strain and the lawas

relating stress to strain. For this reason, elementry theory of elasticity is essential to know the

behaviour of stress under the applied load. Experimental photoelastic stress analysis is essential

method to overview the real image of stresses under applied load. The main advantage of this

subject is to combine the stress with the light to predict the principal stress and stress concentration

factor etc. Also, mechanical properties can be obtain with the help of various experimental

methods.

3. COURSE CONTENT

UNIT I: ( Lectures) Photoelastic technique of stress analysis, Plane Polariscope, Circular Polariscope , Properties

of model material, calibration, stress freezing.

UNIT II: ( Lectures) Various types of strain measurement, Electrical resistance strain gauge and related instrument,

strain rosettes.

UNIT III: ( Lectures)

Theory of brittle coating method, Behavior of brittle lacquer, Selection of brittle lacquer and its

application.

UNIT IV: ( Lectures)

Interferometry, Holography, Moire fringes and their application in stress analysis.

Birefrigerent coating, Piezoelectric sensors, Non-contact stain measurement and remote strain

measurements.

UNIT V: ( Lectures)

Non-destructive Testing: Ultrasonic Method : Oscillations and waves, Modes and forms of waves, Sound waves on

boundaries at perpendicular incidence, Geometric ultrasonic optics, Attenuation of ultrasonic

waves in solids, Resonance methods, Pulse echo methods, Through transmission methods,

Ultrasonic holographic method , Types of ultrasonic probes, Applications.

X-Radiography Method : Principle of differential absorption, Properties of penetrations,

Effect of focal distance, Power and current on radiograph, Applications of X-radiograph,

Safety and precaution, Eddy Current Method: Principles and applications.

Magnetic Methods: Principle and applications, Liquid Penetrant Methods

4. READINGS

4.1. TEXTBOOK

4.2. Experimental Mechanics by James W. Dally & William F. Riley

4.3. Experimental stress analysis by L.S. Srinath, M.R. Raghavan, et. al.

4.4. Elements of Experimental Stress analysis by A.W. Hendry

4.5. Advances in Nondestructive Testing by L.J. Broughtman

4.6. Handbooks of Nondestructive testing Vol. I & II., ASTM book.

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT :

6.3 HA : 5 %






This course will provide the complete information about effect of stress, strain, fracture resistance,

crack growth and effect of defects on mechanical performance of materials by various

experimental methods



INTEREST:


CONTROL SYSTEMS ENGINEERING

9. GENERAL

9.1 TITLE : : Control Systems Engineering

9.2 COURSE NUMBER : : DE.ME 421.15

9.3 CREDITS : : 3-0-0 (9 credits)

9.4 SEMESTER- OFFERED : VIII(EVEN)

9.5 Prerequisite: None

9.6 Syllabus Committee: Dr. Nilanjan Mallik

10. OBJECTIVE : :

This course is designed for the students to understand and utilize control concepts. The course

will introduce the students about conventional classical and modern control methods.

Afterwards advanced concepts of control like digital control, optimal control, Kalman filter,

robust control, nonlinear control will be discussed. Practical problem will be solved with each

concept. Software like MATLAB and Simulink will be used for hands on experience.


Unit 1 Introduction 2 Lectures

Unit 2 Linear systems and classical control 5 Lectures

Unit 3 State space representation 5 Lectures

Unit 4 Observer, Observability and compensator 2 Lectures

Unit 5 Linear optimal control, regulator gain matrix, matrix riccati

equation

8 Lectures

Unit 6 Kalman filters 4 Lectures Unit 7 Digital control systems 7 Lectures

Unit 8 Robust control, nonlinear optimal control 7 Lectures

12. READINGS : :

12.1 TEXT BOOKS : :

4. Title: Modern control design with MATLAB and Simulink, Author: Ashish Tewari


13. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

14. ASSESSEMENT :

6.4 HA : 5 %





15. OUTCOME OF THE COURSE : From this course students will be able to learn basic concepts of control engineering and some

advanced concepts of control engineering. They will also be able to apply these concepts to

design and analyze control systems. Students will also use hands on experience on use of

MATLAB.

8 . EXPECTED ENROLMENT IN THE COURSE: 30


INTEREST:


ME-431: TURBOMACHINES

1. GENERAL

1. 1TITLE: Turbomachines


1.3 CREDITS:: 3-0-0(09 Credits) 1.4 *SEMESTER -OFFERED::ODD, VII Sem

1.5 Prerequisite: Thermodynamics, Fluid Mechanics

2. Objective: To provide elementary knowledge about Turbomachines

3. Course Topics:

PART –I: General Considerations

Introduction Module-1: Nomenclature – Concepts – Theoretical aspects

L1: Classification of Fluid Machinery, stage, stator, rotor

L2: Cylindrical co-ordinate system, Moment of momentum, notations

L3: Euler Equation for turbomachinery

L4: Concept of relative velocity, Velocity-vector equation, Velocity triangle

L5: Performance indices like power, efficiency

Module-2: Dimensional Analysis & Similitude

L6: Dimensional Analysis

L7: Similitude

Module-3: Introduction to Gas and Steam Turbine

L8: Nozzles; shape, critical pressure ratio, maximum mass flow rate, design pressure ratio, nozzle

efficiency, steam nozzle:off design performance

L9: Introduction in gas and steam turbine.

L10: The impulse steam turbine, pressure velocity compounded impulse steam turbines & axial flow

reaction turbines, wind turbines

PART –III: Rotodynamic Pumps

Introduction Module-4: Centrifugal pumps

L11: Types; geometry and working; elementary pump theory; Euler equation; Bernoulli equation in

rotating coordinates

L12: Velocity diagrams at entry and exit of the impeller; output and performance parameters –

manometric head, manometric efficiency, overall efficiency; effect of blade angle on pump head.

L13: Pump performance curves and similarity rules; NPSH and cavitation; specific speed for pumps;

pumps andf fluid networks.

Module-5: Axial-flow and Mixed-flow Pumps

L 14 & L15 : Specific speed and variation of shape; axial-flow pump theory; performance of axial-

and mixed-flow pumps, positive displacement pumps, general aspects, series and parallel combination.

PART –IV: Compressors

Introduction Module-6: Centrifugal Compressors

L16: Geometry, definitions, working; velocity diagrams across the impeller.

L17: Theoretical analysis; enthalpy-entropy diagram of a stage; energy equation for the inlet casing,

impeller and diffuser.

L18: Inlet velocity limitations; optimum design of inlet; slip factor and correlations.

L19: Head increase; performance – efficiency; effect of vane angle; diffuser system;

Module-7: 2D Compressor Cascade

L20 & L21: Two-dimensional cascades; cascade nomenclature; Cascade forces – lift and drag; cascade

efficiency; losses; cascade correlations.

Module-8: Axial-flow Compressors

L22: Geometry and working; stage – stator and rotor blading; velocity diagram across the rotor;

L23: Thermodynamics of the compressor stage; enthalpy-entropy diagram for a stage; energy equation

across the rotor and the diffuser; degree of reaction; stage loading; off-design performance.

L24: Stage pressure rise; pressure ratio of a multistage compressor; work done factor; efficiency; Stall

and surge phenomenon; control of flow instabilities; axial-flow ducted fans.

Module-9: Reciprocating Compressors & Refrigerant Compressor

L25: Geometry and working; cycle analysis; actual indicator diagram, isothermal and volumetric

efficiency.

L26: Effect of multistage compression on volumetric efficiency; effect of intercooling; work of a

multistage compressor & refrigerant compressors

4. Reading:

a. S.L.Dixon, Fluid Mechanics and Thermodynamics of Turbomachinery, 4e, Butterworth and

Heinemann, 1998 (Main text book).

b. J.F.Douglas, J.M.Gasiorek and J.A.Swaffield, Fluid Mechanics, 3e (Ch 22, 23, 24 & 25), Addison-

Wesley, 1995 (International Student Edition 1999)

c. B.S.Massey, Mechanics of Fluids, 5e (Ch. 14 &9), Van Nostrand Reinhold (U.K.), 1983.

d. H.I.H.Saravanamutto, G.F.C.Rogers and H.Cohen, Gas Turbine Theory, 5e (Ch. 4 & 5 Pearson

Education (Singapore), 2001.

5. Other Sessions:- Lecture[3]; Tutorial [0]; Practical[0]


7. OUTCOME OF THE COURSE:: become knowledgeable in turbomachines



INTEREST::

Civil/Chemical Engineering

ME-432: AUTOMOBILE ENGINEERING

1. GENERAL

1.1TITLE: Automobile Engineering

1.2 *COURSE NUMBER:: DE.ME 432.15


1.4 *SEMESTER -OFFERED::ODD

1.5 Prerequisite: IC Engine & Power plant (ME-341)

2. Objective: To provide elementary knowledge about automobile engineering

3. Course Topics:

UNIT I : Introduction&Transmission systems (13 Lectures)

Automotive engine classification, chassis construction, frame and its function, material of chassis and

body, Power and torque characteristics, rolling ,air and gradient resistance, calculation of road

resistance and tractive power.

Clutchsingle plate, multi plate clutch, centrifugal clutch, constructional details, torque capacity and

clutch friction materials,Layout of transmission system, Sliding mesh, constant mesh and synchromesh

gear box, power flow diagrams, torque converter, over drive and free wheel unit, automatic

transmission-an overview, universal coupling, propeller shaft, rear ,differential, semi floating and full

floating rear axles.

UNIT-II : Steering system(6 Lectures) Types of steering system, system components, rack and pinion steering gear, power steering, steering

geometry, Ackerman linkage, centre point steering and camber angle, castor angle, toe-in, toe-out,

slip angle,cornering power, under steer and over steer , steering mechanism, wheel alignment,

balancing.

UNIT-IV : Suspension, Wheels& tyres (9 Lectures)

Purpose, front and rear suspension, independent suspension, system components, leaf spring, coil

spring, torsion bars, dampers, MacPhreson sturt, air suspension system.

Types of wheels, construction, wired wheels, tyres, radial and bias, comparison, slip angle, thread

patterns, tyre specifications.

UNIT-V : Brakes (5 Lectures) Types of brake, mechanical, hydraulic, pneumatic brakes, drum and disc brakes, hydraulic brakes, air

brakes, brake system components, valve, calliper and brake shoes, road tyre adhesion, weight transfer

and thermal aspects.

UNIT-VI : Ignition &other systems (6 Lectures) Battery ,magneto and electronic ignition systems, cooling systems, fuel supply systems, exhaust

systems, auxiliary systems, principle of electric drive.

4. Reading:

1. Automobile Engineering, Kirpal Singh

2. Automobile Engineering, R.K. Rajput

3. Automobile Engineering, K.M.Gupta.

5. Other Sessions:-

Lecture[3]; Tutorial [0] Lab[0]





INTEREST::

ME-433: COMPUTATIONAL FLUID DYNAMICS

1. GENERAL

1. 1TITLE: Computational Fluid Dynamics


1.3 CREDITS:: 3-0-0 (09 Credits)


1.5 ME-231: Fluid Mechanics & Fluid Machinery, ME-241: Heat and Mass Transfer

2. OBJECTIVE: To provide elementary knowledge about CFD (Computational Fluid Dynamics)

3. COURSE TOPICS:

Unit: 1: Introduction[L 9]

Introduction, Partial differential Equations (PDEs), Discritization methods, stability issues, solution of

discritized algebric equations, TDMA, Line by line solver

Unit: 2: Numerical methods for incompressible fluid flow[L 16]

Convection Diffusion (Steady/unsteady, 1D),Convection Diffusion (Steady/unsteady, 2D)

Different schemes, Central, upwinding, hybrid, exponential scheme.

Introduction, Governing Equations, Difficulties in Solving Navier-Stokes Equations.

Stream Function and vorticty method, General Algorithm for solution- methods, Creeping flow,

Inviscid Flow (steady), Determination of pressure for viscous flow,

Unit: 3: Pressure velocity Link-up[L 5]

The primitive variable approach

Simple (Semi-Implicit Method for pressure linked equations) procedure of Patankar (1980) and

Spalding (1972), Computation of boundary layer flow. Simpler, SimpleC

Unit: 4: Numerical methods for convection heat transfer:[[L 9]

Computation of Thermal Boundary layer Flows, Transient Free convection from heated vertical Plate.

Use of NS solver for bench mark problems in unstructured grid

4. Reading:

1. S.V.Patankar, Numerical Heat Transfer and Fluid Flow, Hemisphere

2. H. Versteeg, W. Malalasekera, Introduction to CFD, Pearson

5. Other Sessions:-

Lecture[3]; Tutorial [0]; Practical[0]


7. OUTCOME OF THE COURSE:: become knowledgeable in Computational Fluid Dynamics



INTEREST::

Chemical and Civil Engineering


1. General

ME-441: Internal Combustion Engines

1. 1Title: Internal combustion Engines


1.3 CREDITS:: 13

1.4 *SEMESTER -OFFERED::EVEN

1.5 Prerequisite: Engg Thermodynamics

4. Objective: To provide detailed knowledge about IC Engine

5. Course Topics:

Introduction : Basic Nomenclature, Engine classification, working principle of 2 stroke and 4 stroke,

Analysis of air-standard cycles, fuel air cycles and actual cycles, valve and port timing diagram.

(4:Lecture)

Combustion in SI and CI Engine: Stages of combustion in SI and CI engine, detonation, effect of

engine design and operating variables on engine detonation, combustion knock, effect of engine design

and operating variables on engine knock, comparison of knock in SI and CI engine, combustion

chamber for SI and CI engine. (5 :Lecture)

Fuels for SI and CI engine: Classification, solid, liquid and gaseous fuels, fuel properties and fuel

rating, mixture requirements, characteristics of SI and CI engine fuels.

(3 :Lecture)

Carburettor and Fuel Injection system: Types of carburettor, mixture requirements, single point and

multipoint injection system in SI engine, rate of fuel injection in CI engine, air and solid injection

systems, fuel injection pumps and nozzle.

(5 :Lecture)

Engine friction and lubrication: Components of engine friction, friction mean effective pressure,

Blowby losses, effect of engine variables on friction, side thrust on piston. lubrication principle, types

of lubrication ,properties of lubricant.

(4 :Lecture)

Heat transfer and Cooling system: Engine temperature distribution, heat transfer consideration, gas

temperature variation, effects of operating variables on heat transfer , air cooling and liquid cooling

systems, concept of adiabatic engine

(3 :Lecture)

Engine Testing and performance: Measurement of indicated power, brake power, fuel consumption,

air flow rate, speed, spark timing, performance characteristics, heat balance sheet.

(3 :Lecture)

Supercharging and Scavenging in IC engine : Methods of supercharging, supercharging in SI and

CI engine, limits of supercharging in SI and CI engine. 2 stroke engine scavenging, scavenging

arrangements, scavenging parameters.

(6 :Lecture)

Ignition System: Battery ignition, Magneto ignition and Electronic ignition, factors affecting spark

advance, spark advance mechanism. (2

:Lecture)

Exhaust Emissions; Pollutant formation, measurement of exhaust emissions. NDIR, FID, CLA,

measurement of exhaust smoke, gas chromatography, effect of operating variables on SI and CI engine

pollutant, pollution norms.

(4 :Lecture)

6. Reading:

1. H.N.Gupta, Internal Combustion Engine

2. V.Ganeshann, Internal Combustion Engine

3. Heywood, Internal Combustion Engine

7. Other Sessions:-

Lecture[3]; Practical [0]


9. Chemical Engineering may be interested to opt for it.


ME-442: BIO TRANSPORT MECHANISM

1. GENERAL

1.1TITLE: Bio Transport Mechanism


1.3 CREDITS:: (3-0-0)9 credit

1.4 *SEMESTER -OFFERED:: EVEN

1.5 Prerequisite: ME-241: Heat and Mass Transfer

2. Objective: To provide detailed knowledge about Transport mechanism in biological systems

3. Course Topics: Bio Transport Mechanism

Unit-1 (10 lectures)

Basics of transport mechanism applied to biological systems

Unit-2 (10 lectures) Principles of combined mass transport in homogeneous and heterogeneous reaction systems as applied

to biological processes.

Unit-3 (10 lectures) Introduction to chemical and biochemical reaction kinetics, methods of evaluating kinetic parameters

from reaction rate data

Unit-4 (9 lectures)

Prediction of the performance of biological and biochemical processes.

4. Reading

Welty, James R., Charles E. Wicks, Robert E. Wilson, and Gregory L. Rorrer. Fundamentals of

Momentum, Heat, and Mass Transfer, Fifth Edition. John Wiley, 2008.

Biological & Bioenvironmental Heat & Mass Transfer by AK Dutta

Optional: 1.Truskey, George A., Fan Yuan, and David F. Katz. Transport Phenomena in Biological Systems,

Second Edition. Prentice Hall/Pearson 2009.

5. Other Sessions:-



7. OUTCOME OF THE COURSE:: become knowledgeable in transport phenomena in biological

system



INTEREST::

Chemical, Biomedical, Biochemical Engineering

ME-443: POWER GENERATION

1. GENERAL

1. 1TITLE: Power Generation

1.2 *COURSE NUMBER:: BE.ME.443.15


1.4 *SEMESTER -OFFERED::Even

1.5 Prerequisite: ME-103: Engg Thermodynamics

2. OBJECTIVE: To provide detailed knowledge about power plant technologies

3. COURSE TOPICS:

Unit 1:(13 lectures)

Power development in India, Organizational structure of power supply, Selection of large thermal

power stations, station layout, power plant economics (05L)

Basic power plant thermodynamics, Steam cycles for modern power pants. Combined Cyles (04L)

Fossil fuels and combustion, combustion systems.(04L)

Unit 2:(16 lectures)

Steam generation, Types of boiling, Circulation systems, and Design considerations.(02L)

Fuel burning and preparation equipment, Furnaces, Superheater, Reheater, De-superheaters, Draft

system, Economisers, Soot blowers, Air heaters, Coal pulverizers, Coal feeders, Factors affecting the

performance of pulverizers. (04L)

Ash handling systems, FD and I.D. fans, Dust extraction plant, Cyclone collectors and electrostatic

precipitators.

Water treatment systems, Cooing water systems.(03L)

Steam turbines and their applications, Performance and governing of steam turbines,Gas turbines

(05L)

Power plant electric generator and electrical systems (02L)

Unit 3:(10 lectures) Basic features of hydroelectric power plant, Turbines, Losses, Cavitation, Surge tanks, Governors,

Actuators. (04L)

Basic nuclear power plant, Nuclear fuels, Enrichment of nuclear fuels, power reactor systems, nuclear

fuel cycle (06L)

4. Reading:

1. P.K.Nag: Power Plant Engineering,

2. M.M.Wakil: Power Plant Technology,

3. J. Weisman & R Eckart: Modern Power plant engg.

5. Other Sessions:-

Lecture[3]; Tutorial [0]


7. OUTCOME OF THE COURSE:: become knowledgeable in power plant system and economics



INTEREST::

ME-444: WIND POWER METEOROLOGY

1. GENERAL

1.1TITLE: Wind power meteorology



1.4 *SEMESTER -OFFERED:: Even

1.5 Prerequisite: ME-231: Fluid Mechanics & Fluid Machinary

2. OBJECTIVE: To provide detailed knowledge about wind energy and wind speed data modeling

3. Course Topics:

Unit 1 (5 lectures)

Introduction and historical notes on development of wind power, types of wind and nature of wind,

wind quality, variation of wind speed with elevation, maximum wind turbine efficiency: Betz ratio

Unit 2(8 lectures)

Wind machinery and generating systems, rotor blade assembly, tower, nacelle components, balance-

of-station subsystems, system design challenges, wind turbine rating

Unit 3 (6 lectures)

Wind power economics, measures of sustainability, net energy analysis, cost of externalities,

environmental impact of wind power

Unit 4 (8 lectures)

Meteorological aspects, parent wind climate model, Weibull distribution, different methods for

estimating Weibull parameters, e.g. , least square method, method of moment, maximum likelihood

method, empirical method, energy pattern factor method etc., extreme value distributions for upper tail

modeling, Gumbel, Fre‘chet and Reverse Weibull distribution, uncertainty in wind power estimation,

choice of appropriate site

Unit 5(8 lectures)

Wind turbine aerodynamics, wind induced vibrations on wind turbine structures, gust induced

vibrations, vortex induced vibrations, wind loading due to extreme wind condition, wind and wave

loading in offshore wind turbine

Unit 6(4 lectures)

Indian scenario of wind energy, potential wind energy map of India, current and future prospects

4. Reading:

a) Wind Power Meteorology: E.L. Petersen

b) Wind Energy: Theory and Practice: Siraj Ahmed

5. Other Sessions:-

Lecture [3]; Tutorial [0], Practical [0]


7. OUTCOME OF THE COURSE:: become knowledgeable in wind energy



INTEREST::

Civil Engineering

ME-445: APPLIED CFD

8. GENERAL

8.1. TITLE:: Applied CFD

8.2. COURSE NUMBER:: DE.ME-445.16

8.3. CREDITS:: 3-0-0 (9 Credits)

8.4. SEMESTER -OFFERED:: EVEN


9. OBJECTIVE

Applied Computational Fluid Dynamics (CFD) provides an introduction to the theoretical

fundamentals as well as application of CFD in analyzing flow and heat transfer problems of

practical engineering interest. A detailed overview of the theory and numerics of CFD is provided.

Students are trained to preprocess raw geometric data, mesh it and develop a CFD model. The

students will understand the process of developing a geometrical model of the flow, applying

appropriate boundary conditions, specifying solution parameters, and visualizing the results

keeping in mind the theory behind the CFD process. Students are expected to know the limitations,

accuracy, errors and challenges ahead in CFD solutions.

10. COURSE CONTENT

Unit I (6 lectures)

Concept of boundary layer and scaling laws, Governing Equations: Continuity, Momentum and

Energy Equations, reduction of equations for various fluid flow systems, boundary layer

approximations to momentum and energy, scale analysis

Laminar external flow and heat transfer: Scale analysis, similarity solutions for flat plate (Blasius

solution), scale analysis of thick and thin thermal boundary layer, turbulent flows, LES, DNS, solution

techniques of convection-diffusion problems


Pre-Processing techniques, Complex geometry handling: feature curves, surface organization, free

edges, other pre-processing techniques, Volume extraction technique: Fluid and solid volume, feature

curves, organization, free edges etc. Meshing strategies: Mesh refinement in critical region, 2D and 3D

meshing, quality checks and improvements

Unit III (Lectures 5)

Incompressible flow Steady and unsteady laminar and turbulent flows, multi-component flow, flow

over cylinder, lift and drag coefficient prediction, flat plate boundary layer, lid driven cavity flow

Compressible flow, Flow through turbine blades, modeling subsonic and transonic flow

Unit IV (Lectures 8)

Heat transfer and radiation Conjugate heat transfer, natural convection, graphic card cooling,

surface-surface radiation, Multiphase flow, Volume of Fluid: Gravity driven flow, boiling etc., particle

laden flow in a rotating body

Unit V (Lecture 5)

Turbomachinery Moving reference frame and rigid body motion, rotating fan, techniques for 3D

to 2D conversion

Unit VI (Lectures 6)

FVM vs. FEM Which gives better result: FVM or FEM, linear static analysis, plane stress, Fluid

Structure Interaction (FSI)

Unit VII (Lecture 4)

Real to VirtualGenerating 3D CAD models from still images of real objects, photo capturing

techniques, Developing FEM/CFD models, analysis and reports.

11. READINGS

11.1. TEXTBOOK i. S. V. Patankar, "Numerical Heat Transfer and Fl uid Flow, " Hemi sphere Publishing

Corporation, 1980.

ii. D. A. Anderson, J. C. Tannehill , and R. H. Pletcher, "Computational Fluid mechanics and

Heat Transfer, " Hemi sphere Publishing Corporation, 1984.

iii. H. K. Versteeg and W. Malalasekera, "An Introduction to Computational Fluid Dynamics: The

Finite Volume Method",

iv. Nitin S. Gokhle, ―Practical Finite Element Analysis‖.

12. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: Yes

5.3 PROJECT: YES

13. ASSESSEMENT :

6.4 HA : 5 %






Acquire hands-on and practical knowledge of industry standard tools and processes on CFD



INTEREST : Civil Engineering, Electrical Engineering, Electronics engineering, Metallurgy

engineering

UNCONVENTIONAL MACHINING PROCESSES

1. GENERAL

1.1 TITLE : Unconventional Machining Processes

1.2 COURSE NUMBER : DE.ME 451.15


1.4 SEMESTER- OFFERED : Odd

2. OBJECTIVE : :

The objective of the course is to impart the basic understanding of the various machining

processes to be utilized for machining accurate intricate shapes in the materials which are

difficult to machine by conventional machining processes and to machine the materials which

can be difficult to machine or cannot be machined at all by conventional machining processes.

It obviously covers various components of machining processes which includes; mechanics,

design, limitations and applications of the various processes.

3. COURSE CONTENT :


Mechanical Processes: Abrasive jet Machining, Water jet Machining & ultrasonic Machining,

Abrasive-Water Jet Machining, Abrasive Flow Machining, Magnetic Abrasive Finishing &

Ultrasonic Machining.

Unit 2 (6 lectures)

Chemical Processes & Electro-chemical Processes: Chemical Machining & Electro-chemical

Machining.


Thermo-electric Processes: Electric Discharge Machining, Wire Electric Discharge Machining.

Electron Beam Machining, Laser Beam Machining, Ion Beam Machining & Plasma Arc

Machining.

Unit 4 (5 lectures)

Hybrid Machining Processes: Abrasive- Water Jet Machining, Electro-Chemical Grinding,

Electro-Chemical Spark Machining, Electro-Chemical Arc Machining, Electro Discharge

Abrasive Grinding

4 READINGS : :

4.1 TEXT BOOKS : :

1. New Technology by Amitabh Bhattacharya

2. Modern Machining processes by P. C. Pandey and H. S. Shan

3. Advanced Machining Processes by V. K. Jain


1. Advanced Methods of Machining by J. A. McGeough

2. Modern Machining Methods by M. Adithan

3. Manufacturing Science by Amitabh Ghosh and Ashok Kumar Mallik.

5. OTHER SESSION

5.1 TUTORIALS : :

5.2 LABORATORY : :

5.3 PROJECT : :

6. ASSESSEMENT : :

6.1 HA : 10 6.2 QUIZZES: 10


6.4 PROJECT/ LAB :

6.5 FINAL EXAM : 50


It is anticipated that after completion of the course, a student would be in a position to understand

the concept of machining processes for machining difficult to machine materials. It will also help

student to understand the applications of such machining processes for industrial use. It will certainly

motivate our students to undertake projects to develop new processes to precisely machine intricate

shapes in difficult to machine materials.

8. EXPECTED ENROLMENT IN THE COURSE:


INTEREST :


THEORY OF ABRASIVE MACHINING

1. GENERAL

1.1 TITLE : : Theory of abrasive machining 1.2 *COURSE NUMBER: DE.ME 452.15

1.3 CREDITS :3-0-0 (9 credits)

1.4 SEMESTER OFFERED : :Odd

1.5 PRE-REQUISITES :

2. OBJECTIVE : :To teach the students about abrasive machining process, which would include its

mechanics, thermal aspects and applications.

3. COURSE TOPICS :

Unit 1 (7 Lectures)

Types of abrasives and grinding wheels, types of abrasive machining, advantages and disadvantages of

each process, application areas


Abrasive wheel geometry, designation system mechanics of abrasive machining, force and power

calculations


Determination of temperature in abrasive machining, techniques for temperature measurement, affect

of temperature during grinding, cryogenic grinding and its advantages, thermal damage


Quality control in abrasive machining, surface roughness, super-abrasive machining, surface integrity

and its assessment.

4. READINGS

4.1 TEXTBOOK : :

4.2 *REFERENCE BOOKS : :

1. Grinding Technology: Theory and Application of Machining with Abrasives ,by Stephen

Malkin, ChangshengGuo, Industrial Press Inc.

2. Principles of Modern Grinding Technology (Google eBook), by W. Brian Rowe, Elsevier

5. OTHER SESSIONS

5.1 *TUTORIALS: :

5.2 *LABORATORY: :

5.3 *PROJECT: :

6. ASSESSMENT (indicative only)

6.1 HA : : 5

6.2 QUIZZES - HA : : 5

6.3 PERIODICAL EXAMS : : 30

6.4 *PROJECT : :


7. OUTCOME OF THE COURSE: :The students will have the detailed knowledge of abrasive

machining process and would be in a position to apply the process effectively.

8. *EXPECTED ENROLLMENT FOR THE COURSE: :50

9. *DEPARTMENT OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD BE OF

INTEREST: :

10. *ANY OTHER REMARKS: :

MANUFACTURING SYSTEMS

4. GENERAL

4.1 TITLE : : Manufacturing Systems



4.4 SEMESTER- OFFERED : :Odd

5. OBJECTIVE : :

The objective of the course is to impart the basic understanding of fundamental aspects of the

manufacturing automation and in turn automated manufacturing systems like FMS/CIMS. It

obviously covers various components of manufacturing systems which includes;

NC/CNC/DNC and adaptive control in addition with automated material handling and

computer networks.

6. COURSE CONTENT :

Unit I (8 lectures)

Fundamentals of Manufacturing Automation: Basic automation principles and strategies, product/production relations, classification of automated manufacturing systems, reasons for

automation. Industrial Control Systems, sensors, actuators and other Control Systems

Components


Numerical Control (CNC), DNC, Adaptive Control


NC Part Programming, Applications of NC PLC.

Unit IV (4 lectures)

Industrial Robotics, Automated Material Transport Systems such as Conveyor Systems

Unit V (3 lectures)

AGCS, Storage Systems AS/RS, MRP.

Unit VI (6 lectures) Automated Quality Control: online/offline inspection, Automatic Identification Techniques,

GT & CAPP in Manufacturing.

Unit VII (9 lectures)

FMS, CIMS, Factory Area Network MAP/ TOP, Factories of Future, Introduction of JIT

Production Systems, Lean Manufacturing, Agile Manufacturing

7. READINGS : :

7.1 TEXT BOOKS : :

1. Automation, Production Systems & Computer Integrated Manufacturing, M.P.Groover,

Printice Hall of India (PHI), New Delhi

2. CAD/CAM-Principles & Applications, Tata Mc Graw Hill, New Delhi

3. Principles of Computer Integrated Manufacturing, S.Kant Vajpayee, Printice Hall of India

(PHI), New Delhi

4. CAD/CAM//CIM P.Radhakishnan & S.Subramannyan , New Age International Ltd., New

Delhi

REFERENCE BOOKS : :

1. CAD/CAM: Principles, Practice and Manufacturing Management, Chris Mc Mohan &

Jimmie Brown, Pearson Education Asia, UK

5. OTHER SESSION

5.1 TUTORIALS : :

5.2 LABORATORY : :

5.3 PROJECT : : 6. ASSESSEMENT : :

6.1 HA : 10

6.2 QUIZZES: 10

6.3 PERIODICAL EXAMINATION : : 15+ 15=30

6.4 PROJECT/ LAB : :



It is anticipated that after completion of the course, a student would be in a position to

understand the concept of strategic manufacturing including modern systems like FMS/CIMS.

It will also help student to understand CNC principles and CNC programming, automated

guided vehicles, robots and computer networking for manufacturing.



INTEREST : :

10. ANY OTHER REMARKS :

RAPID DESIGN & MANUFACTURING

1.GENERAL

1.1 TITLE: Rapid Design & Manufacturing

1.2 COURSE NUMBER: BE.ME 454.15

1.3 CREDITS :3-0-0(09 Credits)

1.4 SEMESTER- OFFERED: ODD

2 OBJECTIVE:

The basic objective is providing product design development process concept from concept idea phase

to CAD modeling and prototyping development. It provides foundation knowledge for completive

product manufacturing route such as Rapid prototyping, reverse engineering, Concurrent Engineering,

rapid tooling and CNC manufacturing.

3 Course Content:

Unit 1(6Lectures)

INTRODUCTION TO PRODUCT DESIGN & DEVELOPMENT: Introduction and competitive

product design & manufacturing: design issues, morphology of design, primary design phase and

design for manufacturing. Product design in RDM.

Unit 2(7Lectures)

RAPID PROTOTYPING: Definition, concept, origin, RP cycles & CAD, RP advantages &

applications. Slicing techniques. Surface finish & accuracy issues. RP data correction, maintenance,

validation, exchange & design opportunities.

Unit 3 (6Lectures)

RAP1D TOOLING: Introduction & scope of RT and Overview of processes. Rapid hard tooling.

Volume, tool life, schedule & economics and applications of RT.

Unit 4(7Lectures)

REVERSE ENGINEERING: Introduction, definitions and concepts to RE & Point cloud data & 3D

digitizing, surface re-construction using, parametric functions & polyhedron and Meshing.

Unit 5(6Lectures)

CONCURRENT ENGINEERING: Introduction and need, Essential techniques of CE, Product design,

support and management tools.

Unit 6 (7Lectures)

COMPUTER AIDED DESIGN and MANUFACTURING: Definitions & Development, data

structures and algorithms, picture transformations, basic interpolation and approximation of curves,

surfaces & solids, Graphics standards and basic of solid modeling & visual realism. Definitions of

NC/CNC/DNC/PLC/FMS. Integration using LAN/WANE/E-net and definition of virtual

manufacturing.

TEXT BOOKS:

1. Product Design and Manufacturing, Chatale A K & Gupta RC (PHI pub. New Delhi 2005.

2. Product Design by Otto & Wood (Pearson Publishers)

3. Rapid Prototyping by AmitabhaGhosh (EWP, New Delhi)

4. Software solutions for Rapid prototyping by Gibson I. (Professional Engineering Pub. Ltd.

London 2002)

REFERENCE BOOKS:

1. Proceedings of AICTE-ISTE winter school, Rapid Design & Manufacturing:

CAD/CAM/RP/RT/RE/CE (Dec. 27m 2003- Jan 6, 2004), Santosh Kumar, Deptt. of Mech. Engg.

Pub. 2004) IT BHU.

2. Computer Aided Process Planning for Rapid Prototyping, S. Pande & S. Kumar (LAP- Lambert

academic publishing, USA) 2010 (ISBN 9783 8383 8679 9)

ASSESSEMENT:

6. ASSESSMENT (indicative only)

6.1 HA : : 5

6.2 QUIZZES - HA : : 5

6.3 PERIODICAL EXAMS : : 30

6.4 *PROJECT : :


7. OUTCOME OF THE COURSE: Students will learn how to develop new products from idea level to prototype manufacturing level in a

competitive environment.

8. EXPECTED ENROLMENT IN THE COURSE: 50 1n Each Semester


INTEREST:

10. ANY OTHER REMARKS:UG level course

ROBOTICS

4. GENERAL

4.1 TITLE : Robotics

4.2 COURSE NUMBER : DE.ME 461.15


4.4 SEMESTER- OFFERED :EVEN

5. OBJECTIVE : :

The objective of the course is to impart the basic understanding of fundamental aspects of the

robotics and in turn robotized manufacturing. It obviously covers various components of

robotics which includes; trajectory planning & interpolation, DH convention, robotic sensors

and analysis of robotic work cell.

6. COURSE CONTENT :

Unit 1 ( 4 lectures)

Fundamental concepts in Robotics: Introduction, Basic Structure of Robots, Robot Anatomy, Work Volume


Robot Drive System


Precision of Robot Movement, Robot Workcell Controller, Interlocks, Robot End Effectors

Unit 4 ( 8 lectures) Robot Motion Analysis and Control: Manipulator Kinematics, Homogeneous Transformations

and Robot Kinematics. DH Convention


Sensors in Robotics: Position, Velocity, Tactile, Proximity and Range Sensors

and Machine Vision


Robot Programming and Languages, AI in Robotics

Unit 7 ( 5 lectures) Installing a Robot, Economic Analysis for Robotics. Robot Application in Manufacturing,

Social Issues

READINGS :

6.1 TEXT BOOKS :

1. Robotics for Engineers: Yorem Koren, Mc Graw Hill International, NY

2. Introduction to Robotics, S.K.Shah Tata McGraw Hill Publishing Co.Ltd. New Delhi

3. Robotic Engineering: An Integrated Approach, Richard D.Klafter, Thomas A Chmielewski &

Michael Negin, Printice Hall of India (PHI), New Delhi


1. Robotics: Control, Sensing, Vision & Intelligence, K.S.Fu, R.C.Gonzalez & C.S.G.Lee

5. OTHER SESSION

5.1 TUTORIALS : :

5.2 LABORATORY : :

5.3 PROJECT : :

6. ASSESSEMENT : :

6.1 HA : 10

6.2 QUIZZES: 10


6.4 PROJECT/ LAB :

6.5 FINAL EXAM : 50


It is anticipated that after completion of the course, a student would be in a position to

understand the concept of robotics. It will also help student to understand the basic functions of

a robot for industrial use. It will certainly motivate our students to undertake projects based on

robot design and development.



INTEREST : :


BASICS OF GENERATIVEMANUFACTURING

1.1: GENERAL

1.2 TITLE:: BASICS OF GENERATIVEMANUFACTURING

1.3 COURSE NUMBER (if known): OE.ME 455 .16

1.4 CREDITS: 11(09+02) (with 3 contact hours/week, course project , 02 units of laboratory work)

1.5 SEMESTER OFFERED: odd (VII sem) Semester, (for B. Tech)

1.6 PREREQUISITES: No formal prerequisites. Students are desired to take any basic course on

Engineering Design/ Materials Science/ manufacturing.

2. OBJECTIVES:

In this course STUDENTS will learn basics of generative (Rapid prototyping/3D Printing) and its

huge role in global product development and innovation. Students will develop to Compare traditional

versus next generation manufacturing & will have a rich knowledge of 3D printing technologies,

devices, capabilities, materials and applications. Students will learn the trade-offs between various 3D

printing processes and technologies, along with the various software tools, processes and techniques

enabling personal fabrication, such as 3D scanning. One will explore the broad range of 3D printing

applications, including biomedical &bio-manufacturing, aerospace, consumer products, and creative

artistry, to mention a few. And finally, students will learn the latest trends and opportunities in 3D

printing, including ―personal‖ 3D printing, localized services, production parts, mass customization,

and how to commercialize your ideas.

3. COURSE CONTENT: Lectures = 39

Units Course Contents No. of

Lectures

I

1. Introduction to the Basic Principles of Generative Manufacturing: advantages and

limitations of Generative Technologies AS developing new engineering systems,

identifying emerging opportunities in developing products for mass customization.

4

2. Generative Manufacturing Processes 3

3. Generative Technology (1): Extrusion, Beam Deposition 2

4. Generative Technology (2): Jetting, Sheet Lamination, Direct-Write 3

5. Generative Technology (3): Photo polymerization, Metal Technology & Processes 1

6. Generative Technology (4): Sintering, Powder Bed Fusion 1

II

7. Design/Fabrication Processes: Data Sources, Software Tools, File Formats, Model

Repair and Validation, Pre- & Post-processing, design practices for additive

manufacturing

5

8. Designing for Generative Manufacturing : Scaffolds, bio-printing, tissue and organ

engineering

4

9. Multiple Materials, Metals, polymers, ceramics, Hybrids, Composite Materials,

current and material selection &future directions

4

10. Process & Material Selection 1

III

11. Direct Digital Manufacturing and Distributed Manufacturing 2

12. Related Technologies: 3D scanning, sintering, Mold-making, Casting, Scanning,

rapid tooling (RT) ,rapid manufacturing (RM)

4

13. Applications of Generative Manufacturing: Aerospace, Automotive,

Manufacturing, Architectural Engineering, Art, Jewelry, Toys , Packaging,

Architecture, Design and Entertainment and many more

2

14. Biomedical Applications of GM: Medical, Biomedical, Dental, Bio-printing, Tissue

& Organ Engineering and many others

2

15. Future Trends and Directions in Generative Manufacturing, Business Opportunities 1

3.1 Delivery Mode

Traditional classroom instruction with student participation. On-line students participate through

MOODLE, blogs and threaded discussions. The project will consist of teamed students (who would be

teamed with classroom students) who will identify, design and build a project. Guidelines and

requirements will be provided

4. READINGS

4.1 Text Books:

Direct Write Technologies for RP Applications: Sensors, Electronics and Integrated Power

Sources, Pique, A., Chrisey, DB., Academic Press, (2002).

Rapid Prototyping, World Scientific, Chua, C K, Leong, KF., Lim CS, (2003).

Rapid Prototyping – Laser Based and Other Technologies, Venuvinod, PK., Ma, W.,

Kluwer, (2004).

Advanced Manufacturing Technologies for Medical Applications, Gibson, Wiley, (2005).

Rapid Manufacturing: An Industrial Revolution for a Digital Age: An Industrial

Revolution for the Digital Age, Hopkinson, N, Haque, R., and Dickens,P., , Wiley, (2005).

Virtual and Rapid Manufacturing: Advanced Research in Virtual and Rapid Prototyping,

Bartolo, P J (editor), Taylor and Francis, (2007).

Bourell, Leu, and Rosen, Roadmap for Additive Manufacturing, NSF Workshop

report, (2009).

Understanding Additive Manufacturing, Andreas Gebhardt, Hanser Publ. , (2011).

Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing,

2nd Ed. Ian Gibson, David W. Rosen, Brent Stucker. , Springer Publ. (2015).

4.2 REFERENCE BOOKS:

Laser Additive Manufacturing of High-Performance Materials, Dongdong Gu, Springer

Publ. (2014).

5. OTHER SESSIONS

5.1 TUTORIALS:: NIL

1. Two Demonstration of Generative Manufacturing using FDM technology

2. Demonstration of Generative Manufacturing using Powder technology

3. Simulation of Generative Manufacturing using 3D printing software

4. Making of Simple CAD Model and study of export file formats for GM

5. Making of Functional CAD Model and study of export file formats for

GM

6. Making of Assembly CAD Model and study of lay direction effects for

GM

7. Study of Model Tolerance assignment for GM

8. Making of 3D printed Model using Clay

5.2 *LABORATORY:

5.3 PROJECT: NIL

6. ASSESSMENT (indicative only): YES

6.1 HA: [05 marks]

6.2 QUIZZES-HA: [NIL]

6.3 PERIODICAL EXAMS: [30 marks]

6.4 *PROJECT: mini type, within course[15 marks]

6.5 FINAL EXAM: [50 Marks]


For the students of all branches such a course will be highly useful as the new technology is

evolving with newer areas.

8. *EXPECTED ENROLLMENT FOR THE COURSE: 60 or more


INTEREST:

Ceramic, Civil, Electronics, Electrical, Material science, Bio-Medical etc.

10. *ANY OTHER REMARKS:

Considering the increasing number of career opportunities available for the students with the

Additive Manufacturing industry and the amount of on-going research activity in Additive

Manufacturing , it would be good to have a course on BASICS OFGENERATIVE

MANUFACTURING at IIT (BHU), a premier institute of higher learning .

My doctoral work (at IIT Kanpur), R&D & Industrial experiences and published work in

reputed international research journals. helped me to understand the intricacies of GM and put

the theory and practice in perspective.

*List of Experiments for: BASICS OFGENERATIVE MANUFACTURING

ADDITIVE MANUFACTURING

1: GENERAL

1.7 TITLE:: ADDITIVE MANUFACTURING

1.8 COURSE NUMBER (if known): DE.ME 557.16

1.9 CREDITS: 09 (with 3 contact hours/week, course project , no laboratory Lab)

1.10 SEMESTER OFFERED:: odd Semester, 2016 (for B. Tech/IDD 7th/IX

semester & MTECH/PhD Ist Sem)

1.11 PREREQUISITES: No formal prerequisites. Students are desired to take ANY BASIC

COURSE ON

Engineering Design/ Materials Science/ manufacturing.

2. OBJECTIVES:

In this course STUDENTS will learn the importance of additive manufacturing (3D Printing/

Rapid Prototyping/ Green Manufacturing) and its huge role in global product development and

innovation. Students will develop to Compare traditional versus next generation manufacturing

& will have a rich knowledge of 3D printing technologies, devices, capabilities, materials and

applications. Students will learn the trade-offs between various 3D printing processes and

technologies, along with the various software tools, processes and techniques enabling personal

fabrication, such as 3D scanning. One will explore the broad range of 3D printing applications,

including biomedical & bio-manufacturing, aerospace, consumer products, and creative

artistry, to mention a few. And finally, students will learn the latest trends and opportunities in

3D printing, including ―personal‖ 3D printing, localized services, production parts, mass

customization, and how to commercialize your ideas.

4. COURSE CONTENT: Lectures = 39

Units Course Contents No. of

Lectures

I

1. Introduction to the Basic Principles of Additive

Manufacturing/ digital Manufacturing: advantages and

limitations of AM technologies AS developing new

engineering systems, identifying emerging

opportunities in developing products for mass

customization.

4

2. Additive Manufacturing Processes 2

3. AM Technology (1): Extrusion, Beam Deposition

2

4. AM Technology (2): Jetting, Sheet Lamination, Direct-

Write

2

5. AM Technology (3): Photo polymerization, Metal

Technology & Processes

1

1

6. AM Technology (4): Sintering, Powder Bed Fusion

II

7. Design/Fabrication Processes: Data Sources, Software

Tools, File Formats, Model Repair and Validation, Pre-

& Post-processing, design practices for additive

manufacturing

5

8. Designing for Additive Manufacturing : Scaffolds, bio-

printing, tissue and organ engineering

4

9. Multiple Materials, Metals, polymers, ceramics,

Hybrids, Composite Materials, current and material

selection &future directions

4

10. Process & Material Selection 1

III

11. Direct Digital Manufacturing and Distributed

Manufacturing

2

12. Related Technologies: 3D scanning, sintering, Mold-

making, Casting, Scanning, rapid tooling (RT) ,rapid

manufacturing (RM)

4

13. Applications of AM: Aerospace, Automotive,

Manufacturing, Architectural Engineering, Art,

Jewelry, Toys , Packaging, Architecture, Design and

Entertainment and many more

2

14. Biomedical Applications of AM: Medical, Biomedical,

Dental, Bio-printing, Tissue & Organ Engineering and

many others

2

15. Intellectual Property, Product Development, 1

Commercialization

16. Future Trends and Directions in Additive

Manufacturing, Business Opportunities

1

17. Standards and standardization in 3D Printing and the

Future of Manufacturing

1

3.1 Delivery Mode

Traditional classroom instruction with student participation. On-line students participate through

MOODLE, blogs and threaded discussions. Project (if applicable): The project will consist of

teamed students (optional for on-line students, who would be teamed with classroom students)

who will identify, design and build a project. Guidelines and requirements will be provided

4. READINGS

4.3 Text Books:

Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing, 2nd

Ed. Ian Gibson, David W. Rosen, Brent Stucker. , Springer Publ. (2015).

Rapid Manufacturing: An Industrial Revolution for a Digital Age: An Industrial Revolution for the

Digital Age, Hopkinson, N, Haque, R., and Dickens,P., , Wiley, (2005).

Virtual and Rapid Manufacturing: Advanced Research in Virtual and Rapid Prototyping, Bartolo,

P J (editor), Taylor and Francis, (2007).

Rapid Prototyping, World Scientific, Chua, C K, Leong, KF., Lim CS, (2003).

Direct Write Technologies for RP Applications: Sensors, Electronics and Integrated Power

Sources, Pique, A., Chrisey, DB., Academic Press, (2002).

Rapid Prototyping – Laser Based and Other Technologies, Venuvinod, PK., Ma, W., Kluwer,

(2004).

Understanding Additive Manufacturing, Andreas Gebhardt, Hanser Publ. , (2011).

Bourell, Leu, and Rosen, Roadmap for Additive Manufacturing, NSF Workshop report, (2009).

Advanced Manufacturing Technologies for Medical Applications, Gibson, Wiley, (2005).

4.4 REFERENCE BOOKS:

Laser Additive Manufacturing of High-Performance Materials, Dongdong Gu, Springer Publ.

(2014).

5. OTHER

SESSIONS

*TUTORIALS:: NIL

*LABORATORY: DEMONSTRATION WILL BE SHOWN

*PROJECT: Yes

8. ASSESSMENT (indicative only): YES 6.1 HA:: [xx% GRADE]

6.2 QUIZZES-HA:: [xx% GRADE]

6.3 PERIODICAL EXAMS:: [xx% GRADE]

6.4 *PROJECT:: [xx% GRADE]

6.5 FINAL EXAM:: [xx% GRADE]


For the students of all branches such a course will be highly useful as the new technology is

evolving with newer areas.

9. *EXPECTED ENROLLMENT FOR THE COURSE:: 60

Operations Research

1. GENERAL

1.1 TITLE::Operations Research

1.2 *COURSE NUMBER (if known)::BE.ME485.16

1.3 CREDITS::3-0-0(9)

1.4 SEMESTER-OFFERED::VI(EVEN)

1.5 PRE-REQUISITES::

2. OBJECTIVE::The objective is to learn quantitative techniques for decision making

3. COURSE TOPICS::

Unit I: Linear Programming

Primal and dual problems, Sensitivity analysis, Transportation and assignment problems,

Introduction to multicriteria optimization and goal programming

Unit II: Dynamic Programming: Multistage decision problem and their solution, principle of

Optimality.

Unit III: Decision Theory: Decision under various conditions

Game Theory: Minimax and Maximin strategies, Application of linear programming

Unit IV: Markov Analysis: First order Markov processes and their analysis.

Simulation: Monte Carlo simulation,Generation of Random numbers and random

variates

Unit V: Queueing Models: Simple systems, Cost considerations.

4. READINGS

4.1 TEXT BOOK::

Operations Research – An Introduction by Hamdy A. Taha , Macmillan Publishing Co. Inc.


1. Quantitative analysis for management by Render B., Stair R. M., Hanna M. E.,

PearsonEducation

2. Quantitative methods forBusiness by Anderson, Sweeney and Williams;

ThomsonPublications

3. Operation Research by A. N. Natrajan,P. Balasubharmani, A Tamilarasi, Pearsoneducation.

5. OTHER SESSIONS

5.1 *TUTORIALS::No

5.2 *LABORATORY::No

5.3 *PROJECT::Yes


6.1 HA:: [5% GRADE]






Familiarization of quantitative techniques for modelling real life problems of operations

management and the way to optimize these problems



OF INTEREST:: N.A.


DATED:: PROPOSER SIGNATURE::

PROPOSER NAME::PROF A.K. AGRAWAL, PROF S.K

SHARMA, DR P BHARDWAJ, DR. C. SAMUEL

NAME OF DEPT/SCHOOL:: Dept. of Mechanical Engineering

INDUSTRIAL MANAGEMENT

1. GENERAL

1.1 TITLE:: Industrial Management

1.2 *COURSE NUMBER (if known):: BE.ME 472.15


1.4 SEMESTER-OFFERED:: V to IX

1.5 PRE-REQUISITES:: No

2. OBJECTIVE::

Industrial Management is a course in which one can gain knowledge of Management systems,

Production & Operations management &Corporate services. It will expose the student to

Financial & cost control, Personnel & Management systems, Product & process design,

Method standards & Production control; Comprehensive planning, Policies & procedures, and

analysis.

3. COURSE TOPICS::

Unit I: Introduction to Management (6Lectures) Functions, Environment, Role, Skills, Levels of Decision Making, Historical Perspective.

Types of Organizations

Unit II: FinancialManagement(8Lectures)

Costs- Types, Elements, Allocation of Overheads, Product and Process Costing

Managerial Economics- Time Value of Money, NPV, IRR, Payback Periods

Financial Management- Balance Sheet, Income Statements,

Unit III: Project Management (4Lectures)

PERT and CPM

Unit IV: Facility Planning (4Lectures)

Plant Location and Layout

Unit V: Quality Control (6Lectures Definition of Quality, Cost of Quality, SPC, Acceptance Sampling , TQM Concepts

Unit VI: Inventory Management and Production Planning &Control (6Lectures)

Unit VII: Job Design and Work measurement(5Lectures)

4. READINGS

4.1 TEXT BOOK:: Operations Managementby Jay Heizer& Barry Render, Prentice Hall


1. The Management Challenge by James M. Higgins, MacMillan Publishers

2. Principles of Management by Harold Koontz, Cyril O‘Donnell

5. OTHER SESSIONS

5.1 *TUTORIALS:: No

5.2 *LABORATORY:: No

5.3 *PROJECT:: Yes


6.1 HA:: [5% GRADE]





7. OUTCOME OF THE COURSE:: Familiarize with Industrial Management concepts.



OF INTEREST::All Departments

10. *ANY OTHER REMARKS:: NO

PRODUCTION SYSTEM DESIGN

--------------------------------------------------------------------------------------------------------

1. GENERAL

1.1 TITLE:: PRODUCTION SYSTEM DESIGN

1.2 *COURSE NUMBER (if known):: M.MIM 477.15

1.3 CREDITS:: 11

1.4 SEMESTER-OFFERED:: ODD/EVEN


2. OBJECTIVE:: TO GIVE INFORMATION AND KNOWLEDGE TO THE STUDENTS

TO UNDERSTAND THE BASICS OF THE PRODUCTION SYSTEMS.

3. COURSE TOPICS::

PRODUCTION SYSTEM- DEFINITION, SCOPE AND BOUNDARIES.

LONG TERM FORECASTING-QUANTITATIVE AND QUALITATIVE

TECHNIQUES.

POLICY DECISIONS- GOALS, STRATEGIES, TACTICS AND OPERATIONAL

DECISIONS

PRODUCT DECISIONS-PRODUCT DEVELOPMENT PHASES, INDUSTRIAL

DESIGN, RELIABILITY ALLOCATION.

PROCESS DECISIONS-ASSEMBLY AND OPERATIONS PROCESS CHARTS, WORK

DESIGN, JOB DESIGN, HUMAN FACTORS AND ERGONOMICS

PLANT DECISION-PLANT LOCATION AND PLANT LAYOUT, TYPES OF LAYOUT

AND ANALYSIS, FACILITIES PLANNING MODELS

MATERIALS HANDLING SYSTEM-TYPES, ANALYSIS AND MODELS.

GROUP TECHNOLOGY-CODING AND CLASSIFICATION, CELL FORMATION

TECHNIQUES, GT LAYOUT, ASSEMBLY AND PRODUCTION LINE BLANCHINGMETHODS

OF LINE BALANCING, MULTIPLE PRODUCTS AND MIXED LINE

BALANCING.

PROJECT MANAGEMENT- CPM AND PERT, RESOURCE ALLOCATION AND

SCHEDULING.

4. READINGS

4.1 TEXT BOOK::

RONALD G. ASKIN, MODELING AND ANALYSIS OF MANUFACTURING

SYSTEMS,

JOHN WILEY AND SONS PUBLICATON

JEROME D. WEIST, A MANAGEMENT GUIDE TO PERT/CPM, PHI PUBLICATION

L. SRINATH, CONCEPTS IN RELIABILITY, EAST-WEST PRESS PVT. LTD.

RALPH M. BARENS, MOTION AND TIME STUDY DESIGN AND MEASUREMENT

OF WORK, JOHN WILEY AND SONS PUBLICATON


L. SRINATH, RELIABILITY ENGINEERING, MCGRAW TATA-MCGRAW-HILL

PUBLICATION

5. OTHER SESSIONS

5.1 *TUTORIALS::

5.2 *LABORATORY::

5.3 *PROJECT::


6.1 HA:: [xx% GRADE] 5%

6.2 QUIZZES-HA:: [xx% GRADE] 5%

6.3 PERIODICAL EXAMS:: [xx% GRADE] 30%

6.4 *PROJECT:: [xx% GRADE]

6.5 FINAL EXAM:: [xx% GRADE] 60%


8. *EXPECTED ENROLMENT FOR THE COURSE::

9. *DEPARTMENTS OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD

BE OF INTEREST::


QUANTITATIVE METHODS FOR DECISION MAKING

1. GENERAL

1.1 TITLE::Quantitative Methods for Decision Making

1.2 *COURSE NUMBER (if known)::M.MIM 578.15

1.3 CREDITS::3-0-0(9)

1.4 SEMESTER-OFFERED::VI onwards


2. OBJECTIVE::The objectives are as under

Use optimization techniques in business decision making.

Develop skills in structuring and analyzing business problems statistically.

Formulate models and solutions to common business decision problems.

Learning software for optimization issues

3. COURSE TOPICS::

Unit I: Concept of Decision Making(9Lectures)

Decision Making Scenarios in Business and Industry; Formulation of Class of Problems as

Linear Programming Problems;Simplex Algorithm, Duality, Sensitivity analysis, Perturbation

Analysis

Unit II: Special Cases of LPP (5Lectures)

Distribution (Transportation & Transshipment) and Matching (assignment) models; Integer

Programming

Unit III: Decision Theory, Game Theory (8Lectures),

Unit IV: Queuing theory, Markov process (12Lectures)

Unit V: Discrete Event Digital Simulation (5Lectures)

4. READINGS

4.1 TEXT BOOK::

Operations Research – An Introduction by Hamdy A. Taha , Macmillan Publishing Co. Inc.


1. Quantitative analysis for management by Render B., Stair R. M., Hanna M. E., Pearson

Education

2. Quantitative methods for Business by Anderson, Sweeney and Williams; Thomson

Publications

3. Operation Research by A. N. Natrajan,P. Balasubharmani, A Tamilarasi, Pearson education.

5. OTHER SESSIONS

5.1 *TUTORIALS::No

5.2 *LABORATORY::No

5.3 *PROJECT::Yes


6.1 HA:: [5% GRADE]






Familiarization of quantitative techniques for modeling real life problems of operations

management and the way to optimize these problems



OF INTEREST:: N.A.



PROPOSER NAME::PROF A.K. AGRAWAL, PROF S.K

SHARMA, DR P BHARDWAJ, DR. C. SAMUEL


FORECASTING AND TIME SERIES ANALYSIS

1. GENERAL

1.1 TITLE:: Forecasting and Time Series Analysis

1.2 *COURSE NUMBER (if known):: BE.ME 483.15

1.3 CREDITS::3-0-0( 9credit)

1.4 SEMESTER-OFFERED:: VI(EVEN)

1.5 PRE-REQUISITES:: Not required

2. OBJECTIVE::

Forecasting and Time series analysis and its applications have become increasingly important

in various fields of research, such as business, economics, engineering, medicine,

environometrics, social sciences, politics, and others. It focuses on different methods of

forecasting demand (particularly) for modeling and simulation purposes. Also, students with

the proper concepts will have competitive advantage.

3. COURSE TOPICS::

Unit I: Forecasting markets (7Lectures)

Time series analysis, Causal relationships, Regression models, Forecasting error,

Seasonality, Exponential smoothing, Moving average, Tracking signal

Unit II: Simple And Multi Regression Models (8Lectures)

Theory and methods of modeling dynamic relationship among several interrelated times

series data,

Unit III: Box Jenkins Model for ARIMA (8Lectures)

Time series, stationary, seasonality, inheritability, autoregressive, memory function,

autoregressive and moving average models

Unit IV: Advanced Forecasting models (8Lectures)

Multivariate time series, analysis of leading and lagging relationship, ARIMA models,

Unit V: Qualitative Forecasting (8Lectures)

Technological forecasting, Management System Dynamics as a forecasting and policy

evolution methodology

4. READINGS

4.1 TEXT BOOK::

Forecasting :Methods and applications by Makridakis, Wheelwright & Hyndman, Wiley

publishers


The Analysis of Time Series: An Introduction by Chris Chatfield

Introduction to Time Series and forecasting: Brockwell & Davis, Springer Publication

5. OTHER SESSIONS

5.1 *TUTORIALS::No

5.2 *LABORATORY::No

5.3 *PROJECT::Yes


6.1 HA:: [5% GRADE]


http://www.amazon.in/s/ref%3Ddp_byline_sr_book_1?ie=UTF8&field-author=Chris%2BChatfield&search-alias=stripbooks




7. OUTCOME OF THE COURSE:: Students will learn methods of forecasting that suits to

present requirements of industry.

8. *EXPECTED ENROLMENT FOR THE COURSE::


OF INTEREST::



PROPOSER NAME::DR P BHARDWAJ, PROF A.K.

AGRAWAL, PROF S.K SHARMA, DR. C. SAMUEL


1. GENERAL

OPTIMIZATION FOR ENGINEERING DESIGN

1.1. TITLE : : Optimization in engineering design 1.2. COURSE NUMBER : : BE.ME 511.15

1.3. CREDITS : : 3-0-0 (09Credits)

1.4. SEMESTER- OFFERED : VII

1.5. PREREQUSITE: elementary knowledge of matrix algebra, calculus, and statistics

1.6. Syllabus Committee MemberDr. Rajesh Kumar, Dr. Nilanjan Mallik, Dr S.K.Panda

2. OBJECTIVE:

Primary objective of the course is to introduce the different optimization algorithms so that

designer is able to select the best design. The course will also deal the stochastic nature of

variables so that designs are reliable. To use the optimization algorithms, the mathematical

formulation of the design problem is necessary which will be discussed in the course. The

optimization algorithms to be discussed are broadly classified as single/multi variable,

linear/nonlinear, continuous/discrete. Non-traditional Genetic algorithm will also be discussed.

3. COURSE CONTENT


Introduction, Mathematical formulation of the problem


Classical optimization techniques Single variable optimization, multivariable optimization with and without constraints


Linear programming Simplex method, revised simplex method, postoptimal analysis


Nonlinear programming elimination method, gradient based methods; direct search, indirect search; generalized

reduced gradient (GRG) method, engineering design examples


Geometric programming; engineering design examples


Dynamic programming; engineering design examples


Genetic algorithm

UNIT VIII: (6 Lectures) General reliability model, statistical algebra, Stochastic programming, engineering

design examples

4. READINGS :

4.1. TEXT BOOKS : :

4.1.1. Title: Engineering optimization: Theory and practice, Author: S. S. Rao

4.1.2. Title: Optimization for Engineering Design Algorithms and Examples, Author:

Kalyanmoy Deb

4.1.3. Title: Introductory Probability and Statistical Applications, Author: Paul L

Meyer

4.1.4. Title: Applied Statistics and Probability for Engineers, Authors: Douglas C

Montgomery, George C Runger

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.3 PROJECT: No

6. ASSESSEMENT :

6.1 HA : 5 %






Knowledge to select the best design which is reliable also.


9. DEPARTMENTS OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD BE

OF INTEREST :


COMPUTER AIDED DESIGN

1. GENERAL

1.1. TITLE:: Computer Aided Design


1.3. CREDITS:: 3-0-0(09 credits)



1.6. Syllabus Committee Member:Dr.Sandeep Kumar, Dr. S.K.Panda

2. OBJECTIVE This course provides the students with the needed material for understanding the principles of

Computer Aided Design. The course is focused on mathematical formulation and implementation of

curves, surfaces and solids in the design of mechanical components. This course will help in

improving the students‘ abilities in the use of various techniques used in the representation of

mechanical parts. Students will write computer programs in C++, OpenGL and MATLAB. They will

also practice on Solid Works and CATIA.


UNIT I: (7 Lectures) Transformations: 2D and 3D transformation, homogeneous coordinates, combined

transformations, affine transformation, orthographic and perspective projections.


Plane curves: Introduction to conics - Implicit, explicit, parametric forms


Space Curves: Hermite, Bezier curves - Control polygons and Bernstein basis, DeCasteljau

algorithm, continuity of curves (Cn

and Gn

continuity). B-Spline curves - periodic, open and

non-uniform knot vectors and corresponding curves, Rational B-splines, NURBS, Subdivision,

and Reparameterization.


Surfaces: Surface of revolution, sweep surface, bilinear surface, bi-cubic surface,

Bezier surface, B-spline surface.


Solid Modeling: Intoduction to Solid Modeling - Topology of surfaces, Euler and

modified form of equations, - quadtree, octree, halfspace, boundary representation (B-Rep),

constructive solid geometry (CSG) Boolean operations in 2D - set membership classification,

union, difference and intersection.

4. READINGS

4.1. TEXTBOOK

4.1.1. Mathematical Elements of Computer Graphics, David F. Rogers and Alan J Adams 4.1.2. Computer Aided Engineering Design, A. Saxena and B. Sahay

4.1.3. Geometric Modeling, Michael E. Mortenson

4.1.4. CAD/ CAM, I. Zeid

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.4 PROJECT: No

6. ASSESSEMENT :

6.1HA : 5 %




6.5 FINAL EXAM: 60

7. OUTCOME OF THE COURSE By completing this module the student should be able to understand the basic concepts in CAD.

They will be able to write computer programs and use them in Mechanical Engineering Design



INTEREST :


THEORY OF ELASTICITY

1. GENERAL

1.1 TITLE:: Theory Of Elasticity

1.2 COURSE NUMBER::DE.ME 513.15

1.3 CREDITS:: 3-0-0 Credits 9

1.4 SEMESTER OFFERED:: VII

1.5 PREREQUISITES:: Strength of Materials, Advanced Mechanics of Solids

1.6 Syllabus Committee Members: Prof J P Dwivedi (Convener), Prof V P Singh, Dr R K

Gautam.

2. OBJECTIVE: Theory of elasticity has found considerable application in solution of engineering

problems. In many cases the elementary methods of strength of materials are inadequate to furnish the

satisfactory information regarding stress distribution in engineering structures. The elementary theory

is insufficient to give information regarding local stress near the loads and near the supports of beams.

The stresses in rollers and in the balls of bearings can be found only by using the methods of the

theory of elasticity. Therefore, the theory of elasticity is successfully applied in the solution of many

important engineering problems.

3. COURSE CONTENT


Three dimensional Stress strain analysis. Stress-strain relations and general equations of

elasticity. Plain stress and plain strain. Compatibility equation and stress function.

UNIT II: (6 Lectures) Two-dimensional problems in rectangular coordinates.


Two-dimensional problems in polar coordinates.


Torsion of bars of various cross-sections: Membrane analogy, Energy principles and

variational methods, complex variable techniques.


Axisymmetric stress distribution problems. Rotating disk as a three dimensional

problem.

UNIT VI: (5 Lectures) Propagation of elastic waves in bars, longitudinal impact of bars and beams under

impulsive loading.

4. TEXTBOOKS

4.1.1. Theory of Elasticity, by Timoshenko & Goodeer

4.1.2. Theory of Elasticity, by Aatanakovick & Guran

4.1.3. Elasticity, by Chou & Pagano

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.5 PROJECT: No

6. ASSESSEMENT :

6.1 HA : 5 %




6.5 FINAL EXAM: 60

7. OUTCOME OF THE COURSE The knowledge of theory of elasticity will be helpful to analyze the theoretical problems in

field of machine design. The students are to perform their dissertation work where knowledge of this

course is necessary. Students appreciate this course as an advanced version of solid mechanics.

8.EXPECTED ENROLMENT IN THE COURSE: 30

9.DEPARTMENTS OTHER THAN YOUR OWN TO WHICH THIS COURSE WOULD BE OF

INTEREST :


THEORY OF VIBRATIONS

1. GENERAL

1.1 TITLE:: THEORY OF VIBRATIONS

1.2 COURSE NUMBER:: DE.ME 514.15

1.3 CREDITS:: 3-0-0(09 credits)

1.4 SEMESTER OFFERED:: VII

1.5 PREREQUISITES:: Vibrations (UG), Strength of Materials and mathematics

1.6 Syllabus Committee Members: Prof VP Singh and Prof KS Tripathi.

2. OBJECTIVE:

The objectives of the course are to establish a sense of engineering reality, to provide

adequate basic theory, and to generalize these concepts for wider applications. The focus of the

course is on the engineering significance of the physical quantities, with mathematical structure

providing a supporting role.

3. COURSE CONTENT:


Single and multidegree freedom system with and without damping.


Semidefinite systems, orthogonality of modes and expansion theorem.


Methods for finding natural frequencies. Rayleigh‘s quotient.


Relation between continuous and discrete models, Comparison of continuous versus

discrete models.

UNIT V: (10 Lectures) Transverse vibration of string, longitudinal and lateral vibration of beams, torsional

vibration of shaft or rod. vibration of membrane. Rayleigh‘s quotient, properties of Rayleigh‘s

quotient.


Lagrange‘s equation of motion. Rayleigh‘s energy method, Rayleigh-Ritze method,

Assumed-mode method, Galerkin‘s and collocation methods.

4. TEXTBOOKS 4.1.1. Mechanical vibrations by F. S.Tse, I. E. Morse, R. T. Hinkle.

4.1.2. Elements of vibration analysis by L. Meirovitch.

4.1.3. Theory of vibration with application by W T Thomson.

4.1.4. Analytical methods in vibration by L. Meirovitch.

4.1.5. Mechanical vibration by S S Rao.

5. OTHER SESSION

5.1 TUTORIALS: No

5.2 LABORATORY: No

5.6 PROJECT: No

6. ASSESSEMENT :

6.1 HA : 5 %




6.5 FINAL EXAM: 60

7. OUTCOME OF THE COURSE The course content has sufficient material for a one year-sequence at the senior level. The

material covered will give the student a good background for more advanced studies



INTEREST :


ADVANCED COMPOSITE MATERIALS

9. GENERAL

9.1. TITLE:: Advanced Composite Materials 9.2. COURSE NUMBER:: DE.ME.515.15

9.3. CREDITS:: 3-0-0(09 credits)

9.4. SEMESTER -OFFERED:: VII(ODD)


9.6. Syllabus Committee Member: Dr S.K.Panda, V.K.Srivastava

10. OBJECTIVE

The word composite means consiting of two or more distinct parts. Thus a materials having

two or more distinct constuent materials or phases may be considered composite materials. The

microstructral behaviour of composite materials is appeared in the form of anistropic and

nonhomogenous. Therefore, it is very essential to know mechanics of composite materials. The

main objectove of this course is to explore the advances in composite materials for the application

in aerospace and automotive industries.

11. COURSE CONTENT

Unit-I: (10 Lecture) Fibers and matrices, Various composites, Fiber-matrix interface properties, Uni-directional

laminates, Cross- plied laminates, Multi-directional laminates, Various geometrical aspects of

laminates.

Unints-2: (5 Lecture)

Elastic properties of uni-directional lamina, Random long fiber lamina, Short fiber composites,

Stress-strain distribution at fibre ends, Thermal stresses and curing stresses.

Units-3: (10 Lecture)

Laminate theory, Strength of uni-directional laminate, Various modes of failures, Edge effect

in angle ply laminates, Strength of short fiber composites.

Units-4: (10 Lecture)

Fatigue, Notch sensitivity and fracture energy of composites, Failure modes of fiber

composites, Energy, absorbing mechanism of fiber composites, Property degradation due to

various environmental condition, Manufacturing techniques of composites, Current and potential

applications of composites.

12. READINGS

12.1. TEXTBOOK

Documents

UG Course Structure for Mechanical Engineering (2016- 2017) · 2018. 4. 12. · UG Course Structure for Mechanical Engineering (2016-2017) UG -CRC Code Course Code Course Name L ±