BACHELOR OF TECHNOLOGY (B.Tech.) in ... - NIT Puducherry

BACHELOR OF TECHNOLOGY

(B.Tech.)

in

MECHANICAL ENGINEERING

CURRICULUM (For students admitted from the academic year 2019 - 2020)

DEPARTMENT OF MECHANICAL ENGINEERING

NATIONAL INSTITUTE OF TECHNOLOGY PUDUCHERRY

KARAIKAL – 609 609, INDIA.

Page | 1

Curriculum for B.Tech. in Mechanical Engineering

(Eight Semesters)

The total credits required for completing the B.Tech. Programme in Mechanical Engineering is 169

SEMESTER-I

Code Course Title L T P C

HM141 Communicative English 2 0 2 3

MA141 Calculus 3 1 0 4

PH141 Physics for Mechanical Engineers 3 0 0 3

CH141 Chemistry for Mechanical Engineers 3 0 0 3

EE141 Basic Electrical and Electronics Engineering 3 0 0 3

ME101 Engineering Graphics 1 0 4 3

PH143 Physics Laboratory 0 0 4 2

CH143 Chemistry Laboratory 0 0 4 2

Total Credits 23

SEMESTER-II


HM142 Practical English 2 0 2 3

MA142 Complex Variables and Transforms 3 0 0 3

ME102 Engineering Mechanics 3 0 0 3

CS142 Fundamentals of Computers and Programming 3 0 0 3

ME104 Energy, Environment, Lifesciences and Agriculture 3 0 0 3

ME106 Manufacturing Processes 3 0 0 3

CS144 Basic Programming Laboratory 0 0 4 2

ME108 Basic Workshop Practice 0 0 4 2

Total Credits 22

SEMESTER-III


MA241 Numerical Methods 3 0 0 3

ME201 Engineering Thermodynamics 3 0 0 3

ME203 Strength of Materials 3 0 0 3

ME205 Kinematics of Machinery 3 0 0 3

Page | 2

ME207 Engineering Metallurgy 3 0 0 3

ME209 Machining Processes 3 0 0 3

ME211 Material Testing Laboratory 0 0 4 2

ME213 Material Characterization Laboratory 0 0 4 2

ME215 Manufacturing Processes Laboratory 0 0 4 2

Total Credits 24

SEMESTER-IV


MA242 Probability and Statistics 3 0 0 3

ME202 Heat and Mass Transfer 3 0 0 3

ME204 Dynamics of Machinery 3 0 0 3

ME206 Fluid Mechanics and Machinery 3 0 0 3

ME208 Machine Drawing 1 0 4 3

ME210 Automobile Engineering 3 0 0 3

ME212 Dynamics Laboratory 0 0 4 2

ME214 Fluid Mechanics and Machinery Laboratory 0 0 4 2

Total Credits 22

SEMESTER-V


ME301 Engineering Measurements 3 0 0 3

ME303 Thermal Engineering 3 0 0 3

ME305 Design of Machine Elements 3 0 0 3

ME307 Computer Aided Design 3 0 0 3

ME309 Finite Element Analysis 3 0 0 3

Open Elective – I 3 0 0 3

ME311 Measurements Laboratory 0 0 4 2

ME313 Thermal Engineering Laboratory 0 0 4 2

ME315 CAD Laboratory 0 0 4 2

Total Credits 24

Page | 3

SEMESTER-VI


ME302 Industrial Engineering and Operations Research 3 0 0 3

ME304 Energy Engineering 3 0 0 3

ME306 Computational Fluid Dynamics 3 0 0 3

ME308 Design of Transmission Elements 3 0 0 3

Elective 1 3 0 0 3

Open Elective 2 3 0 0 3

ME310 Energy Laboratory 0 0 4 2

ME312 Simulation Laboratory 0 0 4 2

Total Credits 22

SEMESTER-VII


HM441 Industrial Economics and Management 2 0 0 2

HM443 Professional Ethics and Indian Constitution 0 0 0 0

Elective 2 3 0 0 3

Elective 3 3 0 0 3

Elective 4 3 0 0 3

Elective 5 3 0 0 3

Open Elective 3 3 0 0 3

ME491 Project Phase I 0 0 6 3

Total Credits 20

SEMESTER-VIII


Elective 6 3 0 0 3

Elective 7 3 0 0 3

ME492 Project Phase II 0 0 15 6

Total Credits 12

Semester I II III IV V VI VII VIII Total

Credits

Credits 23 22 24 22 24 22 20 12 169

Page | 4

LIST OF ELECTIVES

SEMESTER V

Open Elective-I

CODE COURSE OF STUDY L T P C ME361 Hybrid Vehicles – Solar and Fuel Cells 3 0 0 3 ME362 Strategic Quality Management 3 0 0 3

SEMESTER VI

Elective – I

CODE COURSE OF STUDY L T P C ME321 Advanced Manufacturing Processes 3 0 0 3 ME322 Computer Integrated Manufacturing 3 0 0 3 ME323 Design for Manufacture and Assembly 3 0 0 3 ME324 Micro and Nano Manufacturing 3 0 0 3

Open Elective-II

CODE COURSE OF STUDY L T P C ME363 Renewable Energy 3 0 0 3 ME364 3D Printing 3 0 0 3

SEMESTER VII

Elective – II

CODE COURSE OF STUDY L T P C ME421 Human Factors Engineering 3 0 0 3 ME422 Lean and Agile Manufacturing 3 0 0 3 ME423 Supply Chain Management 3 0 0 3

Elective – III

CODE COURSE OF STUDY L T P C ME424 Mechanics of Composites 3 0 0 3 ME425 Tribology 3 0 0 3 ME426 Fatigue, Fracture and Failure Analysis 3 0 0 3 ME427 Advanced Material Characterization 3 0 0 3

Elective – IV

CODE COURSE OF STUDY L T P C ME428 Refrigeration and Air Conditioning 3 0 0 3 ME429 IC Engines 3 0 0 3 ME430 Cryogenics 3 0 0 3 ME431 Gas Dynamics and Jet Propulsion 3 0 0 3

Page | 5

ME432 Pressure Vessel Design 3 0 0 3 ME433 Turbomachines 3 0 0 3

Elective – V

CODE COURSE OF STUDY L T P C ME434 Energy Management and Auditing 3 0 0 3 ME435 Solar Power Engineering 3 0 0 3 ME436 Direct Energy Conversion Systems 3 0 0 3 ME437 Nuclear Power Engineering 3 0 0 3 ME438 Fuel Cell Technology 3 0 0 3 ME439 Bio Fuels 3 0 0 3 ME440 Petroleum Engineering 3 0 0 3

Open Elective-III

CODE COURSE OF STUDY L T P C ME461 Industrial Safety Engineering 3 0 0 3 ME462 Mechatronics 3 0 0 3 ME463 Energy from Waste 3 0 0 3

SEMESTER VIII

Elective-VI

CODE COURSE OF STUDY L T P C ME441 Digital Manufacturing 3 0 0 3 ME442 Robotics and Automation 3 0 0 3 ME443 Product Design 3 0 0 3 ME444 Additive Manufacturing 3 0 0 3 ME445 Micro Fluidics 3 0 0 3 ME446 Introduction to Turbulence 3 0 0 3 ME447 Bio Fluid mechanics 3 0 0 3 ME448 Analytical methods for engineering applications 3 0 0 3

Elective-VII

CODE COURSE OF STUDY L T P C ME449 Instrumentation & Control Engineering 3 0 0 3 ME450 Power Plant Engineering 3 0 0 3 ME451 Automotive Fuels and Pollution Control 3 0 0 3 ME452 Fundamentals of Combustion 3 0 0 3 ME453 Advanced Heat and Mass Transfer 3 0 0 3

BACHELOR OF TECHNOLOGY

(B.Tech.)

in

MECHANICAL ENGINEERING

SYLLABUS (For students admitted from the academic year 2019 - 2020)

DEPARTMENT OF MECHANICAL ENGINEERING

NATIONAL INSTITUTE OF TECHNOLOGY PUDUCHERRY

KARAIKAL – 609 609, INDIA.

Page | 1

Syllabus for B.Tech. in Mechanical Engineering

SEMESTER I

HM141 COMMUNICATIVE ENGLISH L T P C 2 0 2 3

OBJECTIVE:

To train students in understanding the basics of communication and enable them to demonstrate good soft skills in their scholastic and professional endeavours.

Elements of Communication: Definition, Importance, Process of Communication, Factors of Communication - Sender, Receiver, Channel, Code etc., Filters and Barriers, Verbal and Non-verbal Communication, Networks and Channel.

Writing Skills: Process of Writing - Stage of Ideation, Idea Mapping etc., Effective Writing Practice- Role of Appropriateness, Brevity, Clarity in Writing; Vocabulary Expansion. Speaking Strategies: Speech Mechanics, Mental Process of Speaking, Presentation Skills- Role of Audience analysis and Technology, Extempore Speech Practice. Spoken English Practice: Functions of Language, Description of a process, Vocabulary Development, Conversation and Dialogue Practice, Seminar Skills.

Soft Skills: Relationship between Soft skills and Communication Skills, Leadership Skills, Team management Skills, Interview Skills, Telephone etiquettes. Activities for Practice:

Task based activities designed based on theory syllabus such as pair work activities, role plays, spoken English practice, mock interviews, group discussions, writing and soft skills practice etc.

OUTCOMES: At the end of the course, the students will have the knowledge of

• Understand the nuances of effective communication and exhibit good soft skills • Apply and incorporate the knowledge of English to facilitate effective communication in their

careers and social realm • Integrate language with content specific subject knowledge through task based activities.

TEXT BOOKS:

1. Meenakshi Raman and Sangeeta Sharma, Technical Communication, OUP Publication, 2005. 2. John Sealy. The Oxford guide to effective writing and Speaking, OUP publication, 2007. 3. K. Alex. Soft Skills, S. Chand Publication, 2010

REFERENCE BOOKS: 1. David Lindsay, A Guide to Scientific Writing, Macmillan, 1995. 2. C. Bovee & C.A. Paul. Business Communication Today, Pearson, 2018. 3. Raymond V Lesikar and Marie E. Flatley. Basic Business Communication, Tata Mc-Graw Hill,

2005. 4. Comfort, Jeremy, et al. Speaking Effectively: Developing Speaking Skills for Business English.

Cambridge University Press, Cambridge: Reprint 2011.

Page | 2

MA141 CALCULUS L T P C 3 1 0 4

OBJECTIVE:

To be able to understand about Calculus problems To be able to understand about Vector problems

DIFFERENTIAL CALCULUS: Basic concepts - Limits, continuity, differentiation, functions of several variables, partial derivatives, total derivatives, Taylor’s formula for functions of two variables. INTEGRAL CALCULUS: Double integrals -double integrals over rectangles, double integrals as volumes, Fubini’s theorem, double integrals in polar form, changing the order of integration. ORDINARY DIFFERENTIAL EQUATIONS OF FIRST ORDER: Basic concepts, separable differential equations, exact differential equations, integrating factors, linear differential equations, Bernoulli equation, modelling- mixing problems, Newton’s law of cooling. LINEAR DIFFERENTIAL EQUATIONS OF SECOND ORDER: Homogeneous linear equations of second order, linearity principle, initial value problem, general solution, second order homogeneous equations with constant coefficients, Euler – Cauchy equation, Applications of ODEs. VECTOR CALCULUS: Green’s, Gauss divergence and Stoke’s theorems, Evaluation of line, surface and volume integrals. OUTCOMES: At the end of the course, the students will be able to solve

Calculus Problems Vector Problems

TEXT BOOKS: 1. Thomas G. B. and Finney R. L., “Calculus and Analytic Geometry”, Pearson Education, New

Delhi, 2012. 2. Erwin Kreyszig, “Advanced Engineering Mathematics”, Wiley India Pvt Ltd, New Delhi, 2012.

REFERENCE BOOKS: 1. Wylie C R and Barrett L C, “Advanced Engineering Mathematics”, Tata McGraw-Hill, New

Delhi, 2013. 2. Peter V.O Neil, “Advanced Engineering Mathematics”, Cengage, New Delhi, 2010.

Page | 3

PH141 PHYSICS FOR MECHANICAL ENGINEERS L T P C 3 0 0 3

OBJECTIVE: To enable the students to refresh their basics of Physics and orient themselves in

implementation of concepts in engineering. To give an exposure on basics of quantum mechanics and statistical physics. To provide fundamentals of Solid-state physics, which give foundation for engineering

Physics and Materials Science. To enable the students to get exposure on different types advanced materials in

engineering, properties and application in the field of engineering OSCILLATORY MOTION AND WAVE MOTION: Review of simple harmonic motion Vibration of a spring and mass system. Frequency response, damping and resonance. Wave motion: Definition of a plane progressive wave. Attenuation of waves. Representation of waves using complex numbers. Differential equation of a plane progressive wave. Phase velocity. Phase and phase difference. Solution of the differential equation of a plane progressive wave. Differential equation of 2-dimensional wave motion. OPTICS: Review of ray optics, Optical instruments for inspection. Spherical and chromatic aberration. Methods of reducing aberrations. Aspherical components, aperture control, multiple elements. Adaptive optics. Interference, diffraction- polarization, applications. Interferometric displacement measurements. Non-contact optical dimension measurements. MATERIAL SCIENCE: Crystalline and amorphous solids-system of crystals-Miller indices-atomic radius-coordination number-Atomic packing factor calculation-Bragg’s law. Drude theory of electrical conductivity, Free electron theory (classical and quantum), band theory of solids, semiconductors and semiconductor devices. PROPERTIES OF MATERIALS: Viscosity, Surface tension, angle of contact-elasticity- elastic constants- interrelations, optical properties, Magnetism-types and properties- Hard and soft magnetic materials, applications, dielectric, piezoelectric materials, dielectric properties of materials. Superconductivity-types, Meissner effect, applications. LASER & OPTICAL FIBERS: Spontaneous and stimulated emissions-Einstein’s coefficients-Population inversion and lasing action, Coherence-Properties and types of lasers-Applications; Optical fiber - Numerical aperture-Types of fibers - Fiber optics communication principle - Fiber optic sensors. OUTCOMES: At the end of the course, the students will be able to

To apply the basic concepts of physics in various applications. To apply the concepts of advanced materials in engineering, properties and application in the

field of engineering TEXT BOOKS:

1. Richard Wolfson, “Essential University Physics”, Vols. 1 and 2. Pearson Education, Singapore, 2011.

2. Gaur R K, Gupta S L, “Engineering Physics”, DhanpatRai Publications, 2013. REFERENCE BOOKS:

1. Halliday D., Resnick R. and Walker J., “Fundamentals of Physics”, Wiley Publications, 2008. 2. Raymond A. Serway and John W. Jewett, “Physics for Scientists and Engineers”, Volume 5,

Chapters 40-46, Cengage Learning, 2010.

Page | 4

3. Paul M. Fishbane. Stephen Gasiorowicz and Stephen T. Thornton, “Physics for Scientists and Engineers”, Extended Version, Addison Wesley, 2001.

4. Paul A. Tipler and GeeneMosca, “Physics for Scientists and Engineers”, W.H.Freeman and Company, New York, 2004.

Page | 5

CH141 CHEMISTRY FOR MECHANICAL ENGINEERS L T P C 3 0 0 3

OBJECTIVE: Enabling the Students to learn the basic principles of bonding, electrochemistry, Corrosion

studies, chemical kinetics and water treatment. BONDING AND GAS LAWS: Types of chemical bonds - bond polarity- dipole moment – partial ionic character - consequences. Weak Interactions – Hydrogen bonding, van der Waals forces - influence on properties of matter. Metallic bond – free electron theory, MO treatment - bonding in metals, semiconductors and insulators. Gas laws - Avogadro’s law, molar volume calculations-applications. ELECTROCHEMISTRY: Electrodes-types - calomel and silver/silver chloride, ion selective electrodes – applications, emf series –Nernst equation, galvanic and concentration cells- Potentiometric titrations. Irreversible processes - activation and concentration overpotentials – practical significance. Electrolytic conductance – conductance of strong and weak electrolyte – conductometric titrations. Electropolishing and electrochemical machining, electrophoretic painting, anodizing. CORROSION AND ITS CONTROL: Corrosion – principles of corrosion – Pilling – Bed worth rule – principles of electrochemical corrosion – difference between chemical and electrochemical corrosion – galvanic corrosion – differential aeration corrosion – factors influencing corrosion – corrosion control – cathodic protection – sacrificial anodic method – corrosion inhibitors. CHEMICAL KINETICS AND SURFACE CHEMISTRY: Integrated rate laws - kinetics of complex reactions. Chain reactions - mechanism and kinetics of combustion of hydrogen and hydrocarbons - adsorption isotherms- Freundlich and Langmuir isotherms, BET isotherm (derivation not required). Determination of surface area of catalyst. Applications of adsorption. Colloidal systems- Sols, critical micelle concentration. WATER: Hardness - estimation - EDTA method – alkalinity - estimation. Boiler troubles and remedies. Softening- zeolite and demineralization processes. Internal conditioning. Treatment of water for municipal supply, break point chlorination, desalination by reverse osmosis and electrodialysis. Water analysis - flame photometry, brief outline of AAS and ICP - MS. OUTCOMES:

At the end of the course, the students will be able to apply the basic principles of bonding, electrochemistry, corrosion studies, chemical kinetics and surface chemistry and water.

TEXT BOOKS: 1. Peter Atkins and Julio de paula, “Physical Chemistry”, Oxford university press, New York,

2010. 2. Puri B. R., Sharma L. R. and Pathania M. S., “Principles of Physical Chemistry”, Vishal

Publishing Company, Delhi, 2010. 3. Jain & Jain, Engineering Chemistry, Dhanpat Rai Publishing Company, New Delhi, 17th Edition,

2018. REFERENCE BOOKS:

1. Gopalan R., “Text Book of Engineering Chemistry”, Vikas Publishing House (P) Ltd., New Delhi, 2006.

2. Sharma B. K., “Engineering Chemistry”, Krishna Prakashan Media (P) Ltd., Meerut, 2005. 3. Shashi Chawla, “A Text Book of Engineering Chemistry”, DhanpatRai& Co, New Delhi, 2005.

Page | 6

EE141 BASIC ELECTRICAL AND ELECTRONICS

ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To enable the students to gain knowledge about the fundamentals of Electrical and Electronics engineering

ELECTRIC CIRCUITS: Ohm’s law, Kirchoff’s Current Law, Kirchoff’s Voltage Law, Solving simple DC Circuits - Single phase AC circuit fundamentals – Power, Power factor – solving simple AC circuits – 3 phase AC circuits – Star and Delta Connection. DC MOTORS: Principle of Operation - types – back emf – torque equation - speed torque characteristics – losses and efficiency –speed control of DC motor – Electric Braking - Motor Selection - Applications. AC MACHINES: Three phase Induction Motor - Construction– Principle of operation – types – torque equation - Speed torque characteristics – 1 phase Induction Motor – Principle of operation- types. Electric Braking of Induction Motor – Single phase Transformers – Construction and working principle – Types and industrial applications. ELECTRONIC DEVICES & CIRCUITS: Operation of PN junction diodes, VI characteristics, Zener diode, BJT - types - CB, CE, CC configurations, input and output characteristics, JFET - working principle and characteristics. MOSFET, Rectifiers, Amplifiers, Oscillators, Diodes. DIGITAL ELECTRONICS: Number systems, Boolean theorems, Logic gates, Implementation of Boolean expression using Gates, Introduction to Integrated Circuits. Fundamentals of Sensors and display devices (Interaction with communication modes – WiFi and Bluetooth) OUTCOMES:

At the end of the course, the students will be able to apply the fundamentals of Electrical and Electronics engineering

TEXT BOOKS: 1. Mehta.V.K and Rohit Mehta, “Principles of Electrical Engineering and Electronics”, S.Chand&

Co. Limited. New Delhi, 2006. 2. Muthusubramanian.R, Salivahanan.S and Muraleedharan.K.A, “Basic Electrical, Electronics

and Computer Engineering”, TataMcGraw Hill Publishers, 2006. REFERENCE BOOKS:

1. Pillai.S.K,”A First Course on Electrical Drives”, New Age International Publications Limited, 2011.

2. MurugeshKumar.K, “Basic Electrical Science and Technology”, Vikas Publishing Limited, 2011.

3. Roy Choudhury and Shail Jain, “Linear Integrated Circuits”, New Age International Limited, 2003.

4. Leach.D. P, Malvino.A.P and GoutamSaha, “Digital Principles and Applications”, Tata McGraw – Hill, 2008

Page | 7

ME101 ENGINEERING GRAPHICS L T P C 1 0 4 3

OBJECTIVE: Irrespective of engineering discipline, it has become mandatory to know the basics of engineering graphics. The student is expected to possess the efficient drafting skill depending on the operational function in order to perform day to day activity.

To provide engineering drawing knowledge. Enables the knowledge about different types of lines their usage Enables the knowledge on 2D & 3D geometrical entities

(USAGE OF ENGINEERING INSTRUMENTS IS MANDATORY)

FUNDAMENTALS: Drawing standard - BIS, dimensioning, lettering, type of lines, scaling conventions. Geometrical constructions: Dividing a given straight line into any number of equal parts, bisecting a given angle, drawing a regular polygon given one side, special methods of constructing a pentagon and hexagon – conic sections – ellipse – parabola – hyperbola - cycloid – trochoid. ORTHOGRAPHIC PROJECTION: Introduction to orthographic projection, drawing orthographic views of objects from their isometric views – Orthographic projections of points lying in four quadrants, Orthographic projection of lines parallel and inclined to one or both planes Orthographic projection of planes inclined to one or both planes. PROJECTIONS OF SIMPLE SOLIDS: Axis perpendicular to HP, axis perpendicular to VP and axis inclined to one or both planes. Sectioning of solids: Section planes perpendicular to one plane and parallel or inclined to another plane. INTERSECTION OF SURFACES: Intersection of cylinder and cylinder, intersection of cylinder and prism, and intersection of prisms. Development of surfaces: Development of prisms, pyramids and cylindrical & conical surfaces. Isometric and perspective projection: PROJECTIONS: Isometric projection and isometric views of different planes and simple solids, introduction to perspective projection, perspective projection of simple solids prisms, pyramids and cylinders by visual ray method and vanishing point method. OUTCOMES: Upon completion of the course the student will be able to

Perform free hand sketching of basic geometrical constructions and multiple views of objects. Do orthographic projection of lines and plane surfaces. Draw projections and solids and development of surfaces. Prepare isometric and perspective sections of simple solids

TEXT BOOKS: 1. Bhatt,N. D and Panchal,V.M.,Engineering Drawing, Publication: Charotar Publishing House,

2010. 2. Natarajan, K. V., A text book of Engineering Graphics, Publication: Dhanalakshmi Publishers,

Chennai, 2006. 3. Venugopal, K. and Prabhu Raja, V., Engineering Drawing and Graphics + AutoCAD, Pub.: New

Age International, 2009. REFERENCE BOOKS:

1. Jolhe, D. A., Engineering drawing, Publication: Tata McGraw Hill, 2008 2. Shah, M. B. and Rana, B. C., Engineering Drawing, Pub.: Pearson Education, 2009.

Page | 8

3. Basant Agarwal and Agarwal C.M., “Engineering Drawing”, Tata McGraw Hill Publishing Company Limited, New Delhi, 2008.

4. Luzzader, Warren.J. and Duffjohn M., “Fundamentals of Engineering Drawing with an introduction to Interactive Computer Graphics for Design and Production, Eastern Economy Edition, Prentice Hall of India Pvt. Ltd, New Delhi, 2005

Page | 9

PH143 PHYSICS LABORATORY L T P C 0 0 4 2

OBJECTIVE: To provide understanding on various experiments such as

To determine young’s modulus

To determine coefficient of viscosity

To measure the vibration frequency

To determine thermal conductivity

LIST OF EXPERIMENTS (8-10 experiments to be chosen)

1. Determination of Young’s modulus of a wooden bar – Cantilever method. 2. Determination of coefficient of viscosity of water – Poiseuille’s method. 3. Measurement of Vibration Frequency of electrically maintained tuning fork - Melde’s

Apparatus. 4. Determination of wavelength of mercury spectrum using diffraction grating. 5. Determination of thermal conductivity of bad conductor using Lee’s disc method 6. Modulus of rigidity using torsion pendulum. 7. Measurement of temperature using thermocouple. 8. Specific heat of liquids by Newton’s law of cooling. 9. B-H curve of ferromagnetic materials. 10. Determination of resistivity and band gap of a semiconductor. 11. Series LCR circuit-resonance phenomenon. 12. Newton’s rings- determination of radius of curvature of a lens. 13. Determination of resistivity and band gap of a semiconductor 14. Charge-discharge characteristics of RC circuit. 15. Verification of Photo-electric effect. 16. Characterizing an optical fiber

DEMONSTRATION:

1. Optical phenomena using He – Ne Laser 2. Ultrasonic cleaning. 3. Thin film deposition using DC/RF sputtering technique. 4. Surface Profilometer

OUTCOMES:

After completion of this course, the students are able to perform the stated experiments. REFERENCE BOOKS:

1. J.D.Wilson and C.A.Hernandez, “Physics Laboratory Experiments”, Houghton Mifflin Company, New York 2005.

Page | 10

CH143 CHEMISTRY LABORATORY L T P C 0 0 4 2

OBJECTIVE: To provide understanding on various experiments such as

Strength of acid. Synthesis of conducting polymer by electrochemical techniques Determination of hardness of water

LIST OF EXPERIMENTS

1. Estimation of strength of an acid by pH -metry 2. Estimation of acids in a mixture by conductometry 3. Determination of total hardness of water by EDTA method 4. Determination of permanent and temporary hardness of water by EDTA method 5. Synthesis of conducting polymer by electrochemical polymerization method using Cyclic

Voltammetric technique 6. Analysis of metal nanoparticles by UV-Visible spectroscopic method 7. Determination of corrosion rate of mild steel 8. Estimation of total alkalinity in the given water sample 9. Estimation of dissolved oxygen in waste water 10. Estimation of Fe2+ by external indicator

OUTCOMES:

After completion of this course, the students are able to perform the stated experiments. REFERENCE BOOKS:

1. Laboratory Manual Prepared by the Department.

Page | 11

SEMESTER II

HM142 PRACTICAL ENGLISH L T P C 2 0 2 3

OBJECTIVE: To enable students to refine their communication skills with an emphasis on Practical /

technical writing and aid them in applying this knowledge to enrich their career and academic pursuits.

Technical Writing Skills: Mechanics of Technical Writing, Paragraph Writing - Coherence, Cohesion, Linkers, Unity; Report Writing - Oral and Written Reports, Precise writing- paraphrasing, Business Proposals, Summary writing on graphs, tables, charts etc.

Listening Skills: Importance of Listening skills in Technical World, Types of Listening, Listening for information, inference and evaluation, Note Taking, Barriers to listening - Physical, Psychological, Linguistic, and Cultural; Methods to overcome the barriers. Reading Skills: Importance of Reading skills, Reading strategies, Reading for information, inference and evaluation. (News papers, Scientific Research, Desired reading materials), Note Making, Reading Practice- Technical and general texts including excerpts from prose and poetry. Study Skills: Reading technical reports/articles, Primary and Secondary literature, Structure of a research article, Glossary, Index, Reference and bibliography.

Language Project: A team-based survey and assessment report on real life language utility in different sectors of society as per the teacher’s instruction.

Activities for Practice:

Task based activities designed on the basis of theory syllabus such as writing practice, listening skills practice, reading strategy practice; reading for research, reference skills etc. OUTCOMES: The students will be able to:

Enrich their language skills with special focus on the technical & practical aspects. Gauge an understanding of the basic idea of research and learn the importance of documentation

in research. Integrate language with content specific subject knowledge through task based activities.

TEXT BOOKS: 1. Meenakshi Raman and Sangeeta Sharma, Technical Communication: Principles and Practice, OUP Publication, 2014. 2. M. Ashraf Rizvi, Effective Technical Communication, Tata McGraw Hill,2005. 3. C. Bovee & C.A. Paul. Business Communication Today, Pearson, 2018. REFERENCE BOOKS: 1. David Lindsay, A Guide to Scientific Writing, Macmillan, 1995. 2. Richard A Boning, Multiple Reading Skills, McGraw Hill, 1990. 3. Rod Ellis. English for Engineers & Technologists: A Skill Approach, Orient Blackswan, Reprint 2003. 4. Dhamija and Sasikumar, Spoken English, McGraw Hill Education, 2015.

Page | 12

MA142 COMPLEX VARIABLES AND TRANSFORMS L T P C 3 0 0 3

OBJECTIVE:

To understand the basic Complex number calculations COMPLEX VARIABLES Complex differentiation-Analytic function, Cauchy Riemann equations, Harmonic functions COMPLEX INTEGRATION Cauchy’s integral theorem, Cauchy’s integral formula, Laurent series (concept and statement only), singularities and zeros, residue integration method (Residue integration of complex integrals only), linear fractional transformations. LAPLACE TRANSFORMS Laplace transform, inverse transform, linearity, s-shifting, transforms of derivatives and integrals, unit step function, t- shifting, Dirac’s delta function, periodic functions, convolution, differentiation and integration of transforms, Method of solving differential equations and integral equations by using Laplace transform technique. FOURIER TRANSFORMS Fourier series – Odd and Even function – Half range sine series - Half range cosine series – Parseval’s identity; Fourier transforms, Fourier cosine and sine transforms. HOMOGENEOUS PDE Basic concepts, modeling–vibrating string, wave equation, solution by separating variables, one-dimensional heat equation, steady state two-dimensional heat equation (Cartesian coordinates only) - solution by Fourier series.

OUTCOMES: On successful completion of the course, the student will be able to solve,

Complex number Problems Fourier and Laplace Transforms

TEXT BOOKS: 1. Erwin Kreyszig, “Advanced Engineering Mathematics”, Wiley India Pvt Ltd, New Delhi, 2012. 2. Wylie C. R. and Barret L.C., “Advanced Engineering Mathematics”, Tata McGraw-Hill, New Delhi,


1. Mathews J. H. and Howell R. W., “Complex Analysis for Mathematics and Engineering”, Narosa Publishing House, New Delhi, 2011.

2. Peter V.O Neil, “Advanced Engineering Mathematics”, Cengage, New Delhi, 2010.

Page | 13

ME102 ENGINEERING MECHANICS L T P C 3 0 0 3

OBJECTIVE:

Inculcate the fundamental knowledge to compute forces and their responses when the bodies are in rest and in motion.

Inculcate the knowledge of the friction and its influence on mechanical structures Fundamentals: Mechanics and its relevance, concepts of forces, laws of mechanics parallelogram law, Lami’s theorem, Law of polygon, concept of free body diagram, centroids, center of gravity, area moment of inertia, mass moment of inertia – simple and composite planes, simple truss analysis, Numerical problems. Friction: Laws of friction, static friction, rolling friction, application of laws of friction, ladder friction, wedge friction, body on inclined planes, simple screw jack – velocity ratio, mechanical advantage, efficiency, Numerical problems. Statics: Statics of particles - Force on a particle – resultant of two forces and several concurrent forces – resolution of a force – equilibrium of a particle – force in space – equilibrium of a particle in space. Statics of rigid bodies - External, Internal forces – transmissibility – moment of a force – Varignon’s theorem – moment of a couple – resolution of a force into a force and a couple – reduction of a system of forces – reactions at supports and connections – equilibrium of a two and three force bodies - simple stresses and strains, elastic coefficients, Numerical problems. Kinematics: Fundamentals of rectilinear and curvilinear motion, application of general equations, concept of relative velocity, analytical and graphical techniques, Numerical problems. Kinetics: Principles of dynamics, Equations of dynamic equilibrium, Alembert’s principle, conservation of momentum and energy, Numerical problems.

OUTCOMES:

1. Draw the free body diagram of a given physical system and compute the resultant of a given coplanar system of forces

2. Estimate the centroid of composite figures and bodies 3. Estimate area moment of inertia and mass moment of inertia of composite figures and bodies 4. Explain concepts of friction and principle of virtual work 5. Summarize power transmission through belts 6. Interpret kinematics and kinetics of a particle in rectilinear motion and solve simple problems 7. Interpret kinematics and kinetics of a particle in curvilinear motion solve simple problems

TEXT BOOKS: 1. S. Timoshenko and D. H.Young, Engineering Mechanics, McGraw Hill, 2006. 2. Singer Ferdinand L, Engineering Mechanics, Harper & Row Publishers, 3 rd Edition, 1975 3. Beer F P and Johnson E R, “Vector Mechanics for Engineers, Statics and Dynamics”, Tata

McGraw Hill Publishing Co. Ltd., New Delhi, 2010. REFERENCE BOOKS:

1. S.S Bhavikatti, Engineering Mechanics, New Age International, 6th Multicolor Edition, 2015 2. R C Hibbeler, Engineering Mechanics, Pearson Education; Fourteenth edition, 2017. 3. Irving. H. Shames, Engineering Mechanics Statics and Dynamics, Pearson Education; Fourth

edition, 2005. 4. J.L. Meriam, L.G. Kraige, J.N.Bolton, Engineering Mechanics: Statics, Wiley, 2017. 5. J.L. Meriam, L.G. Kraige, J.N.Bolton, Engineering Mechanics: Dynamics, Wiley, 2018.

Page | 14

CS142 FUNDAMENTALS OF COMPUTERS AND PROGRAMMING

L T P C 3 0 0 3

OBJECTIVE: To learn the fundamentals of computers. To learn the problem-solving techniques in writing algorithms and procedures. To learn the syntax and semantics for C programming language. To understand the constructs of structured programming such as conditions, iterations,

arrays, functions and pointers. Analyze complex engineering problems to develop suitable solutions

Fundamentals of Computers, Algorithms and Structured Programming Introduction to computers – Computer Organization – Characteristics – Hardware and Software –Modes of operation – Types of programming languages – Developing a program, Algorithms – Characteristics – Flowcharts - Principles of Structured programming – Sequential, Selective structures - Repetitive structures –Bounded, Unbounded and Infinite iterations, Introduction to FORTRAN. Overview of C and Branching Introduction to C – C character set – Identifiers and Keywords – Data types – Constants – Variables – Declarations – Expressions – Statements – Symbolic constants – Operators– Library functions . Data input and output: Single character input and output – Entering input data – Writing output data – gets and puts functions. Control statements: Conditional- Branching- Looping- unconditional: Break- continue-goto. Functions and Arrays Functions: Overview- Defining a Function- Accessing a Function- Function Prototypes- Passing Argument to a Function- Recursion- Storage Classes: Automatic Variables- External (Global) Variables-Static Variables- Register variables. Arrays: Defining an Array- Processing an Array- Passing Array to function- Multidimensional Arrays. Strings and Pointers Strings: Defining a String - NULL Character- Initialization of Strings- Reading and Writing a String- Processing Strings - Character Arithmetic- Library Functions for Strings. Pointers: Pointer Declaration-Passing Pointers to a Function-Pointers and One-dimensional Array- Dynamic Memory Allocation- Operations on Pointers- Pointers and Multidimensional Arrays- Array of Pointers, Command line arguments. Structures, File Management and Preprocessors Basic of Structures, structures and functions, array of structures, structure data types, type definition, defining, opening and closing of files, input and output operations. Introduction to preprocessors, compiler control directives. Introduction to Python programming OUTCOMES: Upon the completion of the course, students will be able to,

Understand the organization of a computer Explain the syntax and semantics of C programming language. Code a given logic in C language. Apply C language for coding a given algorithm.

Teaching and Evaluation guidelines

Page | 15

40% on Analysis and Synthesis (Higher Order Thinking), 30% on Application (Medium Order Thinking), and 30% on Knowledge and Comprehension (Lower Order Thinking).

TEXT BOOKS:

1. Brian W Kerningan and Dennis M. Ritchie, “The C Programming Langauge”, Second Edition, PHI, 2012.

2. Byron Gottfried, “Programming with C”, Third Edition, Tata McGraw Hill Education, 2010. 3. R.G. Dromey, “How to Solve it By Computers?”, First edition, Prentice Hall, 2001. 4. E.Balagurusamy . Fundamentals of Computers and Computer Programming, McGraw-Hill,


1. J.R. Hanly and E.B. Koffman, “Problem Solving and Program Design in C”, Sixth Edition, Pearson Education, 2009. 2. Paul Deital and Harvey Deital, “C How to Program”, Seventh Edition, Prentice Hall, 2012. 3. Yashavant Kanetkar, “Let Us C”, Twelfth Edition, BPB Publications, 2012.

Page | 16

ME104 ENERGY, ENVIRONMENT, LIFESCIENCES AND

AGRICULTURE L T P C 3 0 0 3

OBJECTIVE:

To learn about various Energy Sources To learn about Agricultural Engineering

RENEWABLE ENERGY: Present energy resources in India and World and its sustainability - Different type of Conventional power plants - Energy demand scenario in India - Advantage and disadvantage of Conventional Power Plants – Conventional and Non-Conventional power generation. Solar Energy, Wind Energy, Ocean Energy, Biomass, Waste to Energy, Fuel Cells, Geothermal Energy. ENVIRONMENT: The human population and the environment, the human population’s effects on the earth, the ecosystem, chemical cycling and succession, the biogeochemical cycles, major global biogeochemical cycles - carbon, carbon-silicate, nitrogen and phosphorus cycles, global warming, greenhouse effect, major greenhouse gases. ENVIRONMENTAL POLLUTION CONTROL: Environmental segments – structure and composition of atmosphere - Pollution – Air, water, soil, thermal and radiation – Effects - Control measures – Determination of BOD, COD, TDS and trace metals. WASTE MANAGEMENT: Waste water treatment (general) – primary, secondary and tertiary stages. Solid waste management: sources and effects of municipal waste, bio medical waste, e-wastes - process of waste management. LIFE SCIENCES: Fundaments of Biochemistry, Botany, Microbiology, Zoology, Food Technology AGRICULTURAL CROP PRODUCTION: Concepts in crop production; geographical distribution of crops and cropping systems; economic importance. Concepts in crop production; geographical distribution of crops and cropping systems; economic importance. Techniques of nursery raising, method of planting, fertilization, irrigation scheduling, weed control, and other practices to optimize yield, economic evaluations. FARM MACHINERY AND EQUIPMENT: Objectives of farm mechanization. Classification of farm machines. Materials of construction of farm equipment. Principles of operation and selection of machines used for production of crops. Principles of plantation crops and fruit harvesting tools and machines. Economics of farm mechanization. OUTCOMES: At the end of the course, the students will have the knowledge of

Various Energy Sources Agricultural Engineering Waste Management

TEXT BOOKS: 1. Nag P K, “Power Plant Engineering”, Tata McGraw Hill, New Delhi, 2004. 2. Kothari P, Singal K C and Rakesh Ranjan, “Renewable Energy Sources and Emerging

Technologies”, PHI Pvt. Ltd., New Delhi, 2008. 3. Daniel B Botkin and Edward A Keller, “Environmental Science”, John Wiley & Sons,

Chichester, 2010. REFERENCE BOOKS:

1. Singh, Chidda "Modern technique of raising of field crops". Oxford and IBH Publishing Company Pvt. Ltd., 1994.

2. Srivastava, A.C. “Elements of Farm Machinery”. Oxford & IBH Publishing Co. Pvt. Ltd, New Delhi.1991.

Page | 17

ME106 MANUFACTURING PROCESSES L T P C 3 0 0 3

OBJECTIVE: To learn about Basic Concepts of Manufacturing Technology

METAL CASTING PROCESS: Sand casting - Patterns, Moulding Sand, Gating and Riser system, Melting practices – Casting cleaning and inspection - Special casting processes: Investment casting process, Die casting process, Shell moulding process- Centrifugal casting process. JOINING PROCESSES: Fundamentals of metal joining - Fusion welding and solid-state welding processes – Welding defects – Brazing and Soldering. BULK DEFORMATION PROCESSES: Hot and Cold working - Formability– Forging – Rolling – Extrusion – Drawing – Force estimation - Defects. SHEET METAL FORMING: Shearing, bending, drawing, blanking, piercing, punching - Formability of sheet metal - Special forming methods: Explosive forming, electromagnetic forming, electro hydraulic forming, Composite moldings. POWDER METALLURGY: Definition - Advantages – Limitations – Applications - Manufacture of parts by powder metallurgy - Production of metal powders – Blending – Compaction – Sintering - Finishing. PLASTIC PROCESSING: Processing of plastics: General aspects - Plastic processing methods. OUTCOMES: At the end of the course, the students will be able to

Work in Various Manufacturing Industries Get knowledge about Basic Manufacturing Processes

TEXT BOOKS: 1. Rao P N, “Manufacturing Technology”, Tata McGraw Hill Publishing Co. Ltd., Volume 1, New

Delhi, 2010. 2. Serope Kalpakjian and Stephen Schmid,”Manufacturing, Engineering and Technology”, SI 7th

Edition -”, Pearson Education, 2013.

REFERENCE BOOKS: 1. Mikell P. Groover,” Principles of Modern Manufacturing”, SI Version, Wiley & sons Pvt. Ltd,

2013. 2. R.K. Rajput,”A textbook of manufacturing technology (manufacturing processes)”,Laxmi

publications (p) ltd, 2015. 3. Heine R W, Loper C R and Rosenthal P C, “Principles of Metal Casting”, Tata McGraw Hill

Publishing Co. Ltd., New Delhi, 2010.

Page | 18

CS144 BASIC PROGRAMMING LABORATORY L T P C 0 0 4 2

OBJECTIVE:

Design algorithms for specified engineering problems. Analyze complex engineering problems and develop solutions.

LIST OF EXERCISES: 1. Programs using sequence construct 2. Programs using selection construct 3. Programs using Iterative construct 4. Programs using nested for loops 5. Programs using functions with Pass by value 6. Programs using functions with Pass by reference 7. Programs using recursive functions 8. Programs using one dimensional Array 9. Programs using two dimensional Arrays 10. Programs using Pointers and functions 11. Programs using Pointers and Arrays 12. Programs using Pointers and structures 13. Programs using structures and arrays 14. Programs to perform I/O operations on files. 15. Programs to perform error handling during I/O operations on files. 16. Programs to perform random access to files.

OUTCOMES:

Ability to write program in C language Ability to test and debug the programs for critical errors Ability to analyze and optimize programs

REFERENCE BOOKS: 1. Yashavant Kanetkar, Let us C, BPB Publications, 15th edition, 2016

Page | 19

ME108 BASIC WORKSHOP PRACTICE L T P C 0 0 4 2

OBJECTIVE:

Introduction to the use of tools and machinery in Carpentry, Welding, Foundry, Fitting and

Sheet Metal Working.

LIST OF EXPERIMENTS: 1. Department of Mechanical Engineering; (Any Three Experiments) Carpentry: Wood sizing exercise in planning, marking, sawing, chiseling, and grooving to make

(a) Half - Lap Joint Welding: Exercise in arc welding for making

(a) Lap Joint Fitting: Preparation of joints, markings, cutting, and filling for making

(a) Square Fitting Sheet Metal: Making of small parts:

(a) Tray/Dust Pan II. Department of Electrical and Electronics Engineering; (Any Three Experiments) 1. Residential house wiring using switches, fuse, indicator, lamp and energy meter. 2. Fluorescent lamp wiring. 3. Stair case wiring. 4. Measurement of electrical quantities – voltage, current, power & power factor in RLC circuit. III. Department of Electronics and Communication Engineering; 1. Identification and checking of basic electronic equipment and components 2. Introduction to function generator, cathode ray oscilloscope and regulated power supply. 3. Construction of simple electronic circuit using bread board and printed circuit board (PCB). IV. Department of Civil Engineering; 1. Identification of rock sample using hard lens 2. Demonstration of brick bonds 3. Field measurement of given building or marked using tape OUTCOMES:

Ability to fabricate carpentry components, Ability to use welding equipment’s to join the structures. Ability to fabricate sheet metal, components, Ability to identify and make electrical and electronics circuits.

REFERENCE BOOKS: 1. Laboratory Manual Prepared by the Department.

Page | 20

SEMESTER III

MA241 NUMERICAL METHODS L T P C 3 0 0 3

OBJECTIVE: To understand the Numerical Methods problems

LINEAR ALGEBRAIC EQUATIONS: Direct methods - Naïve Gauss elimination method, Gauss-Jordan method, Crout’s method Iterative methods – Gauss - Jacobi method, Gauss–Seidel method, eigenvalues and eigenvectors - power method, Jacobi method. NONLINEAR EQUATIONS: False- position method, Newton-Raphson method, Bairstow’s method, Graeffe’s root squaring method INTERPOLATION AND CURVE FITTING: Newton’s forward and backward interpolating polynomials, Newton’s divided-difference interpolating polynomials, Lagrange interpolating polynomials, coefficients of an interpolating polynomial, Chebyshev interpolation Curve fitting - least- squares regression DIFFERENTIATION AND INTEGRATION: Numerical differentiation - equally spaced and unequally spaced data, numerical integration, Newton-Cotes formulae, Trapezoidal rule, Simpson’s1/3 rule DIFFERENTIAL EQUATIONS: ODE - Taylor-series method, Euler method, Heun’s method, 4thorder Runge-Kutta method multi step method - Milne method; PDE - Finite difference: Elliptic equations - Laplace equation, parabolic equations – heat conduction equation – Crank Nicolson’s method, hyperbolic equations – vibrating string.

OUTCOMES: On successful completion of the course, the student will be able to solve,

Numerical Problems Finite difference method problems

TEXT BOOKS: 1. Steven C Chapra and Raymond P Canale, Numerical Methods for Engineers, McGraw Hill

Education, New Delhi, 2012. 2. Curtis F Gerald and Patrick O Wheatly, Applied Numerical Analysis, Pearson Education, New

Delhi, 2013. REFERENCE BOOKS:

1. Rizwan Butt, Introduction to Numerical Analysis Using MATLAB, Infinity Science Press, Hingham, 2008.

2. Richard L Burden and Douglas J Faires, Numerical Analysis, Thomas Learning, NewYork, 2005.

Page | 21

ME201 ENGINEERING THERMODYNAMICS L T P C 3 0 0 3

OBJECTIVE:

To familiarize the students to understand the fundamentals of thermodynamics and to perform thermal analysis on their behavior and performance. (Use of Standard and approved Steam Tables, Mollier Chart, Compressibility Chart is permitted)

Basic concepts of thermodynamics, concept of continuum, macroscopic approach, thermodynamic systems – closed, open and isolated, property, state, path, process – quasi static process, work and modes of work, Zeroth law of thermodynamics, concept of temperature and heat – First law of thermodynamics, application to closed and open system. First law of thermodynamics steady flow process to various thermal equipment Second law statements – reversibility and irreversible processes, Carnot theorem, Carnot cycle, reversed Carnot cycle, efficiency, COP, Clausius Inequality – concept of entropy, principle of increase of entropy - Concept of availability. Properties of pure substances –thermodynamics properties of pure substances in solids, liquids and vapour phases – phase rule – p-V, p-T, T-V, T-s and h-s, thermodynamic properties of steam, Calculations of work done and heat transfer - Vapour power cycles - Rankine cycle - Effect of pressure and temperature on Rankine cycle - Reheat cycle - Regenerative cycle – Binary vapour cycles. Air standard power cycles - Assumptions - Otto, Diesel, dual, Stirling and Brayton cycles. Thermodynamic relations: Partial derivatives - Maxwell relations – Tds relations, Clausius Clapeyron equation, Joule Thomson coefficient - entropy change of an ideal gas - equations of state, properties of ideal and real gases, Avagadro law, Vander waal’s equation of state - Compressibility- compressibility chart. Mixture of non-reacting gases - Dalton's and Amalgam's model - calculation of Cp , Cv , Rand U , h and s changes for gas mixtures. Fuels and combustion - combustion chemistry – stoichiometric air required for complete combustion of fuels – excess air, products of combustion, calculation of air fuel ratio – determination of calorific value – Bomb and Junker’s calorimeter, Orsat apparatus for flue gas analysis.

OUTCOMES:

Understand the concepts of continuum, system, control volume, thermodynamic properties, thermodynamic equilibrium, work and heat.

Apply the laws of thermodynamics to analyze boilers, heat pumps, refrigerators, heat engines, compressors and nozzles.

Evaluate the performance of steam power cycles, the available energy and irreversibility and properties of pure substances and gas mixtures.

Analyze air standard cycles applied in prime movers. TEXT BOOKS:

1. Cengal, Y.A and Boles, M.A, Thermodynamics: An Engineering Approach, 5th ed.,McGraw-Hill, 2006.

2. Nag.P.K., “Engineering Thermodynamics”, 4thEdition, Tata McGraw-Hill, New Delhi, 2008

Page | 22

REFERENCE BOOKS: 1. Natarajan E., "Engineering Thermodynamics: Fundamentals and Applications", Anuragam

Publications, 2012. 2. Holman.J.P., "Thermodynamics", 3rd Edition, McGraw-Hill, 1995. 3. Rathakrishnan. E., "Fundamentals of Engineering Thermodynamics", 2nd Edition, Prentice- 4. Hall of India Pvt. Ltd, 2006 5. Chattopadhyay, P, "Engineering Thermodynamics", Oxford University Press, 2010. 6. Arora C.P, “Thermodynamics”, Tata McGraw-Hill, New Delhi, 2003. 7. Van Wylen and Sonntag, “Classical Thermodynamics”, Wiley Eastern, 1987 8. 7. Venkatesh. A, “Basic Engineering Thermodynamics”, Universities Press (India) Limited,

2007. 9. 8.Kau-Fui Vincent Wong, "Thermodynamics for Engineers", CRC Press, 2010 Indian Reprint. 10. Sonntag, R.E., Borgnakke, C., and Van Wylen, G.J., Fundamentals of Thermodynamics, 6th ed.,

John Wiley, 2003.

Page | 23

ME203 STRENGTH OF MATERIALS L T P C 3 0 0 3

OBJECTIVE: To understand statically determinate and indeterminate problems. To determine the resistance and deformation in member’s subjected to axial, flexural and

torsional loads. To evaluate principal stresses, strains and apply the concept of failure theories for design. To analyze and design columns, thin, thick cylinders and springs.

Simple Stresses and Strain – Relation between three modulus and Poisson’s ratio – Thermal Stress - Biaxial stress – Principal stress and Principal planes – Mohr’s Circle -. Beams - Theory of simple bending - Shear Force – Bending Moment – Cantilever and simply supported beams subjected to point loads and uniformly distributed loads; Stress variation in beam cross Section; Normal and Shear stress in Beams – Beam of uniform strength for bending, combined direct and bending stresses.

Double integration method – moment area method – Introduction to strain energy method. Numerical problems. Truss analysis – method of joints, method of sections Numerical problems. Torsion of circular solid and hollow shafts – Shafts in Series and parallel – Combined bending and torsion - Application of Torsion in helical springs: Open and closed coil springs, Leaf Springs.

Euler’s Equation – short and long column, Rankine empirical formulae, Johnson formula Introduction to thin cylinder – Thick cylinder – Lame’s Equation – Compound Cylinders – Interference fit. OUTCOMES:

Upon completion of this course, the students can able to apply mathematical knowledge to calculate the deformation behavior of simple structures.

Critically analyze problem and solve the problems related to mechanical elements and analyze the deformation behavior for different types of loads.

TEXT BOOKS: 1. Ferdinand P. Been, Russell Johnson, J.R. and John J. Dewole "Mechanics of Materials", Tata

McGraw Hill Publishing ‘co. Ltd., New Delhi, 2005. 2. Mechanics of Materials, Timoshenko, S.P., Gere, M.J., C.B.S., Publishers, 2011.

REFERENCE BOOKS: 1. Egor. P.Popov “Engineering Mechanics of Solids” Prentice Hall of India, New Delhi, 2007. 2. Subramanian R., "Strength of Materials", Oxford University Press, Oxford Higher Education

Series, 2010 3. Hibbeler, R.C., "Mechanics of Materials", Pearson Education, Low Price Edition, 2007.

Page | 24

ME205 KINEMATICS OF MACHINERY L T P C 3 0 0 3

OBJECTIVE:

To understand the basic components and layout of linkages in the assembly of a system/machine. To understand the principles in analyzing the assembly with respect to the displacement,

velocity, and acceleration at any point in a link of a mechanism. To understand the basic concepts of cam mechanisms and kinematics of gear trains.

Introduction to kinematics, mechanisms and machines, Elements of kinematic chain, mechanisms, their inversions, mobility (Kutzhbach criteria) and range of movements (Grashof's law) – Miscellaneous mechanisms: straight line generating mechanism, intermittent motion mechanism – Velocity (Relative and Instantaneous centre method) and acceleration (Relative method) analysis of planar mechanisms by graphical method – velocity and acceleration analysis of planar mechanisms by analytical methods – Dimensional synthesis for function, path and motion generation – Introduction to Cam, classifications, nomenclature, types of follower motions and Cam profile synthesis – Introduction to gear, classifications, nomenclature, types of gear profile, Interference and undercutting, contact ratio, minimum number of teeth – gear trains analysis: simple, compound and epicyclic gearing. OUTCOMES:

Upon completion of this course, the students can able to apply fundamentals of mechanism for the design of new mechanisms and analyze them for optimum design.

TEXT BOOKS: 1. A. Ghosh and A. K. Mallik, “Theory of Mechanisms and Machines”, 3rd Ed., East West Press

Pvt. Ltd, 2017. 2. S. S. Rattan, “Theory of Machines”, 3rd Ed., Tata McGraw Hill, 2017. 3. R.L.Norton, Kinematics & Dynamics of Machinery, McGraw Hill Education, 2017. 4. David H. Myszka, Machines and Mechanisms: Applied Kinematic Analysis, Pearson; 3rd

edition, 2005. 5. Thomas Bevan, Theory of Machines, CBS, 2005.

REFERENCE BOOKS: 1. J. J Uicker (Jr), G. R Pennock and J. E Shigley, “Theory of Machines and Mechanisms”, 3rd

ed., Oxford International, 2014.

Page | 25

ME207 ENGINEERING METALLURGY L T P C 3 0 0 3

OBJECTIVE: To impart knowledge on the structure, properties, treatment, testing and applications of

metals and non-metallic materials so as to identify and select suitable materials for various engineering applications.

FERROUS METALS: Carbon steels and Low alloy steels, Effects of alloying elements, Important low alloy steels, Stainless steels, Ferritic, Martensitic and Austenitic stainless steels, Maraging steels, Tool steels, Types, Cast irons, White iron, Malleable iron, Grey iron, Ductile iron. NON FERROUS METALS, CERAMICS AND COMPOSITES: Copper and copper alloys, Brasses, Bronzes, Alunium alloys, Temper designations for aluminium alloys, Heat treatable and non-heat treatable aluminium alloys, Nickel and Nickel alloys, Monel, Super alloys, Titanium and Titanium alloys, Alpha Ti alloys, Beta Ti alloys, Alpha-Beta Ti alloys, Nickel and nickel alloys, Ceramics, Glasses, Refractories, Types of refractories, Composites, Types of composites. MECHANICAL PROPERTIES, FAILURE OF METALS AND TESTING: Hardness, Brinell hardness test, Rockwell hardness test, Vickers Hardness test, Tensile properties, Tensile test, Toughness, Impact tests, Fatigue, Fatigue curves, Fatigue tests, Creep, Creep curve, Creep tests, Fracture, Ductile fracture, Brittle fracture, Non-Destructive Tests, X-ray radiography, Gamma ray radiography, ultrasonic test, Dye penetrant test, magnetic particle test. PHASE DIAGRAMS AND PHASE TRANSFORMATIONS: Phase, Gibbs phase rule, Microstructure, Binary phase diagrams, Isomorphous systems, Conditions of unlimited solubility, Eutectic systems, Intermediate phases, Eutectoid and peritectic reactions, Iron-Carbon diagram, Microstructures in Iron-Carbon alloys, Phase transformations, Isothermal transformation diagrams, Pearlite, Martensite and Bainite transformations, Tempered martensite, Continuous cooling transformation diagrams. HEAT TREATMENT AND STRENGTHENING METHODS: Heat treatment of steels, Annealing, Normalizing, Quench hardening, Tempering, Austempering, hardenability and hardenability test, Surface heat treatment / Case hardening, Carburising, Cyaniding, Nitriding, Flame hardening, Induction hardening, Strain hardening / Cold working and annealing, Three stages of annealing, Solid solution strengthening, Dispersion hardening, Precipitation / Age hardening, Strengthening by grain refinement. OUTCOMES:

Upon completion of this course, the students can able to apply the different materials, their processing, heat treatments in suitable application in mechanical engineering fields.

TEXT BOOKS:

1. William D Callister Jr, “Materials Science and Engineering-An Introduction”, John Wiley and Sons Inc., New York, 2009.

2. Donald R.Askeland, Pradeep P. Fulay and Wendelin J. Wright “Science and Engineering of Materials”, Thomson brooks, 2010.

3. George. E. Deiter, Mechanical Metallurgy, McGraw Hill Education; Third edition, 2017. 4. O.P.Khanna, Material Science and Metallurgy, Dhanpat Rai Publications, 2014.

Page | 26

REFERENCE BOOKS: 1. Sydney H Avner, “Introduction to Physical Metallurgy” Mc Graw Hill Book Company, 1997. 2. Kenneth G. Budinski and Michael K. Budinski ,“Engineering Materials: Properties and

Selection”, Prentice Hall, 2010. 3. Barry Hull and Vernon John, “Non Destructive Testing”, ELEBS/Macmillan,1989. 4. Raghavan V, “Physical Metallurgy: Principles and Practice”, Prentice-Hall of India Pvt.Ltd.,

2006.

Page | 27

ME209 MACHINING PROCESSES L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on metal cutting, lathe machines and tools THEORY OF METAL CUTTING: Introduction: material removal processes: Nomenclature of a single point cutting tool, mechanics of metal cutting, orthogonal and oblique cutting, Mechanism of chip formation, Types of chips, Use of chip breaker in machining, Machining forces and Merchant’s Circle Diagram (MCD), Cutting tool materials - Thermal aspects - tool wear and tool life, surface finish, cutting fluids. CENTRE LATHE AND SPECIAL PURPOSE LATHES: Centre lathe, constructional features, cutting tool geometry, various operations, taper turning methods, thread cutting methods, special attachments, Capstan and turret lathes – automats – single spindle, Swiss type, automatic screw type, multi spindle - Turret Indexing mechanism, Bar feed mechanism. OTHER MACHINE TOOLS: Reciprocating machine tools: Shaper, Planer, Slotter. Milling: types, milling cutters, operations – Hole making: drilling – Introduction, Reaming, Boring, Tapping – Other Hole - Making Operations - Sawing machine: hack saw, band saw, circular saw - Broaching machines: broach construction – push, pull, surface and continuous broaching machines. Work holding devices -Concept of Jigs and Fixtures and its applications. ABRASIVE PROCESSES AND GEAR CUTTING: Abrasive processes: Introduction - Grinding wheel: Designations and selection, types of grinding machines – cylindrical grinding, surface grinding, centre less grinding –Grinding Process parameters- honing, lapping, super finishing, polishing and buffing, - Gear cutting, forming, generation, shaping, hobbing. NON - TRADITIONAL MACHINING: Need for Non Traditional Machining, Electric-Discharge Machining (EDM) - Electrochemical Machining - Ultrasonic Machining - Chemical Machining - Laser Beam machining, Abrasive Water Jet machining (AWJM), Electron Beam Machining (EBM), Ion Beam Machining (IBM), Plasma Arc Machining (PAM) – Equipment - Process- Process parameters and Machining characteristics, Applications, Limitations.

OUTCOMES: Upon the completion of the course, the students are able to understand:

Basic concepts of metal cutting and non-traditional machining. Machine tools and their working in various manufacturing process

TEXT BOOKS: 1. P N Rao, “Manufacturing Technology – Metal Cutting & Machine Tools”, 3/e Tata McGraw-

Hill Publishing Company Limited, 2013. 2. Milton C Shaw, “Metal Cutting Principles”, Clarendon Press, Oxford, 1999.

REFERENCE BOOKS:

1. Serope Kalpakjian and Stephen Schmid,”Manufacturing, Engineering and Technology”, SI 7th Edition -”, Pearson Education, 2013.

2. Mikell P. Groover,” Principles of Modern Manufacturing”, SI Version Fifth Edition, Wiley & sons Pvt. Ltd, 2013.

3. James Brown, “Advanced Machining Technology Handbook”, McGraw Hill Book Company, New York, 1998.

Page | 28

ME211 MATERIAL TESTING LABORATORY L T P C 0 0 4 2

OBJECTIVE: To supplement the theoretical knowledge gained in Strength of Materials with practical testing for determining the strength of materials under externally applied loads.

LIST OF EXPERIMENTS: 1. Deflection test on beams. 2. Torsion test on different grades of steel. 3. Tensile and flexural strength using UTM 4. Compression test on concrete cube 5. Hardness test (Rockwell, Brinell, Vicker Hardness) 6. Impact test 7. Deflection test on open and closed coil springs 8. Fatigue test (Rotary fatigue) OUTCOMES: Upon completion of this course, the students can able to perform different destructive testing to characterize the material properties.

Page | 29

ME213 MATERIAL CHARACTERIZATION LABORATORY L T P C 0 0 4 2

OBJECTIVE: To understand the characterization techniques that identifies the material structure and its properties.

LIST OF EXPERIMENTS:

1. Introduction of metallographic sample preparation.

2. Optical microscopy of ferrous sample (Mild Steel, High Carbon Steel, Cast Iron, Stainless

Steel).

3. Optical microscopy of non-ferrous samples (Cu, Zink, Brass, Pb-Sn).

4. Image analysis and Quantitative metallography (grain size measurements).

5. Examine micro-features of a specimen by etching.

6. Micro-hardness measurements. OUTCOMES: Ability to handle different measurement tools to characterize a material.

Page | 30

ME215 MANUFACTURING PROCESSES LABORATORY L T P C 0 0 4 2

OBJECTIVE: To provide basic understanding on performing various production, metal cutting process.

LIST OF EXPERIMENTS: 1. Exercise on Sand Casting 2. Exercise in Lathe - Facing, Chamfering, Step turning, Taper turning, Knurling and Drilling,

Grooving, Thread Cutting 3. Exercise in Radial Drilling Machine - Drilling, Counter Boring, Counter Sinking and Tapping

exercise 4. Exercise in CNC Machine (including Part Programming) – Turning, Face and End Milling 5. Exercise on Surface and Cylindrical Grinding 6. Measurement of Cutting forces and Temperature in metal cutting 7. Exercise on Plastic Injection Moulding 8. Exercise using Tool and Cutter Grinder 9. Exercise on TIG Welding 10. Machining with Electric Discharge Machine.

OUTCOMES:

Upon the completion of the laboratory, the students are able to perform experiments in given production, metal cutting process.

Page | 31

SEMESTER IV

MA242 PROBABILITY AND STATISTICS L T P C 3 0 0 3

OBJECTIVE:

To impart knowledge on solving the probability and statistics problems. PROBABILITY: Sample spaces and events, interpretations of probability, addition rule, conditional probability, multiplication and total probability rules, independence, Baye’s theorem. RANDOM VARIABLES AND PROBABILITY DISTRIBUTIONS: Random variables - discrete random variables, probability distributions and probability mass functions, cumulative distribution functions, expectation, binomial, Poisson and geometric distributions - continuous random variables – probability distributions and probability density functions, cumulative distribution functions, expectation, uniform, normal, and exponential distributions - Data Sciences. JOINT PROBABILITY DISTRIBUTIONS: Two dimensional discrete and continuous random variables, marginal and conditional probability distributions, independence, covariance, correlation and linear regression. POINT ESTIMATION OF PARAMETERS AND SAMPLING DISTRIBUTIONS: Sampling distributions and the central limit theorem, point estimation - unbiased estimators, variance of a point estimator, standard error and mean squared error of an estimator, method of point estimation - maximum likelihood estimation. TESTING OF HYPOTHESIS: Statistical hypothesis, tests of statistical hypothesis, one - sided and two–sided hypothesis, confidence intervals, large and small sample tests, inference concerning means, variances and proportions - Chi-square test for goodness of fit and independence of attributes. OUTCOMES: On successful completion of the course, the student will be able to,

Solve probability and statistics problems. Apply Hypothesis testing and ANOVA.

TEXT BOOKS: 1. Douglas C. Montgomery and George C. Runger, Applied Statistics and Probability for

Engineers, Wiley India, Delhi, 2012. 2. Richard A. Johnson, Miller & Freund’s, Probability and Statistics for Engineers, Prentice Hall,

New Delhi, 2009. REFERENCE BOOKS:

1. Jay L. Devore, Probability and Statistics for Engineering and the Sciences, Brooks/Cole, USA, 2012.

2. Ronald E. Walpole, Raymond H. Myers, Sharon L. Myers and Keying Ye, Probability & Statistics for Engineers & Scientists,Pearson Education, New Delhi, 2007.

Page | 32

ME202 HEAT AND MASS TRANSFER L T P C 3 0 0 3

OBJECTIVE:

To understand the mechanisms of heat transfer under steady and transient conditions. To understand the concepts of heat transfer through extended surfaces. To learn the thermal analysis and sizing of heat exchangers and to understand the basic

concepts of mass transfer. (Use of standard HMT data book is permitted)

Basics of Conduction Convection and Radiation - General conduction equation – Steady State problems - Heat generation problems - Fins - Unsteady heat conduction – Lumped parameter analysis. Forced Convection - Boundary layer theory - External flow – Flat plate, cylinder, sphere - Internal flow – Flow through circular and non-circular channels - Free convection - Correlations. Boiling and condensation - Boiling regimes and correlations, Nusselt's theory - Condensation over surfaces. Heat exchangers - Fouling factor, LMTD and NTU methods. Radiation Laws - Black and Gray bodies - Radiation exchange between surfaces – Radiation shields. Mass transfer - Fick's law – Diffusion mass transfer - Convective mass transfer. OUTCOMES:

Upon completion of this course, the students can able to understand and apply different heat and mass transfer principles of different applications.

TEXT BOOKS: 1. Theodore L. Bergman, Adrienne S. Lavine, Frank P. Incropera, David P. DeWitt,

Fundamentals of Heat and Mass Transfer, 5th ed., JohnWiley,2002. 2. R.C.Sachdeva, Fundamentals of Engineering Heat and Mass Transfer, New Age Science

Publishers, 2012 REFERENCE BOOKS:

1. Ozisik, M.N., Heat Transfer - A Basic Approach, McGraw-Hill, 1985. 2. Yunus A. Cengel, "Heat Transfer A Practical Approach", Tata McGraw Hill, 2010 3. Yadav, R., "Heat and Mass Transfer", Central Publishing House, 1995. 1. Kothandaraman, C.P., "Fundamentals of Heat and Mass Transfer", New Age International,

New Delhi, 1998. 2. 5.M.Thirumaleshwar : Fundamentals of Heat and Mass Transfer, "Heat and Mass Transfer", 3. First Edition, Dorling Kindersley, 2009 4. Holman, J.P., Heat Transfer, 9th ed., Tata McGraw-Hill, 2004. 5. Nag, P.K., "Heat Transfer", Tata McGraw Hill, New Delhi, 2002 6. Eckehard Specht, Heat and Mass Transfer in Thermoprocessing, Vulkan Verlag, 2017, ISBN

– 97838 02729911.

Page | 33

ME204 DYNAMICS OF MACHINERY L T P C 3 0 0 3

OBJECTIVE:

To understand the force-motion relationship in components subjected to external forces and analysis of standard mechanisms.

To understand the undesirable effects of unbalances resulting from prescribed motions in mechanism.

To understand the effect of Dynamics of undesirable vibrations. To understand the principles in mechanisms used for speed control and stability control

Static and dynamic force analysis of mechanisms; Flywheel function and design; Balancing of rotating and reciprocating masses in one and several planes; Governors; Gyroscope and gyroscopic effect; Vibrations of one degree of freedom systems; Free, damped and Force vibrations; Transverse and torsional vibrations of two and three rotor systems; critical speeds; Introduction to two and multi-degree of freedom vibration system; Vibration isolation, measurements and control.

OUTCOMES:

Upon completion of this course, the Students can able to predict the force analysis in mechanical system and related vibration issues and can able to solve the problem.

TEXT BOOKS: 1. S. S. Rattan, “Theory of Machines”, 3rd Ed., Tata McGraw Hill, 2009. 2. J. J Uicker (Jr), G. R Pennock and J. E Shigley, “Theory of Machines and Mechanisms”, 3rd

ed., Oxford International, 2003. 3. R.L.Norton, Kinematics & Dynamics of Machinery, McGraw Hill Education, 2017.

4. David H. Myszka, Machines and Mechanisms: Applied Kinematic Analysis, Pearson; 3rd

edition, 2005.

5. Thomas Bevan, Theory of Machines, CBS, 2005.

REFERENCE BOOKS: 1. V. P. Singh, “Mechanical Vibrations”, DhanpatRai & Co. Pvt Ltd, 2015. 2. T. Gowda, T. Jagadeesha, D. V. Girish, “Mechanical Vibrations”, Tata McGraw Hill, 2012.

Page | 34

ME206 FLUID MECHANICS AND MACHINERY L T P C 3 0 0 3

OBJECTIVE: To provide basic understanding on the concepts fluids, flows, control valves. To understand

and apply the fundamental governing equations for a given flow field. To gain a knowledge on the different mathematical framework and apply them to the solutions

of real world problems. To understand the importance of dimensional analysis. To realize the concepts of fluid mechanics and its relevant applications in the current scenario.

Classifications of flows, properties of fluids, Pressure measurements, Hydrostatic force on a submerged plane and curved surfaces – Buoyancy and floatation- Metacentric height and its determination. Bernoulli’s equation – applications – venturi meter, orifice meter and Pitot tube Fluid Kinematics – Classification of flow – Velocity field and acceleration - Continuity equation- stream line-streak line-path line- stream function – velocity potential function -Fluid rotation and deformation - Condition of irrotationality. Fluid dynamics; integral and differential formulations - Continuity equation Relation between shear stress and pressure gradient - Navier-Stokes equations – Exact solutions of Navier-Stokes equation - Couette Flow and Poiseuille flow. Boundary layer concept - Prandtl's equation - Drag on flat plates Flow through pipes – Darcy–Weisbach’s equation – pipe roughness - friction factor - Moody’s diagram- major and minor losses of flow in pipes – pipes in series and in parallel. Fundamental dimensions – Dimensional homogeneity – Rayleigh’s method and Buckingham Pi theorem - dimensionless numbers and its physical significance – similitudes and model studies. Introduction of Turbomachines - Classification - Dimensional analysis - Specific speed - Basic laws and equations. Hydraulic turbines; Pelton, Francis, and Kaplan turbines - Turbine efficiencies - Cavitation in turbines. Centrifugal pumps; theory, components, and characteristics - Cavitation - Axial flow pumps - Pump system matching. Centrifugal and axial flow compressors; slip, surging and chocking. OUTCOMES: Upon completion of this course, the students can able to apply their mathematical knowledge to seek the solutions for the various flow field.

TEXT BOOKS: 1. Fox, R.W. and McDonald, A.T., Introduction to Fluid Mechanics, 6th ed., John Wiley, 2003. 2. White, F.M., Fluid Mechanics, 5th ed., McGraw-Hill, 2003. 3. S.L.Dixon and C.A.Hall, Fluid Mechanics and Thermodynamics of Turbomachinery, Elsevier; Seventh edition (2014) REFERENCE BOOKS: 1. Streeter, V. L. and Wylie E. B., Fluid Mechanics, McGraw Hill Publishing Co. 2010 2. Robert L. Street, Gary Z. Watters, John K. Vennard, Elementary Fluid Mechanics. Seventh edition, 1995. 3. Graebel. W.P, "Engineering Fluid Mechanics", Taylor & Francis, Indian Reprint, 2011 4. F.M. White, Viscous Fluid Flow, McGraw-Hill (Any edition) 5. Pijush Kundu Ira Cohen David Dowling, Fluid Mechanics, Sixth edition, Academic Press, 2015 6. Spurk, Joseph, Aksel, Nuri, Fluid Mechanics, Springer, 2008

Page | 35

ME208 MACHINE DRAWING L T P C 1 0 4 3

OBJECTIVE:

To understand the representation of materials used in machine drawing To construct an assembly drawing using part drawings of machine components To introduce the process drawing concepts to make cost estimation for various products after

process drawing. INTRODUCTION: Introduction to machine drawing. Types and importance of sectional views, solid modeling and sectioning of mechanical elements. CONVENTIONS: Code of practice for engineering drawing, Conventional representation of details – drilled, tapped, countersunk and counter bored holes, internal and external threads. Conventions to represent standard components - bolt, nuts, washers, screws, rivets, cotters, pins, keys, circlips, bearings, gears, springs and flanges. LIMITS, FITS AND TOLERANCES: Limits, fits and tolerances - types, representation of tolerances on drawing, calculation of minimum and maximum clearances and allowances. Geometric tolerance - uses, types of form and position tolerances, symbols, method of indicating geometric tolerances on part drawings. Surface finish symbols - methods of indicating the surface roughness. ASSEMBLY USING SOLID MODELING: Introduction - methods and concepts of assemblies, assembly requirements, importance of bill of materials. Solid modeling - Commands used for modeling and assembly of components using CAD software, creation of bill of materials and balloons, extraction of 2D views and sections. PRACTICE SESSION: Various views of the assemblies of following components – Flange coupling, cotter joints, knuckle joint, screw jack, universal coupling, pipe vice and plummer block in drawing sheet and using CAD software. OUTCOMES: Upon completion of this course, the students will be able able to,

Mention the representation of machine elements Represent tolerances and the levels of surface finish of machine elements Draw the different types of machine elements, tool elements and transmission system Use the concepts of process planning and cost estimation for various products

TEXT BOOKS: 1. Gopalakrishna K R, "Machine Drawing", Subhas Stores, Bangalore, 2013. 2. John K C, "Text book of Machine Drawing", PHI Learning Pvt. Ltd., New Delhi 2009. REFERENCE BOOKS: 1. BIS, SP:46-2003 – “Engineering Drawing Practice for Schools and Colleges", New Delhi, 2003. 2. ASME Y 14.5M-2009, “Dimensioning and Tolerancing-Engineering Drawing and Related Documentation Practices”, ASME, New York, 2009.

Page | 36

ME210 AUTOMOBILE ENGINEERING L T P C 3 0 0 3

OBJECTIVE: To understand the construction and working principle of various parts of an automobile. UNIT -I Types of automobiles, vehicle construction and different layouts, chassis, frame and body, resistances to vehicle motion and need for a gearbox, components of engine-their forms, functions and materials.

UNIT -II Electronically controlled gasoline injection system for SI engines, Electronically controlled diesel injection system (Unit injector system, Rotary distributor type and common rail direct injection system), Electronic ignition system,Turbo chargers, Engine emission control by three way catalytic converter system.

UNIT-III Clutch-types and construction, gear boxes-manual and automatic, gear shift mechanisms, Over drive, transfer box, fluid flywheel –torque converter , propeller shaft, slip joints, universal joints, Differential, and rear axle, Hotchkiss Drive and Torque Tube Drive.

UNIT-IV Steering geometry and types of steering gear box-Power Steering, Types of Front Axle, Types of Suspension Systems, Pneumatic and Hydraulic Braking Systems, Antilock Braking System and Traction Control, Electrical systems; construction, operation, and maintenance of batteries -Starter motors. Lighting and electrical accessories .Panel board instruments -Automobile air conditioning -Troubleshooting.

UNIT -V Conventional and alternate fuels in Automobiles - Engine modifications – Performance, Combustion and Emission Characteristics of SI and CI engines with these alternate fuels – Electric and Hybrid Vehicles, Fuel Cell.

OUTCOMES: Upon completion of this course, the students can able to know the principle of various parts of an automobile. TEXT BOOKS: 1. Kirpal Singh, Automotive Engineering, Vol. I & II, Standard Publishers, New Delhi,2002. 2. R.B.Gupta , Automobile Engineering, Satya Prakashan, New Delhi, 1997. 3. W. Crouse and D. Anglin, Automotive Mechanics, McGraw Hill Education, 2017. REFERENCE BOOKS:

1. Heitner, J. Automotive Mechanics Principle and Practice, 2nd ed., Affiliated East-West Press Ltd., 1974.

2. Newton, K., Steeds, W., and Garrett, T.K., The Motor Vehicle, Butterworths, 1989. 3. Jain K.K. and Asthana .R.B, “Automobile Engineering” Tata McGraw Hill Publishers, New

Delhi, 2002. 4. W.H.Crouse, Automotive Mechanics, Tata McGraw Hill Publishing Co., 1995. 5. V.L.Maleev, Internal Combustion Engines, McGraw Hill, 1987. 6. Joseph Heitner, Automotive Mechanics, CBS Publishers & Distributors, 1987. 7. R.B.Gupta., Auto Design, Satya Prakashan, New Delhi, 1995.

Page | 37

ME212 DYNAMICS LABORATORY L T P C 0 0 4 2

OBJECTIVE:

To supplement the principles learnt in kinematics and dynamics of machinery.

To understand how certain measuring devices are used for dynamic testing. LIST OF EXPERIMENTS:

1. Develop the understanding of different types of links, joints, mechanism, its actions and traces

using the kit provided.

2. Understand the Grashoff criterion and its inversions using the kit provided.

3. Measure the input, output and holding torque using spring balance to study torque relationship

and verify the correlation between speed and torque in epicyclic gear train.

4. Natural frequency of single mass, single helical spring system.

5. Natural frequency of combination of springs –springs in parallel, springs in series.

6. Natural frequency of undamped torsional single rotor, double rotor system. Effect of inertia (I)

and stiffness (kt).

7. Determination of characteristic curves of governors.

8. Static and Dynamic balancing of simple rotating mass system.

9. Cam motion analysis.

OUTCOMES: Upon successful completion of this course, the students will be able to,

Ability to demonstrate the principles of kinematics and dynamics of machinery.

Ability to use the measuring devices for dynamic testing. REFERENCE BOOKS: 1. Laboratory Manual Prepared by the Department.

Page | 38

ME214 FLUID MECHANICS AND MACHINERY

LABORATORY L T P C 0 0 4 2

OBJECTIVE:

Upon Completion of this subject, the students can able to have hands on experience in flow measurements using different devices and also perform calculation related to losses in pipes.

LIST OF EXPERIMENTS:

1. Determination of Metacentric height of buoyancy 2. Determination of force due to impact of jets 3. Determination of co-efficient of discharge of venturi meter 4. Determination of co-efficient of discharge of orifice meter 5. Determination of major losses and minor losses in pipe flow 6. Verification of Bernoulli’s Principle 7. Flow visualization on an ideal flow 8. Wake velocity measurement for flow over a circular cylinder 9. Vortex shedding from a cylinder in a water channel 10. Determination of the surface and distribution of the total height of the free vortex 11. Study of forced vortex 12. Pressure measurement using pressure transducer 13. Study and performance test of the any five following hydraulic machines

a. Centrifugal Pump b. Reciprocating Pump c. Jet – Pump d. Submersible Pump e. Parallel & Series Pump f. Gear Pump g. Pelton Wheel Turbine h. Francis Turbine

OUTCOMES: Upon the completion of course, the students are able:

To use the measurement equipment for flow measurement REFERENCE BOOKS: 1. Laboratory Manual Prepared by the Department.

Page | 39

SEMESTER V

ME301 ENGINEERING MEASUREMENTS L T P C 3 0 0 3

OBJECTIVE:

To provide knowledge on the various mechanical measurement techniques Measurements, Error analysis and Design of Experiments.

Measurements of Temperature, Heat Flux, Heat Transfer Coefficient, Thermal Conductivity, Heat Capacity, Calorific value of fuels, Viscosity, Emissivity, Gas concentration.

Measurements of Pressure, Fluid Velocity, Volume Flow Rate

Measurements of Force, Acceleration, Torque, Power, Strain.

Data manipulation – Mechanical signal conditioning & Electrical / Electronics Signal Conditioning.

OUTCOMES:

Upon completion of this course, the Students can demonstrate different measurement technologies.

TEXT BOOKS: 1. J P Holman, Experimental Methods for Engineers, McGraw-Hill, 2011. 2. S P Venkateshan, Mechanical Measurements, Anne Books Pvt. Ltd., 2015. 3. Thomas G Beckwith, N Lewis Buck and Roy D Marargoni, “Mechanical Measurements”,

Narosapublishing house, 1989. 4. Gupta, I.C., Engineering Metrology, DhanpatRai& Sons, 2004.

REFERENCE BOOKS: 1. Turner, J.D., “Instrumentation for Engineers”, Springer – Verlag, New York Inc., 1988. 2. B.C.Nakra and Chaudhry, K.K.,“Instrumentation and Analysis”,TMH, 1985. 3. Doeblin E.O., Measurement Systems, McGraw-Hill, 2004. 4. Harshavardhan, “Measurements – Principles and Practice”, Macmillan India Limited,1993.

Page | 40

ME303 THERMAL ENGINEERING L T P C 3 0 0 3

OBJECTIVE: To integrate the concepts, laws and methodologies from the first course in thermodynamics

into analysis of cyclic processes. To apply the thermodynamic concepts into various thermal applications like IC engines, Steam

Nozzles, Steam Turbines and Compressors systems. To understand the basic difference between incompressible and compressible flow. To understand the phenomenon of shock waves and its effect on flow. To gain some basic knowledge on Refrigeration & Air-conditioning

(Use of standard Steam Tables, Mollier diagram, Gas Tables is permitted)

Reciprocating air compressors - types - construction - work of compression without clearance -effect of clearance – Multistaging - optimum intermediate pressure for perfect intercooling - Compressor efficiencies and mean effective pressure. Working of two and four stroke engines - valve and port timing diagrams – I.C. engines fuels and rating - SI engine air fuel mixture requirements - Battery Ignition - magneto ignition and transistorized coil ignition - Combustion in SI & CI engines - Combustion chambers for SI and CI engines.

Steam Nozzles – Flow through nozzles – nozzle efficiency; Steam turbines - impulse and reaction turbines – Efficiency calculations.

Compressible Flow – Static and Stagnation properties - Speed of sound and Mach Number. Isentropic flow through variable area passage ducts. Choking of flow. Normal and oblique shocks - Prandtl-Meyer flows. Fanno flow - Rayleigh flow.

Refrigeration - Introduction – Air refrigeration cycles and systems; Refrigerant - Selection and properties of refrigerant; Vapor Compression & Vapor absorption refrigeration systems; Introduction to Psychrometry – Properties of atmospheric air and psychrometric process; Air-conditioning systems – Cooling load calculations; Applications of R & AC.

OUTCOMES:

Upon completion of this course, the students can able to apply the different gas power cycles and use of them in internal combustion engine applications.

Upon completion of this course, the students can able to successfully apply principles of compressible flow and refrigeration and air-conditioning to practical systems.

TEXT BOOKS:

1. Ganesan, V., Internal Combustion Engines, Tata McGraw-Hill, 2017. 2. Yahya, S.M., Fundamentals of Compressible Flow with Aircraft and Rocket Propulsion, 3rd

ed., New Age International Publishers, 2016.

REFERENCE BOOKS: 1. Ballaney, P.L., Thermal Engineering, Khanna Publishers, 2002. 2. Sarkar, B.K,”Thermal Engineering” Tata McGraw-Hill Publishers, 2017 3. Rudramoorthy, R, “Thermal Engineering “, Tata McGraw-Hill, New Delhi, 2003 4. Ramalingam. K.K., "Thermal Engineering", SCITECH Publications (India) Pvt. Ltd., 2009. 5. Heywood, J.B., Fundamentals of Internal Combustion Engines, McGraw-Hill, 2017.

Page | 41

6. Kothandaraman.C.P., Domkundwar.S, Domkundwar.A.V.,“AcourseinthermalEngineering", Fifth Edition,”DhanpatRai&sons, 2002.

7. Rajput. R. K., “Thermal Engineering” S.Chand Publishers, 2000

Page | 42

ME305 DESIGN OF MACHINE ELEMENTS L T P C 3 0 0 3

OBJECTIVE:

To familiarize the various steps involved in the Design Process.

To understand the principals involved in evaluating the shape and dimensions of a component to satisfy functional and strength requirements.

To learn to use standard practices and standard data.

To learn to use catalogues and standard machine components. (Use of P S G Design Data Book is permitted)

Fundamentals of machine design: Design considerations, Material selection, Factors to be considered

for material selection – Stresses in machine elements – Modes of failure – Theories of failure –

Endurance limit – Stress concentration – Factor of safety – Design for strength: Design for static

loading, design for dynamic loading, low and high cycle fatigue – Design of shafts, keys and couplings

– Design of riveted, bolted, and welded joints – Design of helical and leaf springs – Design of bearings.

OUTCOMES:

Upon completion of this course, the students can able to successfully design machine components.

TEXT BOOKS: 1. R. G. Budynas and J. K. Nisbett, “Shigley’s Mechanical Engineering Design”, Tata McGraw

Hill, 2008. 2. V. B. Bhandari, “Design of Machine Elements”, 2nd Ed., Tata Mcgraw Hill, 2007. 3. T. V. Sundararajamoorthy and N. Shanmugam, “Machine Design”, Anuradha Agencies, 2003. 4. “Design Data Book of Engineers”, Compiled by Faculty of Mechanical Engineering, PSG

College of Technology, Publisher Kalaikathir Achchagam, Coimbataore, 2009. 5. Robert L. Norton, Machine Design, Pearson, 5th Edition, 2013.

Page | 43

ME307 COMPUTER AIDED DESIGN L T P C 3 0 0 3

OBJECTIVE:

To provide an overview of how computers are being used in mechanical component Design

To provide an outline on geometric modelling CAD hardware - Product cycle - CAD tools, CAD systems; system evaluation, CAD specific I/O devices. CAD software - Graphic standards.

Modes of graphics operation, Software Modules.

Geometric modeling – Types and mathematical representation and manipulation of curves and surfaces.

Solid modeling- fundamentals, feature based modeling manipulations of solid models.

Transformation of Geometric models and visual realism - Animation.

OUTCOMES:

Upon completion of this course, the students can able to perform basic 2D and 3D geometric Transformations.

Able to interpret and develop parametric models of simple curves, surfaces and solids TEXT BOOKS:

1. Ibrahim Zeid - CAD/CAM Theory and Practice, Tata McGraw Hill Publishing Co. Ltd., New Delhi, 2005.

2. M.P.Groover and E.W.Zimmers - CAD/CAM; Computer Aided Design and Manufacturing, Tata McGraw Hill Publishing Co. Ltd., New Delhi, 2006.

REFERENCE BOOKS: 1. Rogers, D.E and Adams, J.A., Mathematical Elements for Computer Graphics, 2nd ed., McGraw-

Hill, 1990. 2. P.Radhakrishnan et al - CAD/CAM/CIM, New Age International P Ltd., New Delhi, 2006. 3. Chris Mcmahon and Jimmie Browne - CAD/CAM – Principle Practice and Manufacturing

Management, 2nd Edition, Addision Wesley England, 2000.

Page | 44

ME309 FINITE ELEMENT ANALYSIS L T P C 3 0 0 3

OBJECTIVE:

To introduce the concepts of Mathematical Modeling of Engineering Problems. To apply the use of FEM to a range of Engineering Problems.

Introduction - Illustration using spring systems and simple problems - Weighted residual methods Galerkin's method - Variational approach - Rayleigh-Ritz method. Finite Element Modeling - Co-ordinates and shape functions - Potential Energy approach One-dimensional finite element analysis; bar element, beam element, frame element – Heat Transfer problems. Two-dimensional finite element analysis; types of elements, shape functions, iso-parametric elements, coordinate systems. Applications to structural mechanics - Numerical integration - Solution of finite element equations. Application to heat transfer problems - Dynamic Analysis problems.

OUTCOMES:

Upon completion of this course, the students can able to understand different Mathematical modelling techniques used in FEM analysis and use of them in Structural and thermal problem.

TEXT BOOKS:

1. T.R Chandrupatla, A.D Belegundu and T. Ramesh, Introduction to Finite Elements in Engineering, Pearson education, 4th Edition, 2012.

2. Seshu, P., Textbook of Finite Element Analysis, Prentice-Hall, India, 2003. 3. Frank L. Stasa, Applied Finite Element Analysis for Engineers, CBS International, Edition,


1. Segerlind, L.J., Applied Finite Element Analysis, John Wiley, 1987. 2. S.S.Rao, Finite Element Method in Engineering, Pergamon Press, 1989. 3. Cook Robert Devis et al, Concepts and Application of finite Element Analysis, Wiley John

&Sons, 1999. 4. G.Buchaman, Schaum’s Outline of finite Element Analysis, McGraw Hill, 1995. 5. J.N.Reddy, An Introduction to Finite Element Method, McGraw Hill International Edition,

1993. 6. David V Hutton, Fundamentals of Finite Element Analysis, McGraw-Hill Higher Education,

2003.

Page | 45

ME311 MEASUREMENTS LABORATORY L T P C 0 0 4 2

List of Experiments (Part A – Any Six Experiments)

1. Measurement of pressure using pressure transducer 2.Measurement of temperature using RTD and Thermistors 3. Measurement of Heat Flux guage 4. Measurement of Thermal Conductivity using square guarded hot plate apparatus for solid and liquid samples 5. Measurement of Thermal Conductivity for gases using radial heat conduction apparatus 6. Measurement of Emissivity 7. Measurement of Force, Acceleration, Torque and Power. 8. Measurement of Volume Flow Rate using rotometer and turbine flow meter. REFERENCE BOOKS:


Page | 46

ME313 THERMAL ENGINEERING LABORATORY L T P C 0 0 4 2

OBJECTIVE:

To study the valve timing diagram and performance of IC Engines To study the characteristics of fuels/Lubricates used in IC Engines To study the heat transfer phenomena to predict the relevant coefficient To study the performance of refrigeration cycle and air conditioning components.

List of Experiments (Part A and Part B) Part A: Heat Transfer and Refrigeration & Air Conditioning (Any Six Experiments) 1. Study and performance tests on refrigeration – Vapour Compression 2. Study and performance tests on air conditioning test rig – Vapour Compression. 3. Performance test on cooling tower. 4. Determination of dryness fraction of steam using calorimeter. 5. Determination of Thermal Resistance and Conductivity of a insulating material square guarded apparatus 6. Heat Transfer from Cylindrical Surface by Natural Convection 7. Heat Transfer from Cylindrical Surface by Forced Convection 8. Heat Transfer from Pin Fin by Forced Convection 9. Performance of Parallel Flow/Counter Flow Heat Exchanger 10. Determination of Calorific value of Solid Fuel using Bomb Calorimeter 11. Determination of Calorific value of Gaseous Fuel using Junker’s Gas Calorimeter Part B: IC Engines (Any Six Experiments) 1. Valve and port timing diagrams of 4 stroke and 2 stroke IC engines respectively 2. Tests on single cylinder petrol engine: (a) Load test (b) finding air-fuel ratio 3. Tests on multi-cylinder petrol engine: (a) Load test (b) Morse test (c) heat balance test 4. Tests on single cylinder 4 stroke diesel engine: (a) Load test (b) Finding air-fuel ratio 5. Test on multi-cylinder diesel engine: (a) Load test (b) Heat balance test 6. Determination of Kinematic Viscosity using Redwood viscometer 7. Determination of Flash and Fire Points using Cleaveland Apparatus. 8. Performance test on Reciprocating Air Compressor 9. Performance test on Centrifugal Air Blower 10. Study on the composition of Exhaust gas of an IC engine using Orsat Apparatus under various loads. 11. Study and performance testing of IC engines & Emission measurements.

OUTCOMES:

Ability to conduct experiment on IC engine to study the characteristic and performance of IC design/ steam turbines.

Ability to demonstrate the fundamentals of heat and predict the coefficient used in that transfer applications and also design refrigeration cycle.

REFERENCE BOOKS:


Page | 47

ME315 CAD LABORATORY L T P C 0 0 4 2

OBJECTIVE:

To gain practical experience in handling 2D drafting and 3D modeling software systems.

To gain knowledge on Preparation of Drawings for Parts and Assembly of the products. LIST OF EXPERIMENTS

1. 2D geometric modelling and manipulation 2. 3D geometric modelling and manipulation of parts (Joints, couplings, screw jack, Connection

rod) 3. Product Assembling 4. Generative & Interactive drafting 5. Automation in CAD

OUTCOMES: At the end of the course, the student will be able to:

To develop 2D and 3D models using modeling softwares. To do assembling and drafting of mechanical components Write programs for automation.

REFERENCE BOOKS:


Page | 48

SEMESTER VI

ME302 INDUSTRIAL ENGINEERING AND OPERATIONS

RESEARCH L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on concepts in Industrial Engineering and Operations Research

Work Systems Engineering - Plant Design – Production Planning and Cost Estimation - Lean Manufacturing - Maintenance Engineering - Six Sigma Concepts – Human Factors Engineering – Industrial Safety. Introduction to Operations Research - Linear Programming Techniques - Transportation Problems - Assignment Models – Scheduling - Inventory Control - Queuing Models - Project Management by PERT and CPM - Game Theory - Replacement Models. OUTCOMES: Upon the completion of the course, the students are able to

Get Knowledge about Industrial Engineering practices Get knowledge about the application of Operations Research

TEXT BOOKS:

1. Buffa E S, Sarin R K, “Modern Production / Operations Management”, John Wiley & Sons Inc, Delhi, 2007.

2. Hamdy A Taha, “Operations Research – An Introduction”, Pearson Education, New Delhi, 2014.

3. Introduction to Work Study, ILO. 4. S.R.Devadasan, V.Mohan Sivakumar, V.Murugesh, P.R.Shalij, ‘Lean and Agile

Manufacturing’, Prentice Hall India, 2012. REFERENCE BOOKS:

1. Prem kumar Gupta and Hira.D.S, “Operation Research”, S Chand and Company Limited, New Delhi, 2010.

2. Frederick S. Hillier and Gerald J. Lieberman,” Introduction to Operations Research”, McGraw-Hill, 2012

Page | 49

ME304 ENERGY ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To provide an idea of the challenges in the field of energy management and to provide a perspective on energy technology.

Students will learn the systems dimensions of the energy problems and its historical perspective on energy technology and system development.

For different types of energy sources utilization in industries, the procedure of power generation, transportation along with conventional and advanced application in different sectors should be known by the student.

Thermal power plant, Diesel power plant, gas turbine power plant, Nuclear power plant, hydroelectric power plant. Rankine cycle-superheat, reheat and regeneration, super critical cycles, combined cycles - binary cycles, cogeneration. Types of combustion, stokers, fuel and ash handling equipment. Selection of fans. Emission control, flue gas cleaning, particulate and gaseous emission control methods. Steam generators-types, forced circulation, high-pressure boilers and super critical boilers, fluidized bed boiler, boiler accessories and mountings, Draft- forced, induced and balanced drafts, Heat recovery equipment’s-economizers, air preheaters and reheaters, different types of superheaters and de-super heaters, Boiler testing, development of a process flow diagram, heat and mass balance of the components of a process flow diagram. Condensers and Cooling Towers, different types, design factors, air removal, performance calculation. Cooling towers-natural and mechanical draft types. Power Plant Economics, Plant load factor and utilization factor, cost economics – tariff rates, demand changes, load distributions. Energy conversion and audit. An Introduction to Energy Sources - Solar Energy - Wind Energy - Energy from Biomass - Fuel Cell – Hydrogen - Nuclear Energy. OUTCOMES: Upon completion of this course, the students can able. 1. To be aware about all the energy sources available and the ways to turn it into power. 2. To understand the principles behind different non-conventional energy sources. 3. To understand the global scenario of energy sector and to work on better economical solutions of it. 4. To utilize the renewable energy in problem solving where conventional energy are not fruitful and require replacement. 5. To understand the design and applications of power generating devices using renewable energy sources as per industrial requirement. TEXT BOOKS:

1. Nag P K, “Power Plant Engineering”, Tata McGraw Hill, New Delhi, 2004. 2. Wakil M M El, “Power Plant Technology”, McGraw Hill Book Company Inc., New Delhi,

1985. 3. Sukhatme, S.P., Solar Energy: Principle of Thermal Collection and Storage, 2nd ed.,

Tata McGraw Hill, 2000. 4. Rao, S. and Parulekar, R.B., Energy Technology - Nonconventional, Renewable and

Conventional, Khanna Publishers, 2009. REFERENCE BOOKS:

1. Rai, G.D., Nonconventional Energy Sources, Khanna Publishers, 2004.

Page | 50

2. Le Gourieres, D., Wind Power Plant - Theory and Design, Pergaman Press, 1982. 3. Godfrey Boyle, "Renewable Energy, Power for a Sustainable Future", Oxford University

Press,U.K., 2012. 4. Tiwari. G.N., Solar Energy – "Fundamentals Design, Modelling & Applications", Narosa

Publishing House, New Delhi, 2002. 5. Freris. L.L., "Wind Energy Conversion Systems", Prentice Hall, UK, 1990. 6. Johnson Gary, L. "Wind Energy Systems", Prentice Hall, New York, 2006. 7. David M. Mousdale – "Introduction to Biofuels", CRC Press, Taylor & Francis Group,

USA2010 8. Chetan Singh Solanki, Solar Photovoltaics, "Fundamentals, Technologies and Applications",

PHI Learning Private Limited, New Delhi, 2009. 9. Twidell, J.W. & Weir, A., "Renewable Energy Sources", EFN Spon Ltd., UK, 2006 10. Solar Energy by Sukatame, Tata McGraw Hill, New Delhi 11. Energy Technology by Rao & Parulaker. 12. Energy Sources 2nd Ed. by G. D. Rai, Khanna Publications, NewDelhi

Page | 51

ME306 COMPUTATIONAL FLUID DYNAMICS L T P C 3 0 0 3

OBJECTIVE:

To introduce Governing Equations of viscous fluid flows To introduce numerical modelling and its role in the field of fluid flow and heat transfer To create confidence to solve complex problems in the field of fluid flow and heat transfer by

using high speed computers. Methods to solve system of linear equations. Governing equations of fluid flow and heat transfer - Classification of partial differential equations - Discretization methods Finite difference and finite volume formulations. Numerical solution of elliptical equations - Numerical solution of parabolic equations - Stability analysis - Numerical solution of hyperbolic equations Incompressible Navier-Stokes equations and algorithms - Basics of grid generation – Basic concepts of

turbulent flow.

OUTCOMES: Upon completion of this course, the students can able

To formulate a numerical modelling in the field of fluid flow and heat transfer

TEXT BOOKS: 1. Tannehill, J.E., Anderson, D.A., and Pletcher, R.H., Computational Fluid Mechanics and Heat Transfer, 2nd ed., Taylor & Francis, 1997. 2. Hoffmann, K.A. and Chiang, S.T., Computational Fluid Dynamics for Engineers, Engineering Education Systems, 2000. REFERENCE BOOKS: 1. Versteeg, H.K. and Malalasekera, W., An Introduction to Computational Fluid Dynamics – The finite volume method, Longman Scientific & Technical, 1995. 2. Patankar, S.V., Numerical Heat Transfer & Fluid Flow, Hemisphere, 1980 3. Numerical method for Scientific & Engineering, Joe D HoffMan, Mc.Graw Hill 4. Anderson J.D., Computational Fluid Dynamics – The basics with applications, McGraw- Hill, 1995.

Page | 52

ME308 DESIGN OF TRANSMISSION ELEMENTS L T P C 3 0 0 3

OBJECTIVE:

To gain knowledge on the principles and procedure for the design of mechanical power transmission components.

To understand the standard procedure available for design of transmission of mechanical elements.

To learn to use standard data and catalogues

(Use of P S G Design Data Book is permitted)

Introduction to transmission elements – Design of belt, rope and chain drives – Design of spur and

helical gears based on contact and beam strength – Design of bevel and worm gears – Design of

multi-speed gearbox – Design of clutches and brakes.

OUTCOMES:

Upon completion of this course, the students can able to successfully design transmission components used in Engine and machines.

TEXT BOOKS: 1. R. G. Budynas and J. K. Nisbett, “Shigley’s Mechanical Engineering Design”, Tata McGraw

Hill, 2008. 2. V. B. Bhandari, “Design of Machine Elements”, 2nd Ed., Tata Mcgraw Hill, 2007.

REFERENCE BOOKS:

1. G. Maitra, L. Prasad “Hand book of Mechanical Design”, 2nd Edition, Tata McGraw-Hill, 2001.

2. T. V. Sundararajamoorthy and N. Shanmugam, “Machine Design”, Anuradha Agencies, 2003. 3. Prabhu. T.J., “Design of Transmission Elements”, Mani Offset, Chennai, 2000. 4. “Design Data Book of Engineers”, Compiled by Faculty of Mechanical Engineering, PSG

College of Technology, Publisher Kalaikathir Achchagam, Coimbataore, 2009.

5. Robert L. Norton, Machine Design, Pearson, 5th Edition, 2013.

Page | 53

ME310 ENERGY LABORATORY

L T P C 0 0 4 2

OBJECTIVE: To conduct experiments on various Energy Engineering devices to study the performance and its applications.

LIST OF EXPERIMENTS: 1. Measurement of direct and diffused solar radiation 2. Determination of thermal efficiency of flat plate solar air collector 3. Experimental study on thermal performance of solar water heater 4. Testing of a solar cabinet solar dryer 5. Performance evaluation of characterization of photovoltaic and concentrating photovoltaic 6. Experimental study on thermal performance of parabolic solar cooker 7. Performance evaluation of a single basin solar still. 8. Determination of optical efficiency of a seasonally adjusted linear solar concentrator 9. Experimental study on thermal performance and efficiency of biomass downdraft gasifier 10. Sampling and analysis of air and flue gas from biomass energy systems i.e. gasifier, combustor

and cook stoves using gas chromatography technique 11. Performance study on biogas plant 12. Study on thermal storage systems 13. Experimental study on performance evaluation of Fuel Cell systems 14. Pump, Fan, Blower, Compressor performance characteristics 15. Power Factor, Voltage, Current characteristics and analysis for any electrical devices 16. Flue gas analyzer


Understand the working principle of different energy sources. Procedure to be adopted for performance analysis energy utilities.

REFERENCE BOOKS: 1. Laboratory Manual Prepared by the Department.

Page | 54

ME312 SIMULATION LABORATORY L T P C 0 0 4 2

OBJECTIVE:

To gain practical experience in handling FEM software systems.

To gain knowledge idealization and approximation of structures

LIST OF EXPERIMENTS: 1. Analysis of Trusses: Determination of deflection and stresses in a) 2D Truss b) 3D Truss 2. Stress analysis of beams (Cantilever, simply supported, fixed ends) 3. Analysis of Plane stress, Plane strain and Axisymmetric Problems: Determination of deflection,

Component, Principal and Vonmises stresses in a) A Plane Stress Problem b) A Plane Strain Problem 4. Modal Analysis of 2D Beams (Cantilever, simply supported, fixed ends)

4. Harmonic analysis of a 2D cantilever beam. 5. Heat Transfer Analysis a) Conductive heat transfer analysis of a 2D Plate b) Convective heat

transfer analysis of a 2D Plate 6. Design and simulation of systems using double acting actuator, Pneumatic elements 7. Analysis of a simple welding problem (based on thermal gradient) using software 8. Analysis of a simple metal forming problem (contact analysis and plastic deformation) using

software. 9. A simple couple field analysis


To determine the deflections and stresses in Trusses and Beams.

Find the stresses through 2D Idealizations i.e., Plane stress, Plane strain and axis symmetry.

Perform modal and harmonic analysis on variety of beams.

Perform Heat transfer analysis involving conduction and convection.

Perform thermal stress analysis. REFERENCE BOOKS:


Page | 55

SEMESTER VII

HM441 INDUSTRIAL ECONOMICS AND

MANAGEMENT L T P C 2 0 0 2

OBJECTIVE:

To learn about Economics and cost Analysis in Industries To learn about Interpersonal Relationship

INTRODUCTION TO ECONOMICS: Definition – Nature and Scope - Significance of Economics for Engineers. DEMAND AND SUPPLY: Demand – Types – Determinants – Law of Demand – Elasticity of Demand – Types – Significance –Supply – Determinants of Supply - Market price determination – Meaning – Methods – Consumer Survey – Trend Projections – Moving average -Case Study in Demand Forecasting. COST AND REVENUE: Concepts – Classifications – Short run and long run cost curves – Revenue – Concepts – Measurement of Profit – Break Even Analysis - Case Studies. VALUE MEASUREMENT OF ANY PRODUCT OR SERVICE OUTCOMES: At the end of the course, the student will be able to:

• To Perform Economics and cost Analysis Problems in Industries • Enhance Interpersonal Relationship in Industries

TEXT BOOKS: 1. Dewett. K.K., & Navalur M. H., “Modern Economic Theory”, S. Chand and Company Ltd, New

Delhi, 2014. 2. Lipsey & Chrystal, “Economics”, Oxford University Press, 2010.

REFERENCE BOOKS: 1. Paul A Samuelson & William, “Economics”, Tata McGraw Hill, New Delhi, 2012. 2. Harold Koontz, Heinz Weihrich and Ramachandra Aryasri, “Principles of Management” - Tata

McGraw Hill, New Delhi, 2004.

Page | 56

HM443 PROFESSIONAL ETHICS AND INDIAN

CONSTITUTION L T P C 0 0 0 0

OBJECTIVE:

To learn about Indian Constitution and Ethics in profession and service INDIAN CONSTITUTION: Introduction, Union Government and its administration, State Government and its administration, Local Administration, Election Commission INDUSTRIAL PSYCHOLOGY: Objectives, Individual behaviour, Group behaviour, Group Dynamics, Leadership Styles, Industrial Fatigue. HUMAN VALUES: Value crisis in Contemporary Indian Society, Aesthetic Values, Moral and Ethical Values, Values in the Work place. WORK ETHICS: Professional Values & Ethics, Need, Issues, Challenges, Ethical Leadership. SOCIAL RESPONSIBILITY AND ETHICS: Concept of Social Responsibility, Importance of Social Responsibility, Business Ethics. INTERPERSONAL RELATIONSHIP: Managing emotions, Emotional Intelligence, Building better interpersonal Relations, Dealing with Superiors and Subordinates, Case Study. MOTIVATION AND PERCEPTION: Meaning, definition, Mechanism, Basic Theories of Motivation, Importance of Perception, Need for Shaping Perception. OUTCOMES: At the end of the course, the student will be able to:

• follow ethical principles in profession and life • possess good interpersonal skills and emotional intelligence • realize the value of Indian Constitution

TEXT BOOKS:

1. Vikram Bisen & Priya, “Industrial Psychology”, New Age International (P) Ltd., Publishers, 2010.

2. Murthy C.S.V., “Business Ethics”, Himalaya Publishing House, 2007.

REFERENCE BOOKS: 1. Harold Koontz, Heinz Weihrich and Ramachandra Aryasri, “Principles of Management” - Tata

McGraw Hill, New Delhi, 2004. 2. Tripathi. A. N., “Human Values”, New Age International Pvt. Ltd., New Delhi, 2002.

Page | 57

ME491 PROJECT PHASE I L T P C 0 0 6 3

OBJECTIVES: To develop the ability to solve a specific problem right from its identification and literature review till the successful solution of the same. To train the students in preparing project reports and to face reviews and viva voce examination. The objective of the project is to enable the students to work in groups of not more than four members in each group on a project involving analytical, experimental, design or combination of these in the area of Mechanical Engineering. Each project shall have a guide. The student is required to do literature survey, formulate the problem and form a methodology of arriving at the solution of the problem. At the end of the project phase - I work, project report /write up should be prepared and submitted to the department. The phase-I evaluation (100 marks) is based on continuous internal assessment by an internal assessment committee through oral presentation. OUTCOMES: On completion of the project work students will be in a position to take up any challenging practical problems and find solution by formulating proper methodology.

Page | 58

SEMESTER VIII

ME492 PROJECT PHASE II L T P C 0 0 15 6

OBJECTIVES: To develop the ability to solve a specific problem right from its identification and literature review till the successful solution of the same. To train the students in preparing project reports and to face reviews and viva voce examination. Project work phase II will be an extension of the project work started in the seventh semester. The evaluation of project phase-II (100 marks) is based on continuous internal assessment by an internal assessment committee and final report evaluation and viva voce examination along with an institute appointed external expert. At the end of the project phase-II work, project report should be prepared and submitted to the department. After that, each group will make an oral presentation followed by a brief question and answer session. The project presentations and report for a total of 100 marks. Based on that, final report evaluation and viva voce examination (60 marks) will be conducted by a committee of one external examiner (appointed by the institution) and department faculties. The continuous internal assessment by an internal assessment committee will be evaluated for 40 marks. The method of evaluation will be as follows: 1st Evaluation = 20 marks (Decided by conducting a review by the department faculties). 2nd Evaluation = 20 marks (Decided by conducting a review by the department faculties). Final evaluation = 60 marks (Decided by conducting final review by the department faculties along with external expert appointed by the institution). OUTCOMES: On completion of the project work students will be in a position to take up any challenging practical problems and find solution by formulating proper methodology.

Page | 59

LIST OF ELECTIVES

SEMESTER V

OPEN ELECTIVE I

ME361 HYBRID VEHICLES – SOLAR AND FUEL CELLS L T P C 3 0 0 3

OBJECTIVE:

To understand the basic solar and fuel cell To understand the phenomenon of hybrid vehicle.

Energy Conversion – Conventional Techniques – Reversible & Irreversible Cycles – Carnot, Stirling& Ericsson – Otto, Diesel, Dual, Lenoir, Atkinson, Brayton and Rankine. Application of Brayton and Rankine cycle. Thermoelectric Converters – Thermoelectric refrigerator – Thermoelectric Generator – Thermionic Converters – Ferro Electric Converter – Nernst Effect Generator Batteries – Types – Working – Performance - Governing Parameters – Hydrogen Energy – Solar Cells Advance Batteries - Lithium chloride Introduction – Storage of Mechanical Energy, Electrical Energy, Chemical Energy, Thermal Energy Photovoltaic Principle –materials for photovoltaic cells – design and fabrication of photovoltaic cells Thermoelectric generator solar cell – photochemical solar cells Basics – Working Advantages & Drawbacks, Types, Comparative Analysis, Thermodynamics AND Kinetics of fuel cell process – Performance of fuel cell.

OUTCOMES: On successful completion of the course, the student will be able to,

Design hybrid vehicle system Understand the concepts of fuel cell and solar energy

TEXT BOOKS: 1. B. K. Hogde, Analysis and Design of Energy Systems, Prentice Hall of India, New Delhi, 1998. 2. Patrich.H. Oosthvizen, William E. Carscallen, Compressible fluid flow, Tata McGraw

HillPublishing Company Pvt Ltd., New Delhi,2004 REFERENCE BOOKS:

1. Rakosh das Begamudre, Energy conversion systems, New age international Publishers, New Delhi,2000.

2. Archie W. Culp, Principles of Energy Conversion, Tata McGraw Hill Publishing Company PvtLtd., Singapore,1991

Page | 60

ME362 STRATEGIC QUALITY MANAGEMENT L T P C 3 0 0 3

OBJECTIVE:

To learn about Strategic Quality Management (SQM) INTRODUCTION TO SQM: The strategic quality management era - Total Quality Management - Strategy, quality and customer value – The continuous improvement philosophy - The total view of quality - Beyond total quality management - The nature of paradigm shift. STRATEGIC MANAGEMENT AND THE EMERGING PARADIGM: Introduction - The growing role of strategic management - Defining strategy - Participants of strategic management - The emerging paradigm and strategic management – Strategic management of customer value. Elements of Strategic Quality Management - Integrating quality into Strategic Management - Quality and the management cycle - Quality policies - Quality goals - Resources for quality activities - Training for quality – Implementing total quality - Obstacles to achieving Strategic Quality Management. STRATEGIC LINKAGE OF OPERATIONS THROUGH EMPLOYEE INVOLVEMENT: Introduction - Definition of employee involvement - Establishing employee involvement within a strategic context - Establishing the context: Utilizing the MAT framework - Improving Operational Proficiency - A “pull” model of employee involvement - The organisational forms of employee involvement - Mistakes to be avoided when implementing employee involvement - Human resource implications of employee involvement. QUALITY MANAGEMENT SYSTEM: Benefits of ISO 9001 registration – ISO 9000 series of standards sector specific requirements – ISO 9001:2015 requirements (titles of main clauses and model of a process based quality management system only) - implementation – documentation – writing the document – internal audits – registration. MEASUREMENT OF CUSTOMER VALUE: Techniques for measuring customer value - Techniques for measuring commercial customer value - Principles of measurement - Avoiding value measurement errors - Using customer value measures – Satisfaction and Dissatisfaction Measurement - Refining satisfaction and dissatisfaction measurement - Implications for strategy. OUTCOMES: At the end of the course, the students will have the knowledge of

SQM, Customer Value TEXT BOOKS:

1. Juran J M and Gryna F M, “Quality Planning and Analysis”, Tata McGraw Hill Publishing Company Limited, India, 1995.

2. Bounds G, Yorks L, Adams M and Ranney G, “Beyond Total Quality Management: Toward the Emerging Paradigm”, McGraw Hill Inc., Singapore, 1994.

REFERENCE BOOKS: 1. Zairi M, “Total Quality Management for Engineers”, Woodhead Publishing Limited, England,

2005. 2. Besterfield D H, Besterfield-MICHNA C, Besterfield G H and Besterfield-Sacre M, “Total

Quality Management”, Pearson Education Private Limited, India, 2003. 3. Logothetis N, “Managing for Total Quality – From Deming to Taguchi and SPC”, Prentice Hall

of India Private Limited, New Delhi, 1997.

Page | 61

SEMESTER VI

ELECTIVE I

ME321 ADVANCED MANUFACTURING PROCESSES L T P C 3 0 0 3

OBJECTIVE:

To learn about latest Manufacturing Processes To learn about High Speed machining To learn about CAE

ADVANCED CASTING PROCESSESES: Expendable-Mold - shell mold casting, Vacuum Mold casing, investment casting, plaster-mold and ceramic-mold casting, Permanent-Mold casting processes - squeeze casting and semisolid metal casting, centrifugal casting, uses of Rapid Prototyping to produce pattern, process selection - dimensional tolerances for various casting processes and metals. ADVANCED WELDING PROCESSES: Electron beam welding, laser beam welding, Solid-State welding - diffusion welding, friction welding, ultrasonic welding, physics of welding, design considerations in welding, NDT methods for testing. ADVANCED FORMING PROCESSES: Material behavior in metal forming, temperature in metal forming, strain rate sensitivity, friction and lubrication in metal forming, bulk deformation processes, sheet metalworking, HERF, hydro forming, explosive forming, magnetic forming process.

HIGH - SPEED MACHINING: High-Speed machining centers, high-speed spindles, spindle sped, feed rate, cutting velocity, surface finish, selection of process parameters, ultra-high-speed machining centers, hard machining. APPLICATION OF CAE IN MANUFACTURING: Need for CAE in manufacturing, simulation of molten metal flow using CAE Techniques, solidification process in casting, inspections of casting. Thermal analysis of Heat-Affected Zone (HAZ), analysis of forging process using CAE, CL data generation for machining process. MANUFACTURING SYSTEMS: Automation technologies for manufacturing systems, integrated manufacturing systems – cellular manufacturing, flexible manufacturing systems, group technology, robotics.

OUTCOMES: At the end of the course, the students will be able to

Handle Advanced Manufacturing Processes Get knowledge about CAE

TEXT BOOKS: 1. Serope Kalpakjian and Stephen Schmid,”Manufacturing, Engineering and Technology”, SI 7th

Edition -”, Pearson Education, 2013. 2. Mikell P Grover “Principles of Modern Manufacturing (SI Version)” John Wiley & Sons, 2014.

REFERENCE BOOKS: 1. Paul DeGarmo E, Black J T and Ronald A Kohjer, “Materials and Processes in Manufacturing,

John Wiley India, 2011. 2. Philip F Ostwald and Jairo Munoz, “Manufacturing Processes and Systems” John Wiley India,

New Delhi, 2013.

Page | 62

3. Sanjay K Mazumdar, “Composite Manufacturing: Materials, Product and Process Engineering”, CRC Press, 2010.

4. Claudio R Boer, Hans A B Rydstad and Ginther Schroder, “Process Modelling of Metal Forming and Thermo Mechanical Treatment”, BBC Brown, Borern & Company Limited, Research Centre, Springer Verlag, New York, 2011.

Page | 63

ME322 COMPUTER INTEGRATED MANUFACTURING L T P C 3 0 0 3

OBJECTIVE:

To understand Concepts of CIM To learn Optimization coding

Meaning and Scope of CIM – Fundamentals of Communication – Product Design – Production Planning – Shop Floor Control – Robotics and Material Handling – Management of CIM.


CIM and Coding System TEXT BOOKS:

1. Kant Vajpayee S, “Principles of Computer Integrated Manufacturing”, PHI Learning Private Limited, New Delhi, 2010.

2. Mikell. P. Groover “Automation, Production Systems and Computer Integrated Manufacturing”, Pearson Education, 2001.

REFERENCE BOOKS: 1. Mikell. P. Groover and Emory ZimmersJr.,“CAD/CAM”, Prentice hall of India Pvt. Ltd., 1998. 2. Rao P N, CAD/CAM Principles and Applications”, Tata McGraw Hill Publications, 2007. 3. Radhakrishnan P, Subramanyam S and Raju V, “CAD/CAM/CIM”, New Age International,

2008.

Page | 64

ME323 DESIGN FOR MANUFACTURE AND ASSEMBLY L T P C 3 0 0 3

OBJECTIVE:

To Learn about Design calculations in Manufacturing

History of DFMA, Implementation of DFA, DFM - Design guidelines for assembly - Design for Die casting - Design for sand Casting - Design for investment casting - Design for injection molding – Design for powder metal processing - Design for hot forging – Design for sheet metal working – Design for Machining - Case studies.


Design calculation for manufacturing systems TEXT BOOKS:

1. Geoffery Boothroyd& Peter Dewhurst – Product Design for Manufacture and Assembly, CRC press, 1994

2. A.K. Chitale, R.C. Gupta, Product Design and Manufacturing –PHI Learning LTD, 2011

REFERENCE BOOKS: 1. Dickson, John. R, and Corroda Poly, “Engineering Design and Design for Manufacture and

Structural Approach”, 2. Field Stone Publisher, USA, 1995. 3. Fixel, J. “Design for the Environment”, McGraw hill., 1996. 4. Graedel T. Allen By. B, “Design for the Environment”, Angle Wood Cliff, Prentice Hall.

Reason Pub., 1996. 5. Kevien Otto and Kristin Wood, “Product Design”, Pearson Publication, 2004

Page | 65

ME324 MICRO AND NANO MANUFACTURING L T P C 3 0 0 3

OBJECTIVE:

To learn about latest Manufacturing Technology To learn about Precision Machining and Cutting Tool

Introduction to Micro and Nano Manufacturing - Influence of Various Errors on Machining Accuracy - Precision Machining and Cutting Tool Materials - Ultra Precision Machine Elements - Micro and Nano Manufacturing Processes - Precision Measurement Techniques OUTCOMES: At the end of the course, the students will have the knowledge of

Micro and Nano Manufacturing Technology Precision Measurement Techniques

TEXT BOOKS: 1. R.L. Murthy, “Precision Engineering”, New Age International Publications, New Delhi, 2009.

REFERENCE BOOKS:

1. Venkatesh V.C. and Sudin I., “Precision Engineering”, Tata McGraw Hill Co., New Delhi, 2007 2. Mark J Madou, “Fundamentals of Micro Fabrication”, CRC Press, New York, 2011. 3. Bharat Bhushan, “Handbook of Nano Technology”, Springer.

Page | 66

SEMESTER VI

OPEN ELECTIVE II

ME363 RENEWABLE ENERGY L T P C 3 0 0 3

OBJECTIVE: To import knowledge to the students about various energy sources from different forms

of waste. To enable the students’ knowledge of Bioconversion and its manufacturing systems.

Basic concepts, solar radiation, potential of solar energy, Solar Collectors, Flat Collectors, Evacuated Tubes and Heat transfer equations. Concentrators, Solar Plant Configurations, Photovoltaic Converters environmental aspects of solar energy, Solar thermal energy conversion – Efficiencies. Principles of wind power, wind turbine operation, site characteristics, horizontal and vertical axis types, aerodynamics of wind turbine, performance and wake analysis, design principles of wind turbine, tower design, new developments, small and large machines, Magnus effect, storage systems Data and energy estimation applications- Geothermal. Bio energy - Conversion - bio degradation - Biogas generation - Fuel properties – Biomass gasifier. About Ocean Waves, Offshore Wave-Energy Converters, Shoreline Wave-Energy Converters, Tidal Energy - Marine Current Turbines System, Salination Energy Tidal energy - Magneto hydrodynamic - Thermionic - Fuel cell and thermo electric generator, micro-hydel systems. Hybrid systems and applications.


Get knowledge about Solar, Tidal, Ocean and wind energy sources. Develop in depth knowledge about Basic concepts about various renewable energy sources.

TEXT BOOKS: 1. Sukhatme, S.P., Solar Energy: Principle of Thermal Collection and Storage, 2nd Ed. 2. Tata McGraw Hill, 2008. 2. Rao, S. and Parulekar, R.B., Energy Technology - Nonconventional, Renewable and 3. Conventional, Khanna Publishers, 1995. 4. Twidell, J.W. & Weir, A., "Renewable Energy Sources", EFN Spon Ltd., UK, 2006.

REFERENCE BOOKS: 1. Rai, G.D., Nonconventional Energy Sources, Khanna Publishers, 1999. 2. Le Gourieres, D., Wind Power Plant - Theory and Design, Pergaman Press, 1982. 3. Godfrey Boyle, "Renewable Energy, Power for a Sustainable Future", Oxford University

Press,U.K., 1996. 4. Tiwari. G.N., Solar Energy – "Fundamentals Design, Modelling & Applications", Narosa

Publishing House, New Delhi, 2002. 5. Freris. L.L., "Wind Energy Conversion Systems", Prentice Hall, UK, 1990. 6. Johnson Gary, L. "Wind Energy Systems", Prentice Hall, New York, 1985 7. David M. Mousdale – "Introduction to Biofuels", CRC Press, Taylor & Francis Group,

USA2010 8. Chetan Singh Solanki, Solar Photovoltaics, "Fundamentals, Technologies and Applications",

PHI Learning Private Limited, New Delhi, 2009.

Page | 67

ME364 3D PRINTING L T P C 3 0 0 3

OBJECTIVE:

To expose the students to different types of Rapid prototyping processes, materials used in RP systems and reverse engineering.

Geometric representation of curves, surfaces and solids. CAD data exchange formats. History – Development of RP systems – Applications in Product Development, Reverse Engineering, Rapid Tooling, Rapid Manufacturing- Principle – Fundamental – File format – Other translators – medical applications of RP. Classification – Liquid based system – Stereolithography Apparatus (SLA), details of SL process, products, Advantages, Limitations, Applications and Uses. Solid based system – Fused Deposition Modelling, principle, process, products, advantages, applications and uses – Laminated Object Manufacturing Selective Laser Sintering – principles of SLS process, principle of sinter bonding process, Laser sintering materials, products, advantages, limitations, applications and uses. Three-Dimensional Printing – process, major applications, research and development. Direct shell production casting – key strengths, process, applications and uses, case studies, research and development. Laser Sintering System, e-manufacturing using Laser sintering, customized plastic parts, customized metal parts, e-manufacturing – Laser Engineered Net Shaping (LENS).

Introduction to 3D Scanners and its applications, Support material removal, surface texture improvement, accuracy improvement, aesthetic improvement, preparation for use as a pattern, property enhancements using non-thermal and thermal techniques.

OUTCOMES:

To provide knowledge on different types of Rapid Prototyping systems and its applications in various fields

TEXT BOOKS: 1. Ibrahim Zeid - CAD/CAM Theory and Practice, Tata McGraw Hill Publishing Co. Ltd., New

Delhi, 2009. 2. Rafiq I. Noorani, Rapid Prototyping, “Principles and Applications”, Wiley & Sons, 2006. 3. Chua C.K, Leong K.F and Lim C.S, “Rapid Prototyping: Principles and Applications”, Second

Edition, World Scientific, 2003. REFERENCE BOOKS:

1. N.Hopkinson, R.J.M, Hauge, P M, Dickens, “Rapid Manufacturing – An Industrial revolution for the digital age”, Wiley, 2006

2. Ian Gibson, “Advanced Manufacturing Technology for Medical applications: Reverse Engineering, Software conversion and Rapid Prototying”, Wiley, 2006

3. Paul F.Jacobs, “Rapid Prototyping and Manufacturing: Fundamentals of Stereolithography”, McGraw Hill 1993.

4. Pham. D.T., and Dimov. S.S., “Rapid Manufacturing”, Springer Verlog 2001.

Page | 68

SEMESTER VII

ELECTIVE II

ME421 HUMAN FACTORS ENGINEERING L T P C 3 0 0 3

OBJECTIVE: The objectives of this course is to inculcate knowledge on

elements of man-machine interaction to enhance work place safety human behavior and perception to create and promote a safe working culture

Human Factors and Ergonomics – Human Body as a Mechanical System – Anthropometry and Work Station Design – Repetitive Risk Assessment and Design of Manual Handling tasks – Display, Controls and Virtual Environments. OUTCOMES: On successful completion of the course, the student will be able to,

identify musculoskeletal disorders in the work environment and behavioural aspects of work place posture

apply anthropometry in designing work stations analyse the ergonomical aspects of repetitive works and thereby prevent work related

musculoskeletal disorders relate human sensory, cognitive, physical capabilities and limitations and suitably design work

place displays and controls TEXT BOOKS:

1. Robert Bridger, “Introduction to Human Factors and Ergonomics”, CRC Press; 4th edition, 2017.

2. Sanders, M.S. and McCormick E.J. Human Factors in Engineering and Design (7th Ed.). McGraw-Hill, Inc, 1997.

REFERENCE BOOKS: 1. Kroemer, K.H.E., Kroemer, H.B., and Kroemer-Elbert, K.E. Ergonomics: How to Design

for Ease and Efficiency (2nd Ed.). Upper Saddle River, New Jersey: Prentice Hall, 2001. 2. Wickens, C.D., Lee, J.D., Liu, Y., Gordon Becker, S.E. An Introduction to Human

Factors in Engineering (2nd Ed.). Upper Saddle River, New Jersey: Pearson Prentice-Hall, 2004. 3. Dul, J. and Weerdmeester,B. Ergonomics for beginners, a quick reference guide, Taylor &

Francis, 1993.

Page | 69

ME422 LEAN AND AGILE MANUFACTURING L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of Lean and Agile Manufacturing. Origins and objectives of lean manufacturing-Lean process,3M concept, key principles and implications of lean manufacturing-traditional vs lean manufacturing characteristics–roadmap for lean implementation and lean benefits. study of Ford and Toyota production system, JIT manufacturing, Lean building blocks.

Value creation and waste elimination – seven types of waste- pull production - different models of pull production -The Kanban system - continuous flow-The continuous improvement process / Kaizen-Worker involvement. Design of Kanban quantities, leveled production, tools for continuous improvement.

JIT with cell manufacturing - Part families - Production flow analysis – Composite part concept – Machine cell design-Quantitative analysis – case studies. Single piece flow.

The value stream – benefits, mapping process. The current state map–mapping icons, mapping steps. VSM exercises, Takt time calculations

Standardized work – standard work sequence, timing and working progress. Quality at source - Automation/Jidoka, Visual management system, Mistake proofing/Poka-Yoke. 5S technique – Elements and waste elimination thro 5S, advantages and benefits, 5S audit. Visual control aids for improvement, Flexible work force.

OUTCOMES: Upon the completion of the course, the students are able:

To apply concepts of JIT with cell manufacturing on various problems. To formulate standard work sequence and Quality at source.

TEXT BOOKS: 1. Micheal Wader, “Lean Tools: A Pocket guide to Implementing Lean Practices”, Productivity

and Quality Publishing, 2002. 2. William M Feld, “Lean Manufacturing: Tools, Techniques and How to Use Them”, APICS,

2001. 3. S.R.Devadasan, V.Mohan Sivakumar, V.Murugesh, P.R.Shalij, ‘Lean and Agile

Manufacturing’, Prentice Hall India, 2012. REFERENCE BOOKS:

1. Taiichi Ohno, “Toyoto Production Systems: Beyond Large Scale Production”, Productivity Press,1988.

2. Askin RG and GoldbergJB, “Design and Analysis of Lean Production Systems”, John Wiley and Sons, 2003.

Page | 70

ME423 SUPPLY CHAIN MANAGEMENT L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of supply chain management.

Definition, global optimization, objectives of SCM. Logistics networks- data collection, model and data evaluation, solution techniques. Introduction to inventory and multi order opportunities, Inventory policy- Periodic review policy, Continuous review policy, Effect of demand uncertainty. Risk pooling, centralized and decentralized system, managing inventory in the supply chain, forecasting-The Role of Forecasting in a Supply Chain, Risk Management in Forecasting, case studies. Bullwhip effect, information and supply chain technology. Supply chain integration- push, pull and push-pull system. Demand driven strategies, impact of internet on SCM, distribution strategies. Framework for strategic alliance, third party logistics, retailer, supplies partnership, distributor- integration, procurement and out servicing strategies. Introduction, risks and advantages- design for logistics, supplies integration into to new product development, mass customization. Issues in customer value.

OUTCOMES:

Upon the completion of the course, the students are able to understand the framework and strategic allegiance in supply chain management.

TEXT BOOKS: 1. Simchi – Levi Davi, Kaminsky Philip and Simchi-Levi Edith, “Designing and Managing the

Supply Chain “3rd Edition McGraw-Hill Education 2007. 2. Chopra S and Meindl P, “Supply Chain Management: Strategy, Planning, and Operation”,

Pearson, 2013. REFERENCE BOOKS:

1. Robert B Handfield and Ernest L Nichols, “Introduction to Supply Chain Management”, Prentice Hall, Inc. New Delhi, 1999.

2. Sahay B S, “Supply Chain Management”, Macmillan Company, 2000. 3. David Brunt and David Taylor, “Manufacturing Operations and Supply Chain Management:

The Lean Approach”, Vikas Publishing House, New Delhi, 2001. 4. HartmudStadler and ChristophKilger, “Supply Chain Management and Advanced Planning:

Concepts, Models, Software”, Springer-Verlag, 2000.

Page | 71

SEMESTER VII

ELECTIVE III

ME424 MECHANICS OF COMPOSITES L T P C 3 0 0 3

OBJECTIVE:

To provide the basic understanding on the concepts of Composite materials and mechanics.

Modern materials in design, types, metals, polymers, ceramics, composites. Polymers-Classification, properties of thermo plastics, properties of thermo setting plastics, applications, merits and demerits. Classification of composites, Honey comb composites, advantages, applications. Matrix and their role, principal types of fibre and matrix materials. Manufacture of polymer matrix composites-Layup and curing, open and closed mold processes, bag molding, filament winding, pultrusion, pulforming, thermoforming, advantages and limitations of different processes. Manufacture of metal matrix and ceramic matrix composites. Advantages, limitations and characteristics of ceramic and metal matrix composites. Stress and strain, Strain Energy, Plane stress and plane strain, Generalized Hook’s Law for different types of materials, material symmetry, Engineering constants, coordinate transformation, thermal effects and moisture effects Volume and mass fractions, density and void content, evaluation of elastic moduli, ultimate strengths of a unidirectional lamina, coefficients of thermal and moisture expansion. Hook’s Law for a two dimensional unidirectional lamina and angular lamina, evaluation of elastic moduli for unidirectional and angle lamina, engineering constants of unidirectional and angle lamina, strength failure theories, failure theories for composite lamina. Laminate code, stress - strain behavior in a laminate, Resultant forces and moments in a laminate, interlinear stresses in laminates. OUTCOMES:

Upon the completion of the course, the students are able to apply the concepts of manufacture of polymer matrix composites.

TEXT BOOKS: 1. Autar K Kaw, "Mechanics of Composite Materials", CRC Press, NY, 1997. 2. Agarwal B D and Broutman L J, "Analysis and Performance of Fibre Composites", John Wiley

and Sons Inc, 1990. REFERENCE BOOKS:

1. Ronald F Gibson, “Principles of Composite Material Mechanics”, McGraw Hill Book Co, 1994. 2. Robert M Jones, "Mechanics of Composite Materials", McGraw Hill Book Co, 2015. 3. Terry Richardson, "Composites - A Design Guide", Industrial Press Inc, NY, 1987. 4. Sanjay K Mazumdar, “Composites Manufacturing”, CRC Press, NY, 2003.

Page | 72

ME425 TRIBOLOGY L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding the concepts of Tribology. Properties of oils and equation of flow: Viscosity, Newton’s Law of viscosity, Hagen-Poiseuille Law, Flow between parallel stationary planes, viscosity measuring apparatus. Lubrication principles, classification of lubricants. Friction forces and power loss in lightly loaded bearing, Petroff’s law, Tower’s experiments, and mechanism of pressure development in an oil film, Reynold’s investigation and Reynold’s equation in 2D. Introduction to idealized journal bearing, load carrying capacity, condition for equilibrium, Sommerfeld’s numbers and significance of it; Partial bearings, end leakages in journal bearing, numerical problems. Pressure distribution, Load carrying capacity, coefficient of friction, frictional resistance in a pivoted shoe bearing, numerical examples. Oil flow through bearings, self-contained journal bearings, bearings lubricated under pressure, thermal equilibrium of journal bearings. Introduction to hydrostatic lubrication, hydrostatic step bearings, load carrying capacity and oil flow through the hydrostatic step bearing. Commonly used bearings materials, properties of typical bearing materials. Advantages and disadvantages of bearing materials. Selection, friction, Wear of ceramic materials, wear measurements, effects of speed, temperature and pressure. Tribological measures, Material selection, improved design, surface engineering

OUTCOMES:

Upon the completion of the course the students are able to apply the design concepts in bearings and materials.

TEXT BOOKS: 1. Piet M. Lugt, “Grease Lubrication in Rolling Bearings” Willey Publishers, 2012.

REFERENCE BOOKS: 1. Gwidon Stachowiak, A W Batchelor, Engineering Tribology, Second Edition, Butterworth-

Heinemann, 2000.

Page | 73

ME426 FATIGUE, FRACTURE AND FAILURE

ANALYSIS L T P C 3 0 0 3

OBJECTIVE:

To develop students understanding of best practice analysis in fracture, fatigue and failure testing.

Griffith’s theory of brittle failures; Irwin’s stress intensity factors; Linear elastic fracture mechanics: The stress analysis of crack tips, Macroscopic theories in crack extension, Instability and R-curves, Crack tip plasticity, K as a failure criterion, Mixed mode of fracture, Analytical and Experimental methods of determining K; Elastic plastic fracture mechanics: Crack tip opening displacement, J Integrals, Crack growth resistance curves, Crack tip constraint under large scale yielding, creep crack growth; Microscopic theories of fracture: Ductile and cleavage fracture, ductile-brittle transition, inter-granular fracture; Fatigue crack propagation: Fatigue crack growth theories, crack closure, Microscopic theories of fatigue crack growth; Application of theories of fracture mechanics in design and materials development.

OUTCOMES: The course is designed to help students to achieve the following outcomes

To equip students with the understanding of concepts in failure, fatigue, failure.

To equip students with the capability to develop, apply the concepts in testing on various materials.

TEXT BOOKS: 1. T. L. Anderson, Fracture Mechanics Fundamentals and Applications, CRC Press, 1994. 2. D. Brock, Elementary Engineering Fracture Mechanics, MaritinusNijhoff Publishers, 1982.

REFERENCE BOOKS:

1. S. T. Rolfe and J. M. Barson, Fracture and Fatigue Control in Structures, PHI, 1977.

Page | 74

ME427 ADVANCED MATERIAL CHARACTERIZATION

L T P C 3 0 0 3

OBJECTIVE: The subject aims to provide the student: To develop students understanding of best practice approaches to material characterization. X-Ray Techniques: Elements of Crystallography, Principles of X-ray diffraction, X-ray

equipment and data analysis, associated techniques in X-ray spectroscopy, Fundamentals of

elemental analysis – Optical / Electron Microscopy Techniques: Elements of phase identification,

grain size determination, inclusion analysis, Image analysis, Electron diffraction, SEM, Failure

analysis and fractography, EDAX / EPMA, data analysis – Neutron Scattering Techniques:

Diffraction, inelastic scattering and reflectometry – Thermal Analysis: Principles and applications

of thermal analysis (DTA, DSC, TGA, TMA, DMA) – Mechanical Property evaluation: Principles

and characterisation techniques related to Tensile, compressive, hardness, fatigue, and fracture

toughness properties.

OUTCOMES: The student after undergoing this course will be able to: To equip students with the capability to apply basic methods in material characterization. To equip students with the capability to select, apply and interpret relevant approaches in

support of various analysis and their characterization. REFERENCE BOOKS:

S.No Name of Author(s) Title of the Book Year Publisher

1 ASM hand book Materials characterisation, Vol. 3, 10

1997 ASM

2 B. D. Cullitey Elements of X-ray diffraction

1968 Addison-Wesely

3 G. Dieter Mechanical Metallurgy 1996 Mc-Graw Hill

4 R.F. Speyer Thermal Analysis of Materials

1994 Marcel Decker

Page | 75

SEMESTER VII

ELECTIVE IV

ME428 REFRIGERATION AND AIR CONDITIONING L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts and equipment in Refrigeration and Air Conditioning.

Refrigeration cycles & processes, Psychometric- properties, processes, cooling load estimation, use of refrigeration &Psychometric chart, Evaporators, Dx coils, Wet coils, flooded liquid cooler, Direct-expansion liquid cooler and liquid overfeed cooler, Condensation and condensers, Water-cooled condensers. Air-cooled, Evaporative condensers, Cooling towers, Thermostatic expansion valves, Compressors- Reciprocating, Rotary, Scroll, and Screw Packaged and chiller units:- Types, Application, Cooling load estimation, Design and Balancing of components, Layout of the components. Cooling load estimation, Design and Balancing of components, Layout of the components. Types, Application, Cooling load estimation, Design and Balancing of components, Layout of the components. Fans- Types & selection, Coils- Characteristics, Types & Coil Accessories, Condensate control, and freeze-up protection, Air filters, Electronic air cleaners, Activated Carbon, humidification and humidifiers, Selection of humidifiers and design. Air condition systems classification, Air Heating, and Cooling Systems, Designation, Air conditioning system, Subsystem, and main components selection, Applications and building occupancies indoor air quality, Types - Packaged terminal air conditioning Systems, Evaporative cooling and evaporative cooling systems, Space air conditioning systems, Packaged systems and Desiccant-based Systems, Central systems and clean room systems, Thermal Storage Systems, Chilled water system Air systems: Equipment— Air-handling units and Packaged units, Functions of AHU, classifications, main components, selection of AHU, Packaged units – types, performance and selection of Packaged units, Fan room – types, layout considerations; Air duct design: Basics of airflow in ducts, characteristics of airflow in ducts, Types, Construction, duct heat gain, heat loss and duct insulation, frictional losses, dynamic losses, flow resistance, principles considerations and procedure in air duct design, layout, methods, computer-aided duct design and drafting, duct liner and duct cleaning, space air diffusion Commissioning and Maintenance: HVAC&R Commissioning, Testing, Adjusting, and Balancing, HVAC&R Maintenance, Monitoring and Fault Detection, Diagnostics Assisting Predictive Maintenance; Sound control, Energy management and global warming: Energy efficiency, Kyoto Protocol, Green Buildings, Energy Star, case study: energy conservation measures for an office, ISHRAE standards, Introduction to Building Management System (BMS)


To understand the concepts of refrigeration and air conditioning. To apply the concepts of Duct design on various problems.

Page | 76

TEXT BOOKS: 1. ISHRAE, “HVAC Handbook” 2014 2. Shan K. Wang, “Hand Book of Refrigeration and Air Conditioning” McGraw-Hill New York,

2008. 3. Arora .C, “Refrigeration and Air Conditioning”, Tata McGraw Hill Publishing Company Ltd.,

New Delhi, 2008.

REFERENCE BOOKS: 1. Roy J Dossat, “Principles of Refrigeration” S I Version, Wiley Eastern Limited, New Delhi,

1985 2. Arora .R.C., “Refrigeration and Air Conditioning”, PHI Learning Pvt. Ltd, New Delhi, 2011 3. Jones W.P., “Air Conditioning Engineering”, Butterworth-Heinemann, 1994. 4. Web and video material of NPTEL, Prof. Ramgopal, IIT Kharagpur.

Page | 77

ME429 IC ENGINES L T P C 3 0 0 3

OBJECTIVE:

To understand the underlying principles of operation of different IC Engines and components. To provide knowledge on pollutant formation, control, alternate fuel etc.

Mixture requirements – Fuel injection systems – Monopoint, Multipoint & Direct injection – Stages of combustion – Normal and Abnormal combustion – Knock – Factors affecting knock – Combustion chambers. Diesel Fuel Injection Systems – Stages of combustion – Knocking – Factors affecting knock – Direct and Indirect injection systems – Combustion chambers – Fuel Spray behavior – Spray structure and spray penetration – Air motion – Introduction to Turbocharging.

Pollutant – Sources – Formation of Carbon Monoxide, Unburnt hydrocarbon, Oxides of Nitrogen, Smoke and Particulate matter – Methods of controlling Emissions – Catalytic converters, Selective Catalytic Reduction and Particulate Traps – Methods of measurement – Emission norms and Driving cycles.

Alcohol, Hydrogen, Compressed Natural Gas, Liquefied Petroleum Gas and Bio Diesel – Properties, Suitability, Merits and Demerits – Engine Modifications.

Air assisted Combustion, Homogeneous charge compression ignition engines – Variable Geometry turbochargers – Common Rail Direct Injection Systems – Hybrid Electric Vehicles – NOx Adsorbers – Onboard Diagnostics.

OUTCOMES:

Upon completion of this course, the students can able to compare the operations of different IC Engine and components and can evaluate the pollutant formation, control, alternate fuel

TEXT BOOKS:

1. Ramalingam. K.K., “Internal Combustion Engine Fundamentals”, Scitech Publications, 2002. 2. Ganesan, “Internal Combustion Engines”, II Edition, TMH, 2002.

REFERENCE BOOKS:

1. Mathur. R.B. and R.P. Sharma, “Internal Combustion Engines”.,DhanpatRai& Sons 2007. 2. Duffy Smith, “Auto Fuel Systems”, The Good Heart Willcox Company, Inc., 1987. 3. Eric Chowenitz, “Automobile Electronics”, SAE Publications, 1995

Page | 78

ME430 CRYOGENICS L T P C 3 0 0 3

OBJECTIVE:

To learn basic concepts about Cryogenics To learn about Cryo coolers and Cryogenic Refrigerators

Insight on Cryogenics - Properties of Cryogenic fluids - Material properties at Cryogenic Temperatures- Carnot Liquefaction Cycle - F.O.M. and Yield of Liquefaction Cycle - Inversion Curve – Joule Thomson Effect – Linde Hampson Cycle - Precooled Linde Hampson Cycle - Claudes Cycle Dual Cycle Binary Mixtures - T-C and H-C Diagrams - Principle of Rectification - Rectification Column Analysis– McCabe Thiele Method - Adsorption Systems for purification J. T. Cryocoolers - Stirling Cycle Refrigerators - G. M. Cryocoolers - Pulse Tube Refrigerators - Regenerators used in Cryogenic Refrigerators Cryogenic Dewar Constructive and Design, Cryogenic Transfer Lines - Different Types of Vacuum Pumps - Instrumentation to measure Flow - Level and Temperature Applications of Cryogenics in Space Programs – Superconductivity - Cryo Metallurgy – Medical Applications. OUTCOMES: On successful completion of the course, the student will be able to,

Get Cryogenics basic concepts and implement Cryogenics in Space Programs Get knowledge about Cryocoolers and Cryogenic Refrigerators

TEXT BOOKS: 1. MamataMukhopadhyay, Fundamentals of Cryogenic Engineering, Prentice Hall of India, 2010.

REFERENCE BOOKS: 1. Thomas M. Flynn, Cryogenic Engineering, Marcel Dekker, New York 2005. 2. J. G. Weisend, The Handbook of Cryogenic Engineering, CRC Press, 1998. 3. K. D. Timmerhaus and T. M. Flynn, Cryogenic Process Engineering, Plenum Press, New York,

1989. 4. R. B Scott.,Cryogenic Engineering, Van Nostrand and Company Inc., 1985. 5. Randall F. Barron, Cryogenic Systems, Tata McGraw Hill Publishing Company Pvt Ltd., New

Delhi, 1985.

Page | 79

ME431 GAS DYNAMICS AND JET PROPULSION L T P C 3 0 0 3

OBJECTIVE: To understand the basic about incompressible and compressible flow To understand the phenomenon of shock waves and its effect on flow. To gain some basic knowledge about jet propulsion and Rocket Propulsion.

(Use of Standard Gas Tables permitted)

Energy and momentum equations for compressible fluid flows- various regions of flows – reference velocities - stagnation state - Wave propagation in elastic medium – propagation of sound waves and derivation for velocity of sound - critical states, Mach number, critical Mach number - types of waves -Mach cone - Mach angle - effect of Mach number on compressibility Isentropic flow through variable area ducts - T-s and h-s diagrams for nozzle and diffuser flows – area ratio as a function of Mach number - mass flow rate through nozzles and diffusers - effect of friction in flow through nozzles. Flow in constant area ducts with friction (Fanno flow) – Fanno curves and Fanno flow equation - variation of flow properties and variation of Mach number with duct length in Fanno flow- Flow in constant area ducts with heat transfer (Rayleigh flow) - Rayleigh line and Rayleigh flow equation - variation of flow properties and maximum heat transfer in Rayleigh flow. Governing equations - variation of flow parameters like static pressure, static temperature, density, stagnation pressure and entropy across the normal shock – Prandtl-Meyer equation - impossibility of shock in subsonic flows - flow in convergent and divergent nozzle with shock - normal shock in Fanno and Rayleigh flows - flow with oblique shock (elementary treatment only). Aircraft propulsion – types of jet engines – energy flow through jet engines - study of turbojet engine components – diffuser, compressor, combustion chamber, turbine and exhaust systems – performance of turbo jet engines – thrust, thrust power, propulsive and overall efficiencies - thrust augmentation in turbo jet engine - ram jet and pulse jet engines. Rocket propulsion – Classification of rocket engines – Propellants: solid and liquid propellants, rocket engines thrust equation – effective jet velocity specific impulse – rocket engine performance – Flow through rocket nozzles – mass ratio and propellant mass fraction – Vertical flight of a rocket: powered flight and coasting flight – Rocket applications


differentiate compressible and incompressible flow 1. Apply the concept of compressible flows in variable area ducts. 2. examine the effect of compression and expansion waves in compressible flow

TEXT BOOKS: 1. P. Balachandran, Fundamental of Compressible Fluid Dynamics, Prentice Hall of India, NewDelhi,

2009. 2. Anderson, J.D., "Modern Compressibleflow",3Edition, McGraw Hill,2012 3. Yahya, S.M. "Fundamentals of Compressible Flow", New Age International (P) Limited,

NewDelhi,2002

REFERENCE BOOKS:

Page | 80

1. E. Rathakrishnan, Gas Dynamics, Prentice Hall of India, New Delhi, 2008. 2. Patrich.H. Oosthvizen, William E. Carscallen, Compressible fluid flow, Tata McGraw

HillPublishing Company Pvt Ltd., New Delhi,2004

Page | 81

ME432 PRESSURE VESSEL DESIGN L T P C 3 0 0 3

OBJECTIVE:

To provide the basic understanding on the concepts of pressure vessel design and its considerations.

Stresses in Pressure Vessels: General theory of membrane stresses in vessel under internal pressure and its application to shells (cylindrical, conical and spherical) and end closures. Bending of circular plates and determination of stresses in simply supported and clamped circular plate. Thermal stresses, Stress concentration in plate having circular hole due to bi-axial loading, Excessive elastic deformation, Plastic instability, Brittle rupture and creep. Theory of reinforced opening and reinforcement limits. Design of Vessels using Codes: Introduction to ASME codes for pressure vessel design, Pressure vessel and related components’ design using ASME codes; Supports for short vertical vessels, Stress concentration at a variable thickness transition section in a cylindrical vessel; Design of nozzles. Supports for vertical & horizontal vessels: Design of base plate and support lugs. Types of anchor bolt, its material and allowable stresses. Design of saddle supports. Other Design Considerations: Buckling phenomenon, Elastic Buckling of circular ring and cylinders under external pressure, Collapse of thick walled cylinders or tubes under external pressure, Effect of supports on Elastic Buckling of Cylinders, Design of circumferential stiffeners, Buckling under combined External pressure and Axial loading. Fatigue, shock, high pressure, high temperature, irradiation, corrosion, and other hostile environments; High strength, lightweight pressure vessels, Vessels resistant to external high pressures found in undersea exploration, offshore drilling, and mineral mining. Piping Design: Flow diagram, Piping layout and piping stress analysis; Flexibility factor and stress intensification factor; Design of piping system as per B31.1 piping code. Piping components - bends, tees, bellows and valves. Types of piping supports and their behavior; Introduction to piping Codes and Standards.


To apply the design concepts on various pressure vessels.

To apply the concepts of design in piping system and its supports. TEXT BOOKS:

1. Harvey J F, “Pressure vessel design”, CBS Publication. 2001 2. Brownell L. E and Young. E. D, “Process equipment design”, Wiley Eastern Ltd., India, 2009 3. “ASME Pressure Vessel and Boiler code, Section VIII Div. 1, 2, and 3”, ASME, 2017.

REFERENCE BOOKS: 1. Henry H Bednar, “Pressure vessel Design Hand book”, CBS publishers and distributors, 2013. 2. Stanley M Wales, “Chemical Process Equipment, Selection and Design”, Butterworths, Series

in Chemical Engineering, 1988.

Page | 82

ME433 TURBOMACHINES L T P C 3 0 0 3

OBJECTIVE: 1. To Provide students with opportunities to apply basic flow equations; 2. To compare and choose machines for various operations.

Basics of isentropic flow –static and stagnation properties –diffuser and nozzle configurations -area ratio –mass flow rate –critical properties. Energy transfer between fluid and rotor velocity triangles for a generalized turbomachine -velocity diagrams. Euler's equation for turbomachines and its different forms. Degree of reaction in turbo-machines –various efficiencies –isentropic, mechanical, thermal, overall and polytropic. Centrifugal compressor -configuration and working –slip factor -work input factor –ideal and actual work -pressure coefficient -pressure ratio. Axial flow compressor –geometry and working–velocity diagrams –ideal and actual work –stage pressure ratio -free vortex theory –performance curves and losses. Basics of combustion - Structure and working of combustion chamber –combustion chamber arrangements -flame stability –fuel injection nozzles. Flame stabilization -cooling of combustion chamber. Elementary theory of axial flow turbines -stage parameters-multi-staging -stage loading and flow coefficients. Degree of reaction -stage temperature and pressure ratios –single and twin spool arrangements –performance. Matching of components. Blade Cooling. Radial flow turbines. Gas turbine cycle analysis –simple and actual. Reheated, Regenerative and Intercooled cycles for power plants. Working of Turbojet, Turbofan, Turboprop, Ramjet, Scarm jet and Pulsejet Engines and cycle analysis –thrust, specific impulse, specific fuel consumption, thermal and propulsive efficiencies. OUTCOMES: Upon the completion of the course, the students will be able:

explain basic concepts of turbomachines and visualize dimensional analysis.

describe the working of Pelton, Francis and Kaplan along their performance parameters.

discuss the operation of centrifugal pumps, centrifugal and axial compressors.

associate the effect of cavitation in turbines and pumps.

express the basic cycles and calculations involved in the operation of steam and gas turbines. REFERENCE BOOKS: 1. Ganesan, V., Gas Turbines, Tata McGrawHill, 2011. 2. Khajuria P.R and Dubey S.P., Gas Turbines and Propulsive Systems, Dhanpat Rai Publications, 2003 3. Cohen, H., Rogers, G F C and Saravanmotto, H I H, Gas Turbine Theory, John Wiely, 5thEdition 2001. 4. Hill P G and Peterson C R, Mechanics and Thermodynamics of Propulsion, Addition-Wesley, 1970. 5. Mattingly J D, Elements of Gas turbine Propulsion, McGraw Hill, 1st Edition. 1997

Page | 83

SEMESTER VII

ELECTIVE V

ME434 ENERGY MANAGEMENT AND AUDITING L T P C 3 0 0 3

OBJECTIVE:

To understand the basic concepts of Energy management and auditing.

Energy - Power – Past & Present scenario of World; National Energy consumption Data –Environmental aspects associated with energy utilization –Energy Auditing: Need, Types, Methodology and Barriers. Role of Energy Managers. Instruments for energy auditing. Components of EB billing – HT and LT supply, Transformers, Cable Sizing, Concept of Capacitors, Power Factor Improvement, Harmonics, Electric Motors - Motor Efficiency Computation, Energy Efficient Motors, Illumination – Lux, Lumens, Types of lighting, Efficacy, LED Lighting and scope of Encon in Illumination. Stoichiometry, Boilers, Furnaces and Thermic Fluid Heaters – Efficiency computation and encon measures. Steam: Distribution and Usage: Steam Traps, Condensate Recovery, Flash Steam Utilization, Insulators & Refractories. Pumps, Fans, Blowers, Compressed Air Systems, Refrigeration and Air Conditioning Systems– Cooling Towers – D.G. sets. Energy Economics – Discount Rate, Payback Period, Internal Rate of Return, Net Present Value, Life Cycle Costing –ESCO concept.


To understand the components of EB billing, HT and LT supply and cable sizing. To apply concepts of Energy Economics, Discount rate, Payback period.

TEXT BOOKS:

1. Energy Manager Training Manual (4 Volumes) available at www.energymanagertraining.com, a website administered by Bureau of Energy Efficiency (BEE), a statutory body under Ministry of Power, Government of India.2004.

REFERENCE BOOKS: 1. L.C. Witte, P.S. Schmidt, D.R. Brown, “Industrial Energy Management and Utilisation”

Hemisphere Publications, Washington, 1988. 2. Callaghn, P.W. “Design and Management for Energy Conservation”, Pergamon Press, Oxford,

1981. 3. I.G.C. Dryden, “The Efficient Use of Energy” Butterworths, London, 1982 4. W.C. turner, “Energy Management Hand book” Wiley, New York, 1982. 5. W.R. Murphy and G. Mc KAY “Energy Management” Butterworths, London 1987.

Page | 84

ME435 SOLAR POWER ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of Solar Power and various storage systems.

Radiation Fundamentals, Sun–Earth Geometric Relationship, Sun-path diagram, Solar Radiation, Beam and Diffuse radiation, Measurement of Solar Radiation, Solar Radiation Mapping, Resource Assessment of Solar Radiation. Radiative Properties and Characteristics of Materials, Types of collectors, Flat, Tubular, Concentrating, Parabolic, Compound, and Fresnel. Applications - Solar Space Cooling and Refrigeration, Solar Desiccant Dehumidification, Passive Space Heating and Cooling Systems, Desalination, Solar Photochemical Applications, Solar power generation cycles and systems, System design. Solar photovoltaic, Basics, Types of Cell, Materials, Parameters and Performances, Tracking, Balance of System, Applications, PV power plants, Types, Plant Design. Thermal Energy Storage, Types, Design of System, Thermal energy transfer system design. Mechanical energy storage, Types and system design, Electrical energy storage types and system design. Plant economy, Energy Delivery Factor, Profitability Index, Cost of Energy.

OUTCOMES: Upon the completion of course, the students are able:

To understand various concepts of Radiation. To apply concepts of Photovoltaic, Power Plants and its design.

TEXT BOOKS:

1. D. Yogi Goswami, “Principles of Solar Engineering”, CRC Press, 2015 2. Soteris Kalogirou, Solar Energy Engineering: Processes and Systems, Academic Press, 2013

REFERENCE BOOKS:

1. Bent Sorensen, “Solar Energy Storage”, Academic Press, 2015. 2. Michael Boxwell, “Solar Electricity Handbook”, Greenstream Publishing, 2013. 3. K. Lovegrove, W Stein, "Concentrating Solar Power Technology: Principles, Developments and

Applications", Woodhead Publishing, 2012.

Page | 85

ME436 DIRECT ENERGY CONVERSION SYSTEMS L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding the concepts of Direct Energy Conversion Systems and Quantum Physics.

Energy: Types and classification – Energy sources – Energy conversion processes. Direct and Indirect energy conversion-Fuels for Energy conversion-Introduction to irreversible thermodynamics. Basic ideas of quantum physics – Pauli Exclusion Principle – Shell structure of electrons – Fermi Energy – Energy levels – Bonding in crystals – Energy bands –Intrinsic and Extrinsic semiconductors – junctions – types. Photovoltaic conversion – solar cell configurations – characteristics of solar cells- performance of solar cells - Thermoelectric converters – Thermoelectric refrigerators – Thermionic converters and other thermal – electric conversion systems. Introduction to plasma physics – Temperature and ionization– confinement of plasma: Magnetic confinement and inertial confinement – Principles of Magneto hydrodynamic conversion-Ideal and practical MHD generators performance – MHD technology. Fuel cells and Batteries – Principles of EMF generation – Description of fuel cells – Applications of fuel cells – Description of batteries: Primary, Secondary, Reserve and advanced battery system – Types – Characteristics – applications. OUTCOMES: Upon the completion of the course, the students are able:

To understand the concepts of plasma physics, MHD technology.

To understand the Plasma Physics, Temperature and Ionization and various confinements. TEXT BOOKS:

1. S.W.Angrist, Direct Energy Conversion, Allyn and Bacon, Boston, 1982 2. W.Culp Archie, Principles of energy conversion, Tata McGraw Hill Publishing Co.Ltd., New

Delhi-2000. 3. K.Messerle Hugo Magneto hydrodynamic Electric Power Generator. JohnWiley&Sons, 1995.

REFERENCE BOOKS:

1. D.Lindon, Handbook of Batteries and Fuel Cells, McGraw Hill Book Co., 1984. 2. M.A.Greem, Solar Cells, Prentice Hall Inc, Englewood Cliffs, 1982. 3. Rakosh Das Begamudre, Energy Conversion System, New Age International (P) Ltd., New

Delhi, 2000. 4. M.A.Greem, Solar Cells, Prentice Hall Inc, Englewood Cliffs, 1982.

Page | 86

ME437 NUCLEAR POWER ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of nuclear power and safety norms at power stations.

Nuclear model of the atom - Equivalence of mass and energy - Binding - Radio activity - Half life - Neutron interactions - Cross sections. Mechanism of nuclear fission and fusion - Radio activity - Chain reactions - Critical mass and composition - Nuclear fuel cycles and its characteristics - Uranium production and purification - Zirconium, thorium, beryllium. Nuclear fuel cycles - spent fuel characteristics - Role of solvent extraction in reprocessing - Solvent extraction equipment. Reactors - Types of fast breeding reactors - Design and construction of fast breeding reactors - heat transfer techniques in nuclear reactors - reactor shielding. Nuclear plant safety- Safety systems - Changes and consequences of an accident - Criteria for safety - Nuclear waste - Type of waste and its disposal - Radiation hazards and their prevention - Weapons proliferation. OUTCOMES: Upon the completion of the course, the students are able:

To understand nuclear fuel cycles, characteristics, solvent extraction equipment.

To understand the nuclear plant safety, safety systems, consequence of accidents. TEXT BOOKS:

1. Thomas J.Cannoly, "Fundamentals of Nuclear Engineering ", John Wiley, 1978. REFERENCE BOOKS:

1. Collier J.G., and G.F.Hewitt, "Introduction to Nuclear Power ", Hemisphere Publishing, New York.1987

2. Lamarsh U.R. " Introduction to Nuclear Engineering Second Edition ", Addison Wesley M.A.1983

3. Lipschutz R.D. “Radioactive Waste - Politics, Technology and Risk ", Ballingor, Cambridge. M.A.1980.

Page | 87

ME438 FUEL CELL TECHNOLOGY L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of Fuel Cells and its production. Types-battery characteristics - voltage, current, capacity, electricity storage density, power, discharge rate, cycle life, energy efficiency, shelf life. Primary cells: Fabrication, performance aspects, packing and rating of zinc-carbon, alkaline-manganese, silver oxide cells. Lithium primary batteries. Fabrication, performance aspects and rating of lead acid and sealed lead acid battery, nickel-cadmium, Ni-metal-hydride lithium ion batteries, Rechargeable Zinc alkaline batteries and thermal batteries. Metal / air, zinc-bromine, sodium-beta alumina and lithium / iron sulphide batteries. Photogalvanic cells. Battery specifications for cars, heart pacemakers, torpedo batteries, satellite batteries. Classification, working principle, components, applications and environmental aspects of alkaline, phosphoric acid, solid oxide, molten carbonate, direct methanol and proton exchange membrane fuel cells. Sources of hydrogen - Hydrogen production – electrolysis, thermochemical methods, fossil fuel methods and solar energy method– gas clean-up – various methods of hydrogen storage. Hydrogen as an engine fuel - features and limitations. Ideal efficiency of a fuel cell.


To understand the concepts of fabrication and performance aspects of lead acid batteries. To understand production of Hydrogen through various methods.

TEXT BOOKS: 1. Dell, Ronald M. Rand and David A. J., “Understanding Batteries”, Royal Society of

Chemistry, 2001. 2. AuliceScibioh M. and Viswanathan B., “Fuel Cells – Principles and Applications”, University

Press, 2006. REFERENCE BOOKS:

1. Lindon David, “Handbook of Batteries”, McGraw Hill, 2002. 2. Kiehne H. A., “Battery Technology Handbook”, Expert Verlag, RenningenMalsheim, 2003. 3. Hoogers G. (Ed), “Fuel Cell Handbook”, CRC, Boca Raton, FL, 2003. 4. Palanna O.G., “Engineering Chemistry”, Tata Mc.Graw Hill Education Pvt. Ltd., New Delhi,

2009.

Page | 88

ME439 BIOFUELS L T P C 3 0 0 3

OBJECTIVE:

Explain fundamental and principles for chemical and biochemical biofuel synthesis. Differentiate between various renewable and non-renewable energy resources. Recognize the use of theoretical concepts of biofuel production technology at commercial level

Introduction and perspective of biofuels: Fossil versus renewable energy resources, economic impact of biofuels, Comparison of Bio-energy Sources, Biorefinery, biofuel production and applications, alternative energies, environmental impact of biofuel Harvesting Energy from Biochemical Reaction: Biochemical Pathways for various metabolic process, chemical oxygen demand and biological oxygen demand Biochemistry of Bioethanol production: Ethanol production from sugar and starch feedstock ethanol production from lingo cellulosic feedstocks, fermentation process and types of fermenters Biofuel Feedstocks and production of biofuel: Various types of feedstocks, starch feedstocks, sugar feedstocks, lingo cellulosic feed stocks, plant oils and animal fats, miscellaneous feed stocks Bioenergy from biomass as source of alternative energy: Wet milling of grain for alcohol production, grain dry milling cooking for alcohol production, use of cellulosic feed stocks for alcohol production chemistry of biodiesel production Bio Diesel production by using various microorganisms, algae and Trans esterification process: Chemistry of biodiesel production, oil Sources and production by plants and other sources, methods of biodiesel production Biological Production of Hydrogen by various microorganisms: Photobiological hydrogen production by using algae, Hydrogen Production by Fermentation various metabolic process for hydrogen production Bioreactor Design for Biofuel Production: Fermentation process, various types of fermenters, bioreactor operation and design OUTCOMES: Upon the completion of the course, the students are able to

To understand the fundamentals and principles of various fuel systems. To understand the production of Bio diesel through various methods.

TEXT BOOKS: 1. Biofuels by WimSoetaert, Erick J. Vandamme, Wiley, 2009 2. Biofuels Engineering Process Technology by Caye M. Drapcho, Terryh. Walker, M.G.Hills,


1. “Biofuels: Towards a Greener and Secure Energy Future” by P PBhojvaid, 2006. 2. “Biotechnology in China III: Biofuels and Bioenergy (Advances in Biochemical

Engineering/Biotechnology)” by Feng-Wu Bai and Chen-Guang Liu, 2012

Page | 89

ME440 PETROLEUM ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To enable the knowledge about Petroleum Industries and basic concepts To learn about various petroleum extraction processes and components

Introduction: Origin, migration, and accumulation of oil and gas fields. Methods of Petroleum Exploration: Geological, geophysical, geochemical, and hydrogeological surveys. Classification of Traps: Structural, stratigraphic, and combination traps. Drilling of Oil‐gas Wells: Different methods, directional and horizontal drilling, offshore drilling, drilling complications, formation evaluation. Drilling Fluids: Composition; Properties and types; Well completion methods Reservoir Engineering: Consideration of different reservoir parameters for exploration, development, and exploitation of petroleum; Reservoir fluid characteristics; Gas reservoir. Driving Mechanisms: Depletion drive, gas cap drive, water drive, combination drive; Gravity drainage. Secondary Recovery of Oil and Enhanced Oil Recovery Methods. Gathering, Processing and Transportation: Surface gathering systems; Gas processing; Liquid processing; Transportation of oil and gas. OUTCOMES: On successful completion of the course, the student will be able to,

Analyze the Thermodynamic behavior of hydrocarbon mixtures. Conduct testing methods to determine Petroleum reservoir parameters. Get knowledge about production operations equipment.

TEXT BOOKS: 1. Nontechnical Guide to Petroleum Geology, Exploration, Drilling and Production, 2nd Edition,

Hyne, Norman J., Penn Well Books, 2001. 2. Drilling Fluid Engineering Manual. Textbook prepared by M-I Drilling Fluids Co., 1998; 3. The Properties of Petroleum Fluids, 2nd ed., McCain, W. D., Penn Well Publishing Co., Tulsa, O

klahoma, 1990. 4. Tiab, D., Donaldson, E.C: Petrophysics: Theory and Practice of Measuring Reservoir Rock and

Fluid Transport Properties, 2ndedition, Elsevier, New York, NY, 2004. 5. Fundamentals of Reservoir Engineering, L. P. Dake, Elsevier Scientific Publishing Co, New York,


1. Reservoir Engineering Handbook, T. Ahmed, Gulf Professional Publishing, 2010. 2. Production Systems, M. J. Economides, A. D. Hill, and C. Ehlig-Economides, Prentice Hall,

Englewood Cliffs, NJ, 2012. 3. Petroleum Engineering Handbook, edited by H.B. Bradley, Society of Petroleum Engineers, 1987.

Page | 90

SEMESTER VII

OPEN ELECTIVE III

ME461 INDUSTRIAL SAFETY ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To learn about Safety Systems to be follow in Industries To learn about Safety Regulations

Safety Management - Accident and its Investigation - Occupational Health and Hygiene - Electrical

Safety - Safety in Machine Operation - Fire Safety – Safety in Material Handling - Ergonomic Safety –

Chemical Safety - Safety in Process Industries – Regulations and Standards.


Safety Systems in Industries, Safety Regulations TEXT BOOKS:

3. National Safety Council, “Accident Prevention Manual for Industrial Operations”, 14th Edition, 2015.

4. REFERENCE BOOKS:

4. Phil Hughes& Ed Ferrett, “Introduction to Health and Safety at Work”, National Examination Board in Occupational Safety and Health (NEBOSH), 2015.

5. Robert Bridger, “Introduction to Human Factors and Ergonomics”, CRC Press; 4th edition, 2017.

Page | 91

ME462 MECHATRONICS L T P C 3 0 0 3

OBJECTIVE:

To enable the students about the elements and techniques involved in Mechatronics systems which are very much essential to understand the emerging field of automation..

Train the students to design of Mechatronics systems. INTRODUCTION: Introduction to Mechatronics, need and applications, elements of mechatronic systems, role of mechatronics in automation, manufacturing and product development. ARCHITECTURE OF 8085 MICROPROCESSOR: Functional Block Diagram – Registers, ALU, Bus systems – Timing and control signals. PROGRAMMING OF 8085: Instruction formats – Addressing modes – Instruction set – Need for Assembly language – Development of Assembly language programs – Machine cycles and Timing diagrams. I/O interfacing: Memory mapped I/O scheme – I/O mapped I/O scheme – Input and Output cycles – Simple I/O ports – Programmable Peripheral Interface (8255). Data transfer schemes – Interfacing simple keyboards and LED displays. 8051 MICROCONTROLLER: Architecture – Memory Organization – Addressing modes – Instruction set – Boolean processing. 8051 PERIPHERALS: Interrupt structure – Timer, Serial ports and Power control: Features and Modes – Interfacing – Instruction set – Boolean processing – Simple programs – Typical Applications – MCS 51 family features 8031/8051/8751. MECHATRONICS SYSTEM DESIGN: Design process-stages of design process. Case studies of Mechatronics systems – Oil lubricating system – Engine Management system – Adaptive control in CNC machines. OUTCOMES: On successful completion of the course, the student will be able to,

Describe mechatronic systems and overview of control systems & actuators. Differentiate between various sensors, transducers and actuators and their applications. Relate various signal conditioning units, amplifiers, logic gates and their role in programmable

logic controllers. TEXT BOOKS:

1. Ramesh S Goankar, “Microprocessor Architecture: Programming and Applications with the 8085”, Penram International, Mumbai, 2000.

2. Kenneth Ayala, “The 8051 Microcontroller”, Delmar Cengage Learning, New Delhi, 2004. REFERENCE BOOKS:

1. Muhammed Ali Mazidi, Janice Gillispie Mazidi, Rolin D Mckinlay, “The 8051 Microcontroller and Embedded Systems”, Pearson Education India, New Delhi, 2011.

2. David Bradley, David Russell, “Mechatronics in Action”, Springer, 2010

Page | 92

ME463 ENERGY FROM WASTES L T P C 3 0 0 3

OBJECTIVE:

To import knowledge to the students about various energy sources from different forms of waste.

To enable the students’ knowledge of Bioconversion and its manufacturing systems. Energy plantations, short rotation species, forestry system, biomass resource agro forestry wastes, biomass energy development. Municipal solid wastes and agro processing industrial residues, environmental factors.

Metal emissions control technologies for waste incineration. Transition metals as catalysts for pyrolysis and gasification of biomass, Metal behavior during medical waste incineration. Distributed Energy generation through Non-Conventional Fuels and Fuel Cells.

Combustion, Pyrolysis, gasification and liquefaction, modeling, appliances and latest development. Estimating the heating value of sewage sludge.

Bio-diesel, ethanol, methanol, manufacture and properties. Converting waste to ethanol. Co firing tire-derived fuel and coal for energy recovery.

Bioconversion: biogas, fermentation and wet processes, chemicals from biomass and biotechnology. Ash utilization and Disposal, Nuclear fuels and solid radioactive waste forms.


Understand about Energy plantations and biomass energy development. Develop in depth knowledge about Bio fuels and its manufacturing systems. Design latest gasification and liquefaction systems for energy. Develop energy from Nuclear and radioactive waste.

TEXT BOOKS: 1. M. Rashid Khan, Clean Energy from Waste and Coal, American Chemical Society, 1992. 2. Michael A Ojovan, Handbook of Advanced Radioactive Waste Conditioning Technologies,

Woodhead Publishing, 2011. 3. Stephen J. McPhail, Viviana Cigolotti, Angelo Moreno, Fuel Cells in the Waste-to-Energy

Chain, Springer-Verlag London,2012. REFERENCE BOOKS:

1. Keith W. Waldron, Advances in Biorefineries: Biomass and Waste Supply Chain Exploitation, Woodhead Publishing,2014.

2. International Atomic Energy Agency,Design and operation of radioactive waste incineration facilities, International Atomic Energy Agency,1992.

Page | 93

SEMESTER VIII

ELECTIVE VI

ME441 DIGITAL MANUFACTURING L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of Digital Manufacturing.

Boundary representations (wireframe modeling), Solid representations (CSG/Boolean mathematics), Function representations (Parametric Modeling), Mesh Modeling/Digital Sculpting, Voxel representations/Medical Imaging/Modeling. NURBS Modeling/Bezier Surfaces, Parametric Modeling, Generative modeling, Mesh/Voxel Modeling Gantry Control (Cartesian), Delta Machine Control, Polar Machines Control, STL/AMF Slicing Safety, Liability and intellectual property, Environmental impact, On-demand fabrication models and mass customization, Mechanical properties of printed materials, Post processing, Multi-materials manufacturing Stereo lithography, Selective Laser Sintering, Fused Deposition Modeling and Polyjet/ink Jet printing/single/multi Layered object manufacturing, Digital Light Processing (DLP), Metal Additive Manufacturing (SLM, Inkjet, etc.), Sand/Ceramics Printing. Advanced materials - Electronic Materials, Bio printing, Food Printing


To understand various CAD representations such as Boundary representation, Solid representations, Function representations.

To understand the concepts of Stereo lithography, Selective Laser Sintering, Fused Deposition and additive manufacturing

TEXT BOOKS: 1. Zhou Zude, “Fundamentals of Digital Manufacturing Science”, Springer, 2012. 2. Brian Underdahl, “Digital Manufacturing for Dummies”, Protolabs(Wiley), 2015

REFERENCE BOOKS: 1. Jay Lee,LinxiaLiao,EdzelLapira, Jun Ni (auth.),LihuiWang,Andrew Y.C. Nee, “Collaborative

design and planning for digital manufacturing, Springer, 2009. 2. Neil Hopkinson,RichardHague,Philip Dickens, “Rapid manufacturing: an industrial revolution

for the digital age”, Wiley, 2003.

Page | 94

ME442 ROBOTICS AND AUTOMATION L T P C 3 0 0 3

OBJECTIVE:

To understand the functions of the basic components of a Robot. To impart knowledge in Robot Kinematics and dynamics. To impart knowledge on actuators and feedback components.

Industrial automation and Robotics, CAD/CAM and Robotics –An over view of Robotics –present and future applications –classification by coordinate system and control system. Function line diagram representation of robot arms, common types of arms. Components, Architecture, number of degrees of freedom –Requirements and challenges of end effectors, determination of the end effectors. Comparison of Electric Hydraulic and Pneumatic types of locomotion devices. Homogeneous transformations as applicable to rotation and translation –problems. Specifications of the matrices, D-H notation joint coordinates-problems World Coordinates Forward kinematics. Inverse kinematics Differential transformation and manipulators, Jacobians–problems. Lagrange –Euler and Newton –Euler formations –Problems. General considerations in path description and generation. Trajectory planning and avoidance of obstacles, path planning, Skew motion, joint integrated motion –straight line motion - Robot programming languages and software packages. Robot actuators and feedback components-Robot Application in Manufacturing – Actuators Pneumatic, Hydraulic actuators, electric &stepper motors. Feedback components Position sensors–potentiometers, resolvers, encoders –Velocity sensors. Applications of Robots Material Transfer - Material handling, loading and unloading- Processing - spot and continuous arc welding &spray painting. OUTCOMES:

Upon completion of this course, the students can able to apply the basic engineering Knowledge for the design of robotics for industrial applications.

TEXT BOOKS: 1. M P Groover, Industrial Robotics (Special Indian Edition), Tata McGraw-Hill Education, 2nd

Edition,2012. 2. Mair, G.M., Industrial Robotics, Prentice-Hall, 1988. 3. A.K.Gupta and S.K.Gupta, Industrial Automation and Robotics, University Science Press,

NewDelhi, 2009 . REFERENCE BOOKS:

1. Philippe Coiffet, Michael Chirouze, An Introduction to Robot Technology, Springer Science & BusinessMedia, Illustrated Edition, 2012

2. Craig J.J., “Introduction to Robotics Mechanics and Control”, Pearson Education, 2008. 3. Deb S.R., “Robotics Technology and Flexible Automation” Tata McGraw Hill Book Co., 1994. 4. Koren Y., “Robotics for Engineers", McGraw Hill Book Co., 1992. 5. Fu.K.S.,Gonzalz R.C. and Lee C.S.G., “Robotics Control, Sensing, Vision and Intelligence”,

McGraw Hill Book Co., 1987. 6. Janakiraman P.A., “Robotics and Image Processing”, Tata McGraw Hill, 1995. 7. Surender Kumar, “Industrial Robots and Computer Integrated Manufacturing”, Oxford and

IBH,1992. 8. Considine, D.M. and Considine, G.D., Standard Hand Book of industrial Automation, Chapman

and Hall, 1986.

Page | 95

ME443 PRODUCT DESIGN L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on the concepts of Product Design

Design briefing or product brief statement, Product Design Specification (PDS) and constraints vs. limits. Sketching skills and other skill sets evaluation, Design documentation Definition, Concept design, Concept generation and evaluation Design factors – manufacture, sales, purchase, cost, transport, and disposal. Material selection, Manufacture, Marketing and evaluation of the final design. OUTCOMES:

Upon the completion of the course, the students are understand the concepts of design, design factors, materials selection.

TEXT BOOKS: 1. Karl T Ulrich, Steven D Eppinger, Anita Goyal, “Product Design and Development”, Tata

McGraw-Hill, 2009. 2. Mike Ashby, Kara Johnson, “Materials and Design: The Art and Science of Material Selection

in Product Design”, Butterworth Heinemann, 2009. REFERENCE BOOKS:

1. Chitale.A.K, Gupta.R.C, “Product Design and Manufacturing”, Prentice Hall Of India, 2009. 2. Lal.G.K, Vijay Gupta, VenkataReddy.N, “Fundamentals of Design and Manufacturing”, Narosa

Book Distributors Private Limited, 2010.

Page | 96

ME444 ADDITIVE MANUFACTURING L T P C 3 0 0 3

OBJECTIVE:

Generating a good understanding of RP history, its development and applications.. To expose the students to different types of Rapid prototyping processes, materials used in RP

systems and reverse engineering. History – Development of RP systems – Applications in Product Development, Reverse Engineering, Rapid Tooling, Rapid Manufacturing- Principle – Fundamental – File format – Other translators – medical applications of RP – On demand manufacturing – Direct material deposition – Shape Deposition Manufacturing. Classification – Liquid based system – Stereolithography Apparatus (SLA), details of SL process, products, Advantages, Limitations, Applications and Uses. Solid based system – Fused Deposition Modeling, principle, process, products, advantages, applications and uses – Laminated Object Manufacturing Selective Laser Sintering – principles of SLS process, principle of sinter bonding process, Laser sintering materials, products, advantages, limitations, applications and uses. Three-Dimensional Printing – process, major applications, research and development. Direct shell production casting – key strengths, process, applications and uses, case studies, research and development. Laser Sintering System, e-manufacturing using Laser sintering, customized plastic parts, customized metal parts, e-manufacturing – Laser Engineered Net Shaping (LENS). Nature of material – type of material – polymers, metals, ceramics and composites- liquid based materials, photo polymer development – solid based materials, powder-based materials – case study. Introduction, measuring device- contact type and non-contact type, CAD model creation from point clouds-preprocessing, point clouds to surface model creation, medical data processing – types of medical imaging, software for making medical models, medical materials, other applications – Case study. OUTCOMES:

To provide knowledge on different types of Rapid Prototyping systems and its applications in various fields

TEXT BOOKS: 1. Rafiq I. Noorani, Rapid Prototyping, “Principles and Applications”, Wiley & Sons, 2006. 2. Chua C.K, Leong K.F and Lim C.S, “Rapid Prototyping: Principles and Applications”, Second

Edition, World Scientific, 2003. REFERENCE BOOKS:

1. N.Hopkinson, R.J.M, Hauge, P M, Dickens, “Rapid Manufacturing – An Industrial revolution for the digital age”, Wiley, 2006

2. Ian Gibson, “Advanced Manufacturing Technology for Medical applications: Reverse Engineering, Software conversion and Rapid Prototying”, Wiley, 2006

3. Paul F.Jacobs, “Rapid Prototyping and Manufacturing: Fundamentals of Stereolithography”, McGraw Hill 1993.

4. Pham. D.T., and Dimov. S.S., “Rapid Manufacturing”, Springer Verlog 2001.

Page | 97

ME445 MICROFLUIDICS L T P C 3 0 0 3

OBJECTIVE: To present the concept of the fluid flows at the micrometer scale and identify the dominant in various applications in micro devices. This course will also enhance the knowledge of microfluidics in the emerging microfluidics and interdisciplinary research area.

Introduction, application and scope of microfluidics; Scaling analysis. - Capillary driven microfluidics

- Stokes flow - Pressure-driven microfluidics - Diffusion and mixing in microfluidics - Droplet

microfluidics - Microfabrication and Bio-MEMs.

OUTCOMES: Upon completion of this course, the student can able to integrate fluid dynamics engineering concepts to examine and to model applicable to the micro systems. TEXT BOOKS: 1. Brian J. Kirby, Micro- and Nanoscale Fluid Mechanics: Transport in Microfluidic Devices. Cambridge: Cambridge University Press, 2010 2. Tabeling, P. Introduction to Microfluidics, Oxford, 2005. 3. Bruus, Henrik, Theoretical Microfluidics, Oxford University Press, 2008 REFERENCE BOOKS: 1. Probstein, R.F. Physicochemical Hydrodynamics, 2nd Ed., Wiley, 1994 2. Ronald L. Fournier, Basic Transport Phenomena in Biomedical Engineering, Fourth Edition, CRC press, 2017

Page | 98

ME446 INTRODUCTION TO TURBULENCE L T P C 3 0 0 3

OBJECTIVE: To introduce the physical behaviour and its associated mathematical framework to understand the turbulent flow in the engineering applications To impart a knowledge on theoretical, numerical and experimental techniques to characterize the nature of turbulence. Introduction to turbulence in engineering applications. Basic governing equations of the turbulent flow. Statistical description of turbulence. Experimental techniques to study the turbulent flows. Reynolds equations. Kolmogorov's theory. Scales of turbulence. Homogeneous or isotropic turbulence. Energy transfer. Spectral description. Introduction to turbulent free-shear flows and Bounded flows. Boundary layers. Simulating turbulent flows. Reynolds Averaged Navier-Stokes approach. Introduction to Large Eddy Simulations. Two-dimensional turbulence. OUTCOMES: Upon completion of this course, the students can able understand the nature of the turbulent fluid flow and formulate a numerical modelling. TEXT BOOKS: 1. H. Tennekes and J.L. Lumley, A First Course in Turbulence, The MIT Press, Cambridge, Massachusetts, and London, England, 1987. 2. Peter Davidson, Turbulence: An Introduction for Scientists and Engineers, Oxford University Press, 2015 3. S.B. Pope, Turbulent Flows, Cambridge University Press, UK., 2000 REFERENCE BOOKS: 1. Turbulence, By J. Hinze, New York: McGraw-Hill The Theory of Homogeneous Turbulence, By G. Batchelor, Cambridge University Press• 2. G. Biswas and V. Eswaran, 2002, Turbulent Flows: Fundamentals, Experiments and Modeling, Narosa Publishing House, New Delhi, India.

Page | 99

ME447 BIOFLUID MECHANICS L T P C 3 0 0 3

OBJECTIVE:

To present the current understanding of biofluid mechanics fundamentals their realization in human body flow systems.

Fundamentals: Basic concepts, properties and conservation laws of Fluid Mechanics, Introduction to physiological systems Circulatory bio fluid mechanics - Function of circulatory system, circulation in heart, blood and lymphatic vessels. Blood properties. Models for blood flow: Steady flow in tubes. Pulsatile flow in a rigid tube. Pulsatile flow in an elastic tube. Respiratory biofluid mechanics. Alveolar ventilation. Air flow in the lungs. Mechanics of breathing. Gas exchange and transport. Flow and pressure measurement techniques in human body.

OUTCOMES:

Upon completion of this course, the student can able to integrate fluid dynamics engineering concepts to examine and to model the biological flow in human body.

TEXT BOOKS: 1. 1.C.Ross Ethier and Craigg A. Simmons, Introductory Biomechanics, Cambridge texts in

Biomedical Engineering, 2007. 2. C. Kleinstreuer, Biofluid Dynamics: Principles and Applications, CRC Press, Taylor&Francis

Group, 2006. 3. M. Zamir, The Physics of pulsatile flow, Springer-Verlag NY, 2000. 4. J. N. Mazumdar, Biofluid Mechanics, World Scientific, 2004. 5. Y.C. Fung, Biodynamics: Circulation, Springer-Verlag NY, 1997.

REFERENCE BOOKS: 1. L. Waite & J. Fine, Applied Biofluid Mechanics, McGraw-Hill, 2007 2. F.M. White, Fluid Mechanics, McGraw-Hill (Any edition) 3. F.M. White, Viscous Fluid Flow, McGraw-Hill (Any edition)

Page | 100

ME448 ANALYTICAL METHODS FOR ENGINEERING

APPLICATIONS L T P C 3 0 0 3

OBJECTIVE:

To introduce the fundamentals of the engineering mathematics in a few engineering applications and to discuss the analytical solution methods of such problems.

Minimization of Functionals – one/many dependent/independent variables -Euler-Lagrange Equation - Brachistocrone Problem - Lagrangian Mechanics – one/many dependent/independent variables - Partial Differential Equations and their solutions – Heat Equation, Wave Equation Solution of General Partial Differential Equations using Separation of Variables - General nature of Boundary Value Problems, Interior & Exterior Dirichlet, Neumann & Robin Problems - Orthogonal functions: Sturm-Liouville problem. Bessel functions. Fourier-Bessel series. Fourier cosine/sine integrals. Fast Fourier transform (FFT).

OUTCOMES:

Upon the completion of the course, the students are familiar with the fundamentals in engineering mathematics in engineering applications.

TEXT BOOKS: 1. Partial Differential Equations for Scientists and Engineers by Stanley J. Farlow 2. The Calculus of Variations by Bruce van Brunt 3. Dennis G.Zill, Warren S.Wright, “Advanced Engineering Mathematics”, Jones&Barlett

learning 5th Ed. 2012. REFERENCE BOOKS:

1. R. V. Churchill and J. W. Brown. Fourier series and Boundary Value Problems, McGraw-Hill Book Company.

2. G. B. Gustafson and C. H. Wilcox, Analytical and Computational Methods of Advanced Engineering Mathematics, Springer.

3. W. E. Boyce and P. C. Diprima. Elementary Differential Equations and Boundary Value Problems, John Wiley and Sons.

Page | 101

SEMESTER VIII

ELECTIVE VII

ME449 INSTRUMENTATION AND CONTROL ENGINEERING

L T P C 3 0 0 3

OBJECTIVE:

To learn about Various Instruments used for Measurements in Industries To learn about Calibration of Measurement Instruments

BASICS OF MEASUREMENT SYSTEM AND DEVICES: Definition of metrology, accuracy, precision and sensitivity, Abbe’s principle. Three stages of generalized measurement system - mechanical loading - static characteristics of instruments - factors considered in selection of instruments - commonly used terms, error analysis and classification - sources of error. Principle of interferometry, laser interferometer. CALIBRATION OF INSTRUMENTS AND QUALITY STANDARDS : Calibration of measuring instruments - principles of calibration, Calibration of Instruments - Vernier caliper, Micrometer, feeler gauges, dial indicator, surface plates, slip gauges, care of gauge blocks. General cares and rules in measurement, ISO 9000 quality standards. Comparators - mechanical, electrical, optical and pneumatic. GEOMETRICAL MEASUREMENT AND MACHINE ELEMENTS: Angular measurement - optical protractors, sine bar, roundness measurement, limit gauge, design of plug gauge, Taylor’s principle and three basic types of limit gauges, Tomlinson surface meter and computer controlled CMM. ISO metric thread, measurement of major, minor and effective diameters. Gear terminology, spur gear measurement, checking of composite errors, base pitch measurement. POSITION, VIBRATION, TORQUE AND TEMPERATURE MEASUREMENT: Position sensors: potentiometer, LVDT, proximity sensors - types. Vibration sensors: accelerometer - types, vibrometer, seismic instrument. Torque sensors: strain gauge based and proximity sensor based. Temperature sensors: liquid in glass thermometer, pressure thermometer, resistance temperature detector, thermocouples and thermopiles, thermistor, optical pyrometer. PRESSURE AND FLOW MEASUREMENT: Elastic transducers - pressure cell, bulk modulus pressure gauge - Low Pressure Measurement: McLeod gauge - thermal conductivity gauge, calibration of pressure gauge. Flow measurement - turbine type meter, hotwire anemometer, magnetic flow meter. OUTCOMES: At the end of the course, the students will have the knowledge of

Various Measuring Instruments used in Industries Handle the Various Measurement Equipment

TEXT BOOKS: 1. Gupta.I.C, “A text book of Engineering Metrology”, Dhanpat Rai publications, New Delhi,

2007. 2. Beckwith.T.G,Roy D. Marangoni, John H. Lienhard, “Mechanical Measurements”, Prentice

Hall, 2006. REFERENCE BOOKS:

1. Holmen.J.P, “Experimental Methods for Engineers”, Tata McGraw Hill Publications CoLimited, 2004.

2. Jain.R.K, “Mechanical and Industrial Measurements”, Khanna Publishers, Delhi, 1999. 3. Alan S Morris, “Measurement and Instrumentation Principles”, Butterworth, 2006.

Page | 102

ME450 POWER PLANT ENGINEERING L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on components and its working in Power Plants Thermal power plant, Diesel power plant, gas turbine power plant, Nuclear power plant, hydroelectric power plant. Rankine cycle-superheat, reheat and regeneration, super critical cycles, combined cycles - binary cycles, cogeneration. Types of combustion, stokers, fuel and ash handling equipment. Selection of fans. Emission control, flue gas cleaning, particulate and gaseous emission control methods. Steam generators-types, forced circulation, high-pressure boilers and super critical boilers, fluidized bed boiler, boiler accessories and mountings, Draft- forced, induced and balanced drafts, Heat recovery equipment’s-economizers, air preheaters and reheaters, different types of superheaters and de-super heaters, Boiler testing, development of a process flow diagram, heat and mass balance of the components of a process flow diagram. Condensers and Cooling Towers, different types, design factors, air removal, performance calculation. Cooling towers-natural and mechanical draft types. Hydroelectric Power Plant, Runoff River plants, pumped storage plants, underground stations, hydal plant axillaries and plant operation. General nuclear fuels used in reactors, elements of nuclear reactor, moderator, control rods, coolants, description of different types of reactors. Radiation hazards, radioactive waste disposal. Renewable energy sources, concentrating collectors, photovoltaic cell. Horizontal and vertical types of wind turbines. Other plants: Geothermal plants, tidal power plant, biomass and biogas plant sand OTEC plants. Power Plant Economics, Plant load factor and utilization factor, cost economics – tariff rates, demand changes, load distributions. Energy conversion and audit. OUTCOMES: Upon the completion of the course

Able to understand Rankine Cycle, Superheating, Regeneration and Reheating. TEXT BOOKS:

1. Nag P K, “Power Plant Engineering”, Tata McGraw Hill, New Delhi, 2004. 2. Wakil M M El, “Power Plant Technology”, McGraw Hill Book Company Inc., New Delhi,


1. Rajput R K, “Power Plant Engineering”, Laxmi Publications (p) Ltd, 2006. 2. Rudramoorthy R, “Thermal Engineering”, Tata McGraw Hill, 2017. 3. Arora S C and Domkundwar S, “Power Plant Engineering”, DhanpatRai and Sons, New Delhi,

2001. 4. Ashok V Desai, “Non-Conventional Energy”, Wiley Eastern Limited, New Delhi, 1990.

Page | 103

ME451 AUTOMOTIVE FUELS AND POLLUTION CONTROL L T P C 3 0 0 3

OBJECTIVE:

Generating a good understanding of various liquid and gaseous fuel To train the students to implement the pollution control techniques

Liquid Fuels: Gasoline and Diesel - Physical and chemical properties. Fuel rating – octane rating and cetane rating - Fuel additives. Gaseour Fuels: LPG and CNG – Alternative Fuels: sources – Liquid fuels – vegetable oil and its derivatives – methanol and ethanol Gaseous fuels: methane and producer gas – physical and chemical properties. Pollutants from automobiles - carbon, nitrogen and sulfur compounds – aldehydes – particulate matter and smoke – odour – Influence of fuel constituents on pollutant emissions. Impact of pollutants on health and environment – Norms – ambient emission norms – noise level norms – waste disposal norms, Formation of hydrocarbons, oxides of nitrogen, sulphur and carbon monoxide in SI and CI engines. Formation of particulate emission from CI engine – Formation of aldehydes – Effect of operating parameters on the formation of pollutants. Chassis Dynamometer tests – CVS methods – Sampling techniques – Emission measurement – Chemiluminescence and NDIR Analysers – Flame ionization detector – smoke measurement: Comparison and obscuration’s methods – Bosch smoke meter-measurement of particulate matter. Influence of operating parameters in the control of pollutants – changes in the design of combustion chamber – Fuel modification – Exhaust gas recirculation - Catalytic convertors for spark ignition engines - NO

x reduction methods – Fuel additives to control emission - particulate traps.


Get knowledge about Automotive Fuels Get knowledge about causes of Pollution and its control methods

TEXT BOOKS: 1. JohnB.Heywood, Internal Combustion Engine Fundamentals, McGraw Hill International

Edition, 1988. 2. V.Ganesan, Internal Combustion Engines, Tata McGraw Hill, New Delhi, 1995.

REFERENCE BOOKS: 1. Paul Degobert, Automobiles & Pollution, Society of Automotive Engineers, 1995. 2. Obert, Edward, Internal Combustion Engines and Air Pollution, Harper and Row, 1973. 3. Crouse William, Automotive emission control, Gregg Division, McGraw Hill, New York, 1971. 4. George, Springer and Donald J Patterson, Engine emissions, pollutant formation and

measurement, Plenum press, 1973. 5. Osamu hirao, Present and future Automotive fuels, John Wiley and sons, New York, 1975.

Page | 104

ME452 FUNDAMENTALS OF COMBUSTION L T P C 3 0 0 3

OBJECTIVE:

To understand the principle of combustion in spark ignition and diesel engines. To introduce the thermodynamics concepts and chemical kinetics involved during combustion.

Introduction and Principle of combustion. Classification of fuels/oxidizers and its properties – Various combustion models – Scope and recent trends in combustion. Thermodynamics of combustion – Thermodynamic properties – Laws of thermodynamics – Stoichiometry – Adiabatic flame temperature – Chemical equilibrium Chemistry of combustion – Basic reaction kinetics, Fundamentals of elementary reactions, Chain reactions, Multistep reaction mechanism, Global kinetics Laminar and turbulent flames - Quenching, flammability, ignition and flame stabilization. Droplet combustion, spray formation and spray combustion.

OUTCOMES:

Upon completion of this course, the students will be able to understand the principles of the Combustion and its complexities involved in detail.

TEXT BOOKS: 1. Turns, S.R., An Introduction to Combustion concepts and Applications, 2nd ed., McGraw-Hill,

2000. 2. Glassman, I., Combustion, 3rd ed., Academic Press, 1996.

REFERENCE BOOKS: 1. Heywood, J.B., Internal Combustion Engine Fundamentals, McGraw-Hill, 1988. 2. Mukunda, H.S., Understanding Combustion, Macmillan, 1992. 3. Samir Sarkar, Fuels & Combustion, 2nd Edition, Orient Longman, 1990 4. Principles of Combustion by Kenneth Kuo, John Wiley 5. Combustion Theory by F. A. Williams, ABP

Page | 105

ME453 ADVANCED HEAT AND MASS TRANSFER L T P C 3 0 0 3

OBJECTIVE:

To provide basic understanding on various heat transfer process such as conduction, convection, radiation.

Conduction, convection, radiation, thermal conductivity, Fourier Law, Fick’s Law, Newton’s Law, Stefan Boltzmann’s Law, viscosity, heat transfer coefficient, mass transfer coefficient. Review of Steady State Governing equations and boundary conditions, Extended surfaces (fins) and analysis, 2-D Steady State Problems, Cylindrical and Spherical Geometries, Transient Conduction – General Lumped parameter Analysis, Method of separation of variables, Similarity Variable Method, Laplace Transforms, Heisler Charts, Green’s Functions, Numerical Methods – Implicit, Explicit and Crank Nicholson Method, Finite Element Method, Introduction to Inverse Heat Conduction Derivation of the full energy equation, Boundary layer approximations for momentum, heat and mass transfer, Similarity of Boundary Layers, Momentum, heat and mass transfer analogy, Blasius Similarity Solution, Karman-Pohlhausen Integral Solution, Forced Convection Heat and Mass transfer cylinders and spheres, Internal flow – Fully Developed flow for constant heat flux and constant temperature boundary conditions, Developing Flow, Graetz Problem, . Free convection, heat transfer from vertical and horizontal surfaces, Similarity Solution Pool boiling heat transfer, Nucleate Boiling and bubble growth, Critical heat flux, Film Boiling and Leiden frost point, Convective Boiling, Condensation, film wise condensation and drop wise condensation, Nusselt Model UNIT-V: Rayleigh and Wien Distribution, Planck’s Distribution, and Derivation of the Stefan Boltzmann Law, Spectral, Total, Hemispherical and Directional Emission, Irradiation, Reflection, Absorption and Transmission, Emissive power, Black Body and Grey body Definition, Radiation heat transfer between surfaces, shape factor, radiation shield.

OUTCOMES: Upon completion of this course, the students can able:

To differentiate heat process such as Conduction, Convection, Radiation and solve problems TEXT BOOKS:

1. Frank P Incropera and David P Dewitt, “Fundamentals of Heat and Mass Transfer”, Wiley India Private Limited, 2007.

2. Boundary Layer Theory, H. Schlicting, 7th Edition, Springer, 2014 REFERENCE BOOKS:

1. NecatiOzisik M, Heat Transfer –A Basic Approach, McGraw Hill, New York, 1995. 2. Fundamental of Heat Exchanger Design – R. K. Shah and D. Sekulic, John Wiley, 2003

BACHELOR OF TECHNOLOGY (B.Tech.) in ... - NIT Puducherry

Documents

Transcript of BACHELOR OF TECHNOLOGY (B.Tech.) in ... - NIT Puducherry