Bachelor of Technology in Mechanical

Engineering June 2018

GSFC University, Vadodara

Bachelor of Technology (B. Tech.) Program in Mechanical Engineering Curriculum

Code Course Title L-T-P Credits Code Course Title L-T-P Credits

I Semester II Semester

18C101 Basic of Electrical &

Electronics 3-0-2 4 18C201 Engineering Mechanics 4-0-2 5

18C102

Basic

English/Advanced

English

3-0-0 3 18C202 Computer Programming 1-0-4 3

18C103 Mathematics - I 3-1-0 4 18C203 Engineering Chemistry 3-0-2 4

18C104 Engineering Graphics 2-0-4 4 18C204 Basic of Civil Engineering 3-0-0 3

18C105 Engineering Physics 3-0-2 4 18C205 Mathematics - II 3-1-0 4

18C106 Basic of Mechanical

Engineering 3-0-0 3 18C206

Workshop Manufacturing

Practice 0-0-4 2

18NC01 Environmental Studies 2-0-0 0 18NC02 Basics of Industrial Safety 2-0-0 0 Total 28 22 Total 29 21

III Semester IV Semester

18C301 Mathematics - III 3-1-0 4 18ME401 Numerical Methods 2-0-2 3

18ME302 Engineering

Thermodynamics 3-1-0 4 18ME402 Fluid Mechanics 3-0-2 4

18ME303 Material Science &

Metallurgy 3-0-2 4 18ME403 Machine Design-I 3-1-0 4

18ME304 Solid Mechanics 3-0-2 4 18ME404 Dynamics of Machines 3-0-2 4

18ME305 Kinematic of Machines 3-1-0 4 18ME405 Manufacturing Technology 3-0-0 3

18ME306 Manufacturing Process 3-0-0 3 18ME406 Economics & Principles of

Management 3-0-0 3

18ME307 Student Industrial

Training - I 0-0-4 2 18MC407

Student Industrial Training-

II 0-0-4 2

Total 25 25 Total 24 23

V Semester VI Semester

18ME501 Computer Aided Design 0-0-4 2 18ME601 Operation Research 3-1-0 4

18ME502 Heat Transfer 3-0-2 4 18ME602 Manufacturing System 3-1-0 4

18ME503 Machine Design-II 3-1-0 4 18ME603 Thermal Engineering 3-0-2 4

18ME504 Industrial Engineering 3-1-0 4 18ME604 Refrigeration & Air

Conditioning 3-0-2 4

18ME505 Turbomachinery 3-0-2 4 18ME605 Professional Elective –II

(Even) 3-0-0 3

18ME506 Professional Elective - 1

(Odd) 3-0-0 3 18OE Open Elective 3-0-0 3

18ME507 Student Industrial

Training - III 0-0-4 2 18ME607

Student Industrial Training -

IV 0-0-4 2

Total 25 23 Total 24 24

VII Semester VIII Semester

18ME701 Energy Management

System 3-0-2 4 ME 801 Power Plant Engineering 3-1-0 4

18ME702 Fluid Power Control 3-0-0 3 ME 802 Professional Elective – IV

(Even) 3-0-0 3

18ME703 Professional Elective -

III (Odd) 3-0-0 3 ME 803 B. Tech Project 0-0-8 4

18OE Open Elective 3-0-0 3 ME 804 MOOC Courses - 1

18ME704 B. Tech Project 0-0-8 4

Total 22 17 Total 15 12

Grand Total 184 167

Semester - I Semester I B. Tech Civil Engineering

Sr.

No Couse Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/Wk. Theory Practical Total

Marks MS ES CE LW LE/ Viva

1 18C101 Basic of Electrical &

Electronics 3 0 2 4 5 20 50 30 25 25 150

2 18C102 Basic English/ Advanced

English 3 0 0 3 3 20 50 30 -- -- 100

3 18C103 Mathematics - I 3 1 0 4 4 20 50 30 -- -- 100

4 18C104 Engineering Graphics 2 0 4 4 6 20 50 30 25 25 150

5 18C105 Engineering Physics 3 0 2 4 5 20 50 30 25 25 150

6 18C106 Basic of Mechanical

Engineering 3 0 0 3 3 20 50 30 -- -- 100

7 18NC01 Environmental Studies 2 0 0 -- 2 -- -- -- -- -- P/F

Total 19 1 8 22 28 750

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

18C101 Basic of Electrical & Electronics Engineering

Prerequisites: Nil

Course Objectives: It is an introductory course which emphasize the fundamental concepts and overview of

Electrical Engineering & Electronics. The course work aims in imparting fundamental

knowledge on electronic components and communication engineering concepts.

Course Content

Electrical Engineering Study of voltage, current, power & energy. Application of Ohm’s law, Kirchhoff’s law, Lenz

law. Electromagnetic induction through working of a transformer. Concept of 1-phase, 3-

phase AC supply. Introduction of terms like RMS value, average value. Familiarity with

components like resistors, capacitors, diodes, LED’s, their application, uses, industrial

specification. Introduction to component data sheets.

Electrical Machines

Understanding the construction, type, principle of operation of various motors like DC,

Stepper, Servo, AC. Introduction to the concepts of motor selection and sizing

Electronics Electronics Engineering

Introduction of electronic components like diodes, LED’s, transistors, OpAmps, Gates

Industrial specification and data sheets of the components. Characteristics and usage of the

components. Signals: Analog & Digital. Introduction to industrial data acquisition

Test Equipment Introduction to Multimeter and Oscilloscope

Course Outcome This course is designed with industry focus. End of the course the students will be able to

appreciate the applications of electrical component.

Text/Reference Books 1. Albert Paul Malvino,” Electronic Principles”, Tata Mcgraw Hill,2002

2. Simon Haykin, “Communication Systems”, Wiley Eastern, Third Edition,19

L T P C

3 0 2 4

18C102 English

Prerequisite: Nil

Course Objectives 1. To enhance students’ proficiency in English language and acquaint him with English

Grammar

2. To enhance listening, speaking, reading and writing skills.

Course Content Grammar and Vocabulary: Types of sentences, Synonyms, Antonyms, Tenses Past, Present

& Future, Homophones, Modals, Verb forms, Phrasal Verbs, Error correction, commonly

misused words, Technical terms.

Listening and Speaking: Importance & types of listening, Introducing self, Communication

process & types, Listening comprehension, exercises, Ted talks, Barriers of communication,

how to overcome barriers, Speeches and Debates, Role plays, Group Discussion.

Reading: Reading of texts, Reading comprehension and exercises, News Paper reading based

exercise.

Writing: Application and letter writing: Complaint letter, placing an Order letter. Business

letters & application: complaint letter, leave application, Notice Writing. Article writing,

Précis Writing, Summarizing, Note taking and Note-making, Report writing: features and

format.

Text/Reference Books 1. High School English Grammar and Composition by Wren and martin.

2. 'Essential English Grammar by Raymond Murphy.

3. “Wings of Fire” by APJ Kalam

4. Beyond 2020: A Vision for Tomorrow’s India by AP J Kalam

5. Cambridge English Pronouncing Dictionary, Cambridge University Press, India, 2012

6. Word Power made easy.

7. Dhanavel, S.P. 2009. English and Communication Skills for Students of Science and

Engineering. Units 1-5. Chennai: Orient Blackswan Ltd. Meenakshi Raman and

Sangeetha

L T P C

3 0 0 3

18C103 Mathematics - I

Prerequisite: Differentiation and Integration (Basic calculus), Trigonometry

Course Objectives: 1. Gives a clear understanding of the ideas of calculus as a solid foundation for

subsequent courses in mathematics and other disciplines.

2. Comprehensive focus on teaching calculus based on concepts as well as

procedures.

3. Enables students to apply their knowledge and solve practical problems in physical

sciences and engineering.

Course Content: Review of limits, continuity, and differentiability of function of single variable;

indeterminate forms and L’Hospitals Rule. Roll’s theorem, Mean value theorems,

Evaluation of definite and improper integrals.

Sequences and series, Tests for convergence of series (nth term, Comparison, limit

comparison, Ratio, Root, Integral, Geometric series, Alternating series), Power Series, Taylor

Series, Maclaurin’s Series.

Partial Derivatives: Limit and continuity of functions of two variable, chain rule, total derivatives, Taylor’s series

expansion of function of two variables.

Applications of Partial Derivatives:

Maxima and minima, Lagrange multipliers, errors and approximation, implicit functions,

tangent plane and normal to a surface.

Multiple Integration: Double and Triple integration, Change of order of double integration, double integration in

Polar form, Jacobians and change of variables formula.

Vector Calculus:

Vector valued functions, gradient and directional derivatives, Line and surface integrals;

Divergence and curl, Vector identities, Theorems of Green, Gauss, and Stokes.

Course Outcomes: 1. Apply the concepts of limits, continuity and derivatives to solving problems.

2. Determine convergence or divergence of sequences and series

3. Use Taylor and MacLaurin series to represent functions. Solve application problems.

4. Define an improper integral; apply the concepts of limits, convergence, and

divergence to evaluate some classes of improper integrals.

5. Understand the concept of vector-valued function, differentiation and

integration of vector-valued functions.

6. Understand functions of several variables, limits, continuity, partial

derivatives, and differentials chain rules, directional derivatives gradients, tangent

planes, normal lines and extrema of functions of two variables.

7. Calculate and understand iterated integrals, double integrals, triple integrals and

change of variables in multiple integrals.

8. Understand vector analysis, vector fields, line integrals, and Green’s theorem.

Conservative Vector fields, and independence path. Surface integrals

divergence theorem and Stokes’s Theorem.

L T P C

3 1 0 4

Text/Reference Books: 1. Thomas, G.B., Finney, R.L., Calculus and Analytic Geometry, 9th Ed.,

Wesley/Narosa, (1998).

2. Ghorpade, S.R., Limaye, B.V., A course in Calculus and Real Analysis, Springer,

2006 (Indian Reprint) (2010).

3. Apostol, T.M., Calculus, Vol. I, 2b Edition, Wiley India, (2006).

4. Apostol, T.M., Calculus, Vol. II, Wiley India, (2007).

5. Kreyszig, K., Advanced Engineering Mathematics, 9th Edition, Wiley India,

(2011).

18C104 Engineering Graphics

Prerequisites: Nil

Objectives 1. To learn a hand-sketch skills for 2D and 3Ddrawings

2. To learn the theory of projections

3. To learn a 3D imaginational skill

4. To learn the descriptive geometry

5. To introduce students to basics of AUTOCAD

Course Content Introduction to Engineering Drawing:

Drawing instruments and their uses, Sheet layout, types of lines, lettering, dimensioning, scales, and

geometric construction, Engineering Curves: Introduction, conic curves (ellipse, parabola, and

hyperbola), cycloid, involute, spiral.

Projection of Points And Lines: Introduction to point and lines tracing of lines, Projection

of points, Lines, Plane and Solid. Projection of plane: Introduction to plane, Types of plane,

projection of plane in simple position, projection of plane inclined to the axis. Projection of

Solid: Introduction, Types of solid, projection of solid in simple positions, projection of solid

inclined to the axis. Section of Solids: Introduction, section of prism, pyramid, cylinder and

cone.

Orthographic Projection and Isometric projection: Orthographic Projection: Introduction,

principle of projection, method of projection, planes of projection. First and third angle

projection.

Isometric projection: Introduction, Isometric axis, Isometric scale, isometric drawing and

isometric view.

Symbols and Standard Sketches: Development of surface Welding symbols, Screw threads,

Interpretation of manufacturing drawing.

Software for Graphics: Introduction to graphic software, 2D and 3D drawing using

AUTOCAD, VISIO

Laboratory Practicals:

1. Practical Sheet (which includes dimensioning methods, different types of line,

construction of different polygon, divide the line and angle in parts, use of stencil)

2. Plane scale and diagonal scale.

3. Conic section.

4. Special curve.

5. Projection of line.

6. Projection of plane.

7. Projection of solid.

8. Development of surface.

9. Orthographic projection.

10. Isometric projection.

11. Symbols of welded joint and screw.

L T P C

2 0 4 4

Course Outcome 1. Interpret and synthesize information & ideas effectively. 2. Perform basic sketching techniques.

3. Draw orthographic projections and sections.

4. Use engineering scales.

5. Convert sketches to engineered drawings.

6. Use computer technologies for communication.

7. To create and modify two and three dimensional drawings using AUTOCAD.

8. Cultivate good communication and team work skills.

Text/References 1. N.D. Bhatt, Panchal, V.M., Engineering Drawing, 43rd Edition, Charotar Publishing

House, (2001).

2. Dhananjay, A.J., Engineering Drawing, TMH, (2008).

3. Shah, M.B., Rana, B.C., Engineering Drawing, 2ndEdition, Pearson Education, (2009).

4. French, T.E., Vierck, C.J., Foster, R.J., Graphic Science and Design, 4thEdition,

McGraw Hill, (1984).

5. Venugopal, K., Engineering Drawing and Graphics, 3rdEdition, New Age

International, (1998).

18C105 Engineering Physics

Prerequisites: Nil

Course Objectives 1. To familiarize the student with elementary concepts of Engineering Physics, and to

inculcate good habits of experimentation.

Course Content Noise and Vibrations:

Concept of Noise and its sources. Noise Terminology. Definition of Harshness,

acceptable levels and perception. Sources of Vibrations. Simple harmonic motion.

Damped harmonic oscillator and its energy decay, Quality factor. Forced harmonic

oscillator and its steady-state motion. Power absorbed by oscillator. Resonance.

Analogy between electrical and mechanical oscillations. Mathematical modeling of

vibrations.

Electromagnetism:

Laws of Electrostatics. Polarization and corresponding classification of materials.

Permittivity and Dielectric constants. Laws of Magnetostatics. Magnetization and

corresponding classification of materials, Permeability and susceptibility. Hysteresis.

Maxwell’s equations. Continuity equation.

Modern Optics:

Superposition of waves and Interference. Concept of Diffraction and types of

Diffraction. Fraunhofer diffraction of single and multiple slits. Types and applications

of Diffraction gratings. Bragg’s law. Concept of Polarization and types of Polarization.

Polarization using reflection, double refraction, and scattering. Optical activity.

Concept of Lasers, working and different types of Lasers, safety aspects, using lasers

as sensors.

Quantum Physics:

Black body radiation and concept of Photons, Photoelectric effect, de Broglie

hypothesis, wave-particle duality, Interpretation of wave-function, Uncertainty

relations, Schrodinger's wave-equation, Particle in a box. Laboratory Practicals (Eight experiments from the list below)

1. Understanding experimental errors and uncertainty when using laboratory equipment

2. To determine the frequency of vibrations on a string using Melde’s experiment

3. To understand some basic properties of electric fields and magnetic fields

4. To determine the frequency of the A.C. mains source using a sonometer

5. To determine magnetic hysteresis properties of ferromagnetic materials

6. To determine the wavelength of Laser source using diffraction gratings

7. To determine polarization of given light source using a smartphone

8. To determine planck’s constant using photoelectric effect setup

9. To determine wavelength of light using Newton’s rings setup

10. To determine wavelength of light using Newton’s rings on Virtual Labs

L T P C

3 0 2 4

Course Outcomes 1. Student would be proficient in application of basic physics principles to various

physical phenomena encountered in different branches of engineering and technology.

2. Student would learn necessary skills to work in a laboratory, and would be able to

acquire data, analyze data, and arrive at valid conclusions.

Text/Reference Books 1. Mechanical Vibrations and Noise Engineering by A, G. Ambekar, PHI Learning Pvt.

Ltd.

2. Electromagnetism by B. B. Laud, 2nd edition, Wiley Eastern Limited

3. Optics by E. Hetcht, 3rd edition, Addison Wesley Publishing Company

4. Quantum Mechanics by Aruldhas, 2nd edition, PHI Learning Pvt. Ltd.

5. The Feynman Lectures on Physics, 1st edition, Pearson Education (Available online).

18C106 Basic of Mechanical Engineering

Prerequisites: Basics of Science

Course Objectives 1. To introduce basic concepts of Mechanical Engineering

2. To impart Basic Mechanical Engineering principles.

Course Content Energy Sources Petroleum based solid, liquid and gaseous fuels, Calorific values of fuels, Combustion and

combustion products of fuels, Solar Power, Wind Power, Bio Fuels.

Pumps, Boiler, Turbine and Compressor

Pumps: Introduction and classification of pumps, Importance of pumps in industries.

Steam Formation and Properties:

Classification of boilers, Lancashire boiler, Babcock and Wilcox boiler, boiler mountings and

accessories wet steam, saturated and superheated steam, specific volume, enthalpy and

internal energy. Classification, Principle of operation of Impulse and reaction turbines,

Delaval’s turbine, Parson’s turbine. (No compounding of turbines).

Gas turbines: Classification, Working principles and Operations of Open cycle and closed

cycle gas turbines.

Water turbines: Classification, Principles and operations of Pelton wheel, Francis turbine

and Kaplan turbine. Air

Compressors: Types and operation of Reciprocating and Rotary air compressors,

significance of Multi-staging

Machine Tools

Turning, facing, knurling, Thread cutting, Taper Turning by swiveling the compound rest,

Drilling, Boring, Reaming, Tapping, Counter Sinking, Counter Boring, Plane milling, End

milling, Slot milling.

Engineering Materials and Joining Processes: Engineering Materials: Types and applications of Ferrous & Nonferrous metals and alloys,

Composites: Introduction, definition, Classification and applications (Air craft and

Automobiles)

Soldering, Brazing and Welding: Definitions, classification and method of soldering,

Brazing and welding. Differences between soldering, brazing and Welding. Description of

Electric Arc Welding and Oxy-Acetylene Welding.

Course Outcome 1. Gain idea about nature, scope and application of mechanical engineering principles.

Text/Reference Books 1. V. K. Manglik, “Elements of Mechanical Engineering”, PHI Publications, 2013.

2. S. Trymbaka Murthy, “A Text Book of Elements of Mechanical Engineering”,

4th Edition, 2006, Universities Press (India) Pvt. Ltd, Hyderabad.

3. K. P. Roy, S. K. Hajra Choudhury, Nirjhar Roy, “Elements of Mechanical Engineering”,

Media Promoters & Publishers Pvt. Ltd,Mumbai,7th Edition,2012.

L T P C

3 0 0 3

18CNC01 Environmental Studies

Prerequisite: Basics of science

Course Objectives: 1. To aware environmental issues i.e. Continuing problems of pollution, loss of forget,

solid waste disposal, degradation of environment, issues like economic productivity

and national security, Global warming, the depletion of ozone layer and loss of

biodiversity etc.

2. To know about ecology and values of environmental conservation,

3. To understand environmental concerns and to follow sustainable development practices

Course Content: Scope and Importance of Environmental Studies

Components of Environment, Status of India’s Environment & Need for Protection, Global

Environmental Crisis related to Population, Water, Sanitation and Land. Ecosystem: Concept,

Classification, Structure of Ecosystem, overview of Food chain, Food web and Ecological

Pyramid

Sustainable Development

Concept of sustainable development, Climate change and its mitigation, Social, Economic and

Environmental aspect of sustainable development. Carbon Credit –Introduction, General

concept

Types of carbon credit projects, Green Building.

Environmental Pollution

Air Pollution Sources and effects of air pollution, NAAQS Basic principles of air pollution

control devices Global effects of air pollution, Air Pollution due to automobiles, photochemical

smog Water Pollution: Sources and effects, Effluent standards Domestic and Industrial

wastewater and treatment principles, Land pollution:- Solid waste, solid waste management by

land filling, composting, Noise Pollution:- Sources and effects

E-waste: - Sources and effects.

Social Issues and the Environment From Unsustainable to Sustainable development, urban problems related to energy

Water conservation, rain water harvesting, watershed management, Resettlement and

rehabilitation of people; its problems and concerns. Case Studies, Environmental ethics: Issues

and possible solutions.

Climate change, global warming, acid rain, ozone layer depletion, nuclear accidents and

holocaust. Case Studies. Wasteland reclamation. Consumerism and waste products.

Environment Protection Act.

Air (Prevention and Control of Pollution) Act. Water (Prevention and control of Pollution)

Act

Wildlife Protection Act Forest Conservation Act. Issues involved in enforcement of

environmental legislation.

Course Outcomes

After learning the course the students should be able to

1. Understand and realize the multi-disciplinary nature of the environment, its

components, and inter-relationship between man and environment.

L T P C

2 0 0 -

2. Understand the relevance and importance of the natural resources in the sustenance of

life on earth and living standard.

3. Comprehend the importance of ecosystem, biodiversity and natural bio geo chemical

cycle.

4. To correlate the human population growth and its trend to the environmental

degradation and develop the awareness about his/her role towards environmental

protection and prevention.

5. Identify different types of environmental pollution and control measures.

6. To correlate the exploitation and utilization of conventional and non-conventional

resources

Text/Reference Books: 1. Agarwal, K.C. 2001 Environmental Biology, Nidi Publ. Ltd. Bikaner.

2. Bharucha Erach, the Biodiversity of India, Mapin Publishing Pvt. Ltd., Ahmedabad –

380 013, India.

3. Brunner R.C., 1989, Hazardous Waste Incineration, McGraw Hill Inc.

4. Clark R.S., Marine Pollution, Clanderson Press Oxford.

5. Cunningham, W.P. Cooper, T.H. Gorhani, E & Hepworth, M.T. 2001, Environmental

Encyclopedia, Jaico Publ. House, Mumbai.

6. De A.K., Environmental Chemistry, Wiley Eastern Ltd.

7. Down to Earth, Centre for Science and Environment.

8. Gleick, H.P. 1993. Water in crisis, Pacific Institute for Studies in Dev., Environment &

Security. Stockholm Env. Institute Oxford Univ. Press.

9. Jadhav, H & Bhosale, V.M. 1995. Environmental Protection and Laws. Himalaya Pub.

House, Delhi.

10. Mckinney, M.L. & School, R.M. 1996. Environmental Science systems & Solutions,

Web enhanced edition.

11. Mhaskar A.K., Matter Hazardous, Techno-Science Publication.

Semester – II Semester II B. Tech Civil Engineering

Sr.

No Couse Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/Wk. Theory Practical Total

Marks MS ES CE LW LE/ Viva

1 18C201 Engineering Mechanics 4 0 2 5 6 20 50 30 25 25 150

2 18C202 Computer Programming 1 0 4 3 5 20 50 30 25 25 150

3 18C203 Engineering Chemistry 3 0 2 4 5 20 50 30 25 25 150

4 18C204 Basic of Civil

Engineering 3 0 0 3 3 20 50 30 -- -- 100

5 18C205 Mathematics - II 3 1 0 4 4 20 50 30 -- -- 100

6 18C206 Workshop Manufacturing

Practice 0 0 4 2 4 -- -- -- 50 50 100

7 18NC02 Basics of Industrial Safety 2 0 0 0 2 -- -- -- -- -- P/F

Total 16 1 12 21 29 650

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

18C201 Engineering Mechanics

Course Outcome On Successful completion of the course, student will be able to enumerate the basic concept of

mechanics and fundamental of friction.

Course Content Rigid Body Statics

Vector algebra, force systems, moment of a force about a point and about an axis; simplest equivalent forces and moment; free body diagram; force equilibrium, equations of equilibrium; problems in two and three dimensions. Types of loading, supports and reactions; evaluating internal forces in bodies; axial force, Basic of shear force and bending moment. Planar Trusses and frames: static indeterminacy, analysis by method of joints and method of sections.

Center of Gravity and Moment of Inertia

First and second moment of area and mass, radius of gyration, parallel axis theorem, product

of inertia, rotation of axes and principal M.I., Thin plates, M.I. by direct method (integration),

composite bodies.

Friction

Types and laws of friction, impending motion problems involving large and small contact

surfaces: wedge friction, ladder friction, disk friction (thrust bearing), and belt friction.

Dynamics

Kinematics and Kinetics of particles: Particle dynamics in rectangular coordinates

cylindrical coordinates and in terms of path variables. Dynamics of rigid bodies: Newton’s laws, Chasle’s Theorem; D’ Alembert’s Principal, Work & Energy and Impulse Momentum methods, Impact.

Text/Reference Books 1. Shames, I.H., Rao, G.K.M., Engineering Mechanics – Statics and Dynamics,

Pearson‘s Education, (2006).

2. Desai and Mistry, "Engineering Mechanics", Popular Prakashan, Surat.

3. Beer, F.P., Johnston, E.R., Vector Mechanics for Engineers, Vol. 1 - Statics,

Vol. 2, Dynamics, 9thEdition, Tata McGraw Hill, (2011).

4. Meriam, J.L., Kraige, L.G., Engineering Mechanics, Vol. I Statics, Vol. 2

Dynamics, 6thEdition, John Wiley, (2008).

5. Timoshenko, S., Young, D.H., Engineering Mechanics, McGraw Hill Inc.,

(1940).

L T P C

4 0 2 5

18C202 Computer Programming

Course Outcome 1. Students would be capable to generate and edit technical reports using MS Word,

spreadsheets using MS Excel, and presentations using MS PowerPoint.

2. Students would gain basic understanding of good programming techniques, and would

be able to create and run programs for engineering applications.

Course Content MS Office Introduction to Microsoft Office package. Opening, closing, and saving files. Creating and

using templates. MS Word working environment, basic editing and formatting. Inserting and

formatting text and paragraphs. Formatting document styles. Inserting and editing tables and

lists. Inserting and editing graphics MS Excel working environment, basic editing and

formatting. Formatting cells, rows, and columns; and the data contained there-in. Inserting and

editing formulae and functions. Basic operations on data like filtering and sorting. Inserting

and editing graphics and charts. MS Power Point working environment, basic ideology of good

presentations. Inserting shapes, text, and smart art. Inserting and editing tables and lists.

Inserting and editing pictures, sounds, movies, and animations. Formatting slides with themes

and styles.

Matlab

Variables and Arrays: Types of variables, creating and clearing variables, basic mathematical

operations on variables. Types of arrays, creating and indexing multi-dimensional arrays,

clearing arrays, properties of arrays, basic mathematical operations on arrays. Writing Scripts:

Relational and logical operators, hierarchy of operators, conditional statements and structures,

repetitive structures, control of flow in programs, nesting operations. User-defined functions:

Importance of writing functions, input-output arguments, visibility and path of functions. Plots

and Figures: Basic 2 and 3-dimensional plots, special types of plots, subplots, overlay plots,

interactive plotting, regression, interpolation.

Text/Reference Books 1. Microsoft Office 2016 Step by Step by Joan Lambert and Curtis Fyre

2. MATLAB Programming for Engineers by Stephen Chapman

L T P C

1 0 4 3

18C203 Engineering Chemistry

Course Outcome 1. The confidence level of students will be improved to tackle problems in engineering

field related to chemical aspects.

2. The students understand novel materials with properties that find various engineering

applications.

3. Use the analysis results to ascertain quality of water, and other material.

Course Content Electrochemistry

Introduction, Electrochemical cell: Galvanic cell - Concentration cell, Electrode potential

Helmholtz electrical double layer, Nernst equation, Derivation and applications, Reference

electrodes: Standard hydrogen electrode – Saturated calomel electrode – pH determination

using glass electrode, Faraday’s law of electrolysis, Buffer solution and its application, theory

of buffer solution, Handerson Hasselblatch equation for acidic and basic buffer with numerical.

Corrosion, Control and Prevention

Introduction, Corrosion problems, Types of corrosion: Chemical Corrosion-Pilling Bedworth

Rule- and Electrochemical corrosion, Theory of corrosion, pitting corrosion, crevice corrosion,

waterline corrosion, factors affecting corrosion, Corrosion control methods, Corrosion

inhibitors.

Protective Coatings

Metallic coatings – Galvanizing, Tinning and electroplating – Nonmetallic coatings –

Chromate coating and Anodising. Powder coating – methods of application and advantages.

Water Technology

Types of impurities in water, Types of hardness, Units of hardness, Estimation of hardness-

EDTA method, Disadvantages of using hard water for industrial purpose-Scale and sludge

formation in boiler, Caustic embrittlement-Priming and foaming, Softening of water: Ion

exchange process-Lime soda process with numerical-Zeolite process-Desalination etc.

Drinking water and its characteristics, Reverse osmosis.

Polymer Technology

Classification of polymers, Types of polymerization, Moulding constituents of plastics,

Moulding techniques of plastics (Injection Extrusion, Blow moulding, Compression and

Transfer Moulding), -Preparation, properties and uses of PMMA, PET, Nylon, Bakelite and

Urea formaldehyde resins. Biodegradable plastics-PHBA, PLA. Conducting polymers-

Introduction-Preparation, properties and applications of Polyacetylene and polyaniline.

Text/Reference Books 1. Jain P.C.; Engineering Chemistry, Dhanpat Rai Publishing Company

2. S. S. Dara, “Engineering Chemistry”, S. Chand Publication, New Delhi.

3. Gowariker B.R.; Polymer Science, New Age International

L T P C

3 0 2 4

18C204 Basic of Civil Engineering

Course Outcome Students will learn about the basic areas of civil engineering, various methods of surveying

and levelling, types of buildings.

Course Content Civil Engineering

An Overview, role of civil engineers, job in civil engineering areas viz. Surveying, Town

Planning, Transportation Engineering, Water Resource Management, Structural Engineering,

Geotechnical & Foundation Engineering, Environmental Engineering, Construction Project

Management, Quantity Survey, Valuation, Earthquake Engineering, Disaster Management

etc.

Introduction to Surveying

Basic terminology of Surveying, Fundamental principles of surveying, Classification of

surveying, Basic Concepts of Linear measurement, Angular measurement.

Introduction to Civil Engineering Materials

Basic introduction to various traditional construction materials rock, brick, aggregate, cement,

sand, etc. Concrete types - PCC, RCC pre-stressed and precast. Introduction to smart materials,

recycling of materials, miscellaneous building materials i.e. Glass, Plastics, Paints, Ceramic

etc.

Basics of concepts of Building Construction

Basic introduction to foundation, type of foundation and its function, Types of construction

viz. load bearing, framed, composite etc., Types of building and its components, Basic concept

of loads viz. dead load, live load, wind loads, earthquake considerations.

Recent Trends in Civil Engineering

Green Buildings, Smart city, sky scarper, etc.

Text/Reference Books: 1. Basics of civil engineering S. S. Bhavikatti New age international Publishers.

2. Elements of Civil Engineering Author: Dr. R.K. Jain and Dr. P.P. Lodha Publisher:

McGraw Hill Education, India Pvt. Ltd.

3. Engineering Material, S.C. Rangwala, Charotar Publication.

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18C205 Mathematics - II

Course Outcome After the completion of course, students will learn:

1. The mathematical tools needed in evaluating multiple integrals and their usage.

2. The effective mathematical tools for the solutions of differential equations that model

physical processes.

3. The tools of differentiation and integration of functions of a complex variable that are

used in various techniques dealing engineering problems.

Course Content Multi variable Calculus (Intégration)

Multiple Integration: Double integrals (Cartesian), change of order of integration in double

integrals, Change of variables (Cartesian to polar), Applications: areas and volumes, Center

of mass and Gravity (constant and variable densities); Triple integrals (Cartesian), orthogonal

curvilinear coordinates, Simple applications involving cubes, sphere and rectangular

parallelepipeds; Scalar line integrals, vector line integrals, scalar surface integrals, vector

surface integrals, Theorems of Green, Gauss and Stokes.

First order ordinary differential equations

Exact, linear and Bernoulli’s equations, Euler’s equations, Equations not of first degree:

equations solvable for p, equations solvable for y, equations solvable for x and Clairaut’s

type

Ordinary differential equations of higher order: Second order linear differential equations

with variable coefficients, method of variation of parameters, Cauchy-Euler equation; Power

series solutions; Legendre polynomials, Bessel functions of the first kind and their properties. Complex Variable – Differentiation Differentiation, Cauchy-Riemann equations, analytic functions, harmonic functions, finding

harmonic conjugate; elementary analytic functions (exponential, trigonometric, logarithm)

and their properties; Conformal mappings, Mobius transformations and their properties.

Complex Variable – Integration

Contour integrals, Cauchy-Goursat theorem (without proof), Cauchy Integral formula

(without proof), Liouville’s theorem and Maximum-Modulus theorem (without proof);

Taylor’s series, zeros of analytic functions, singularities, Laurent’s series; Residues, Cauchy

Residue theorem (without proof), Evaluation of definite integral involving sine and cosine,

Evaluation of certain improper integrals using the Bromwich contour.

Text/Reference Books: 1. G.B. Thomas and R.L. Finney, Calculus and Analytic geometry, 9th Edition, Pearson,

Reprint, 2002.

2. Erwin kreyszig, Advanced Engineering Mathematics, 9th Edition, John Wiley &

Sons, 2006. W. E. Boyce and R. C. DiPrima, Elementary Differential Equations and

Boundary Value Problems, 9th Edn., Wiley India, 2009.

3. S. L. Ross, Differential Equations, 3rd Ed., Wiley India, 1984.

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4. E. A. Coddington, An Introduction to Ordinary Differential Equations, Prentice Hall

India, 1995.

5. E. L. Ince, Ordinary Differential Equations, Dover Publications, 1958.

6. J. W. Brown and R. V. Churchill, Complex Variables and Applications, 7th Ed., Mc-

Graw Hill, 2004.

18C206 Workshop & Manufacturing Practice

Course Outcome 1. Read and use a manufacturing drawing as a definition for the manufacturing of a part.

2. Realize and use their skills during their project work.

3. Understand the practical difficulties encountered in industries during any assembly

work.

4. To understand basic mechanical engineering.

5. Explain and strictly adhere to the mechanical workshop rules and safety regulations.

6. Properly operate the manufacturing equipment in the workshop.

7. Create and document a typical process plan for manufacturing of a product in the

mechanical workshop.

8. Cultivate good communication and team work skills.

Course Content Introduction to Manufacturing, Classification of manufacturing processes, Safety in

workshop, Engineering materials classification, Marking & measuring tools, holding tools,

cutting tools, Lathe machine, working principle and construction, various operations on a

lathe, shaping machine, operations on shapers, milling machine, Types of milling operations,

Tool geometry, Cutting tool materials. Hot & cold working. Black smithy, Common hand

forging tools, forging operations, Common bulk deformation processes (Rolling, Forging,

Extrusion and Drawing). Common sheet metal forming processes. Gas-Arc & resistance

welding, Brazing and soldering, Mechanical fastening, Heat treatment processes Ex.

annealing, normalizing, hardening and tempering, quenching.

Text/Reference Books 1. Hajra Choudhary, S. K., Elements of Workshop Technology, Media Promotors&

Publishers Pvt. Ltd, 12thEdition, (2002).

2. Chapman, W.A.J., Workshop Technology, ELBS Low Price Text, Edward Donald

Pub. Ltd., (1961).

3. Schey, J.A., Introduction to Manufacturing Process, 3rd.Edition, McGraw Hill,

(2000).

4. Singh, D.K., Fundamentals of Manufacturing Engineering, Ane Books Pvt. Ltd, New

Delhi, 2nd Edition, (2009).

5. Raghuwanshi, B.S., Course in Workshop Technology, DhanpatRai& Sons, New

Delhi, (1991).

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18NC02 Basic of Industrial Safety

Course Outcome 1. Understand various terms related to industrial safety, health & hazards.

2. Knowledge of various types of accidents, safety measures to prevent the same to be

taken during industrial visit.

3. Knowledge of relief system & types, HAZOP and process hazard checklist.

4. Knowledge of major industrial accidents and its consequences in and around the world.

Course Contents Introduction

Importance of safety programs in Industry, Engineering Ethics & Industrial Hygiene, Risk,

Hazard, and Danger & Accident.

Basic Laboratory, Industrial & personal protective safety equipment. Special safety equipment,

SCABA, Special Chemical protections etc. and chemical hazard symbols.

Introduction to Work permit system.

Toxicology, Fire & Explosion

Toxicity class, Entry points for toxic substances & organs affected, Carcinogenicity, LD50

Doses, TWA-TLV, PEL, NFPA DIAMOND, Material safety datasheet, confined spaces

hazards, oxygen scale, Prevention & control methods.

Fire & Fire triangle, Chemistry of Fire, effective ignition source, Static electricity & its control

method, Fire point, flash point, Flammable/Explosive limits, Pyrophoric materials, Auto

oxidation, Auto ignition temperature, types of explosion, BLEVE, vapor cloud explosion,

detonation & deflagration, TNT equivalent.

Introduction to Electrical & Constructional Safety & Hazards

Electrical Hazards, Electrical shocks causes & prevention methods.

Excavation & Erection site hazards & prevention methods

Introduction to relief and Hazard Identification

Relief concepts, definition, Location of relief, Relief types and characteristics, Relief scenario

& systems.

Process hazards checklist, Hazards & Operability studies, Safety Reviews

Case studies

Case studies of fire, explosion, incident in GSFC Ltd, Indian industry scenario, piper alpha

case, union carbide, Deep Water Horizon etc.

Text/Reference Books 1. D.A.CROWL & J.F. LOUVAR, Chemical Process Safety (Fundamentals with

applications) ,Prentice Hall , 2011

2. Fawcett H.H. and W.S. WOOD, Safety and Accident Prevention in chemical operations

, 2nd Edition John Wiley and Sons Inc(1982)

3. R.K. Sinnott, Coulson’s & Richardson’s , Chemical Engineering , Vol 6 , Elsevier India

, 2006

4. Skelton, B. (1997). Process safety analysis, Gulf Publishing Company, Houston,

210pp.

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Semester – III Semester III B. Tech Mechanical Engineering

Sr.

No Couse Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/Wk. Theory Practical Total

Marks MS ES CE LW LE/ Viva

1 18C301 Mathematics - III 3 1 0 4 4 20 50 30 -- -- 100

2 18ME302 Engineering

Thermodynamics 3 1 0 4 4 20 50 30 -- -- 100

3 18ME303 Material Science &

Metallurgy 3 0 2 4 5 20 50 30 25 25 150

4 18ME304 Solid Mechanics 3 0 2 4 5 20 50 30 25 25 150

5 18ME305 Kinematic of Machines 3 1 0 4 4 20 50 30 -- -- 100

6 18ME306 Manufacturing Process 3 0 0 3 3 20 50 30 -- -- 100

7 18ME307 Student Industrial Training

- I 0 0 0 2 -- -- -- -- 50 50 100

Total 20 3 4 25 25 800

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

Course Outcome Upon completion of this course, students will be able to solve field problems in engineering

involving PDEs. They can also formulate and solve problems involving random variables and

apply statistical methods for analysing experimental data.

Course Content Partial Differential Equation

Definition of Partial Differential Equations, First order partial differential equations,

solutions of first order linear PDEs; Solution to homogenous and non-homogenous linear

partial, differential equations of second order by complimentary function and particular

integral method. Second-order linear equations and their classification, Initial and boundary

conditions, D'Alembert's solution of the wave equation; Duhamel's principle for one

dimensional wave equation. Heat diffusion and vibration problems, Separation of variables

method to simple problems in Cartesian coordinates. The Laplacian in plane, cylindrical and

spherical polar coordinates, solutions with Bessel functions and Legendre functions. One

dimensional diffusion equation and its solution by separation of variables.

Probability

Probability spaces, conditional probability, independence; Discrete random variables,

Independent random variables, the multinomial distribution, Poisson approximation to the

binomial distribution, infinite sequences of Bernoulli trials, sums of independent random

variables; Expectation of Discrete Random Variables, Moments, Variance of a sum,

Correlation coefficient, Chebyshev's Inequality. Continuous random variables and their

properties, distribution functions and densities, normal, exponential and gamma densities.

Bivariate distributions and their properties, distribution of sums and quotients, conditional

densities, Bayes' rule.

Statistics

Basic Statistics, Measures of Central tendency: Moments, skewness and Kurtosis -

Probability distributions: Binomial, Poisson and Normal - evaluation of statistical parameters

for these three distributions, Correlation and regression – Rank correlation. Curve fitting by

the method of least squares- fitting of straight lines, second degree parabolas and more

general curves. Test of significance: Large sample test for single proportion, difference of

proportions, Tests for single mean, difference of means, and difference of standard

deviations. Test for ratio of variances - Chi-square test for goodness of fit and independence

of attributes.

Text/Reference Books

1. Erwin Kreyszig, Advanced Engineering Mathematics, 9th

Edition, John Wiley &

Sons, 2006.

2. N.P. Bali and Manish Goyal, A text book of Engineering Mathematics, Laxmi

Publications, Reprint, 2010.

3. P. G. Hoel, S. C. Port and C. J. Stone, Introduction to Probability Theory, Universal

Book Stall, 2003 (Reprint).

18C301 Mathematics - III

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Course Outcome 1. Basic concepts of Thermodynamics and first law can be understood.

2. PVT behaviors of fluids and Ideal gas processes can be understood.

3. Heat engines and Entropy concepts can be understood.

4. Students can be able to understand the Phase equilibria concepts.

5. Analyzing the thermal efficiencies of heat engines such as Carnot, petrol, diesel,

bryton , air standard cycle and the coefficients of performance for refrigerators and

heat pump.

Course Content Basic concepts: Thermodynamic system, Properties, State, Process, Thermodynamic

equilibrium, Pressure measurement, Zeroth law, Temperature measurement;

Concept of energy and energy transfer in the form of work and heat: Thermodynamic

definition and evaluation of work, Work transfer and its value for different processes, Heat

transfer; Equation of state for ideal and real gases, Gas mixtures

Energy analysis of closed and open systems: First law analysis for closed systems

undergoing cycle and process, Steady flow energy equation, Flow processes, Throttling

process, Joule-Thomson effect, Energy analysis of open systems, Analysis of First law for

unsteady flow;

Second law of thermodynamics and Thermodynamic property relations: Kelvin-Planck

and Clausius statement, Heat engine, Heat pump, Refrigerator, Concept of entropy, Entropy

principle, Change of entropy for various processes, Introduction to Availability, Concept of

Irreversibility, Second law efficiency, Maxwell relations, T-ds relation, Clausius-Clapeyron

equation;

Thermodynamic properties of pure substance: Phase change process of pure substance and

their property diagram, Use of steam table and Mollier diagram;

Real gas, Deviation with ideal gas, Generalized compressibility chart, Thermodynamics

relations, Maxwell relations and there applications.

Gas power cycles and Air Standard cycle: Otto, Diesel, Dual and Brayton cycles

Text/Reference Books 1. P.K.Nag; Engineering Thermodynamics; TMH

2. Van GJ; Thermodynamics; John Wylen

3. Cengel Y; Thermodynamics; TMH

4. Arora CP; Thermodynamics; TMH

5. Thermal Engineering by R Yadav

6. Engineering Thermodynamics by Omkar Singh New Age International.

7. Engineering Thermodynamics by Ratha Krishanan PHI India Pvt. Ltd.

8. Engineering Thermodynamics by M. Achuthan, PHI India.

18ME302 Engineering Thermodynamics

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Course Outcome After the completion of the course, student will be able to

1. Understand and apply fundamental scientific and engineering principles to

engineering problems in the context of inter-relationship between structure,

properties, processing and performance of all classes of materials and material

systems.

2. Have the ability to design, conduct, analyse and interpret behaviour of materials

Course Content Introduction

Classification of engineering material, ferrous & non-ferrous materials, unified numbering

system, material standard and specification

Structure of Metals and Alloys

Crystal Structure, Phase Diagram, Solid Solution, Grain boundaries, Iron-Carbon Phase

Diagram, Binary Iron Alloys, Ternary Phase Diagrams

Mechanical Behaviours of Metals & Alloys

Mechanical Properties, Deformation, Strengthening mechanisms, fracture mode, Docility of

materials, fracture mechanics, tensile properties, hardness, fatigue, creep

Heat Treatment

Introduction, Heat treatment of ferritic steels, constant temperature transformation,

transformation on continuous cooling, heat treatment processes, surface hardening,

carburizing, nitriding, shot peening, laser peening,

Material Degradation & Failure Analysis

Fundamental of Corrosion, Corrosion Control & Monitoring, Failure Causes of Material

Failure, Steps in Failure Analysis, Tools and stages in Failure Analysis,

Text/Reference Books 1. Smith, Foundations of Materials Science and Engineering, 4th Edition, McGraw Hill,

2009.

2. William D. Callister, Material science and Engineering and Introduction, Wiley,

2006.

3. V.Raghavan, Materials Science and Engineering, , PHI, 2007

18ME303 Material Science & Metallurgy

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Course Outcome On completion of the course, the student will be able to:

1. Describe the concepts and principles, understand the theory of elasticity including

strain/displacement and Hooke’s law relationships; and perform calculations, relative

to the strength and stability of structures and mechanical components.

2. Define the characteristics and calculate the magnitude of combined stresses in

individual members and complete structures; analyze solid mechanics problems using

classical methods and energy methods.

3. Analyze various situations involving structural members subjected to combined

stresses by application of Mohr’s circle of stress; locate the shear center of thin wall

beams; and

4. Solve torsion problems in bars and thin walled members.

Course Content Simple Stresses and Strains:

Concept of stress and strain, St. Venant’s principle, stress and strain diagram, Elasticity and

plasticity – Types of stresses and strains, Hooke’s law – stress – strain diagram for mild steel

– Working stress – Factor of safety – Lateral strain, Poisson’s ratio and volumetric strain –

Elastic moduli and the relationship between them – Bars of varying section – composite bars

– Temperature stresses. Strain Energy – Resilience – Gradual, sudden, impact and shock

loadings – simple applications.

Compound Stresses and Strains:

Two-dimensional system, stress at a point on a plane, principal stresses and principal planes,

Mohr circle of stress, ellipse of stress and their applications. Two dimensional stress-strain

system, principal strains and principal axis of strain, circle of strain and ellipse of strain.

Relationship between elastic constants.

Bending moment and Shear Force Diagrams:

Bending moment (BM) and shear force (SF) diagrams.BM and SF diagrams for cantilevers

simply supported and fixed beams with or without overhangs. Calculation of maximum BM

and SF and the point of contra flexure under concentrated loads, uniformly distributed loads

over the whole span or part of span, combination of concentrated loads (two or three) and

uniformly distributed loads, uniformly varying loads, application of moments.

Flexural Stresses & shear stresses:

Theory of simple bending – Assumptions – Derivation of bending equation: M/I = f/y = E/R -

Neutral axis – Determination of bending stresses – Section modulus of rectangular and circular

sections (Solid and Hollow), I,T, Angle and Channel sections – Design of simple beam

sections. Shear Stresses- Derivation of formula – Shear stress distribution across various beam

sections like rectangular, circular, triangular, I, T angle sections.

Torsion & thin cylinders:

Derivation of torsion equation and its assumptions. Applications of the equation of the hollow

and solid circular shafts, torsional rigidity, Combined torsion and bending of circular shafts.

Derivation of formulae and calculations of hoop stress, longitudinal stress in a cylinder, and

sphere subjected to internal pressures.

18ME304 Solid Mechanics

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Theories of failure, Column and strut, eccentricity.

Text/Reference Books

1. Timoshenko, S. and Young, D. H., “Elements of Strength of Materials”, DVNC, New

York, USA.

2. Hibbeler, R. C. Mechanics of Materials. 6th ed. East Rutherford, NJ: Pearson Prentice

Hall, 2004

3. Mechanics of Materials - Ferdinand P. Beer, E. Russel Jhonston Jr., John T. DEwolf –

TMH 2002.

4. Strength of Materials by R. Subramanian, Oxford University Press, New Delhi.

5. Bhavikatti S S “Strength of Materials”, Vikas Publication House, New Delhi,2007

6. Egar P. Popov & Toader A . Balan “Engineering Mechanics of Solids” 2nd Edition,

Pretice Hall of India Pvt Ltd, New Delhi, 2002.

7. Strength of materials by Dr. R.K. Bansal.

8. Ramamrutham,S, Strength of materials, DhanpatRai, New Delhi.

Course Outcome On completion of the course, student will be able to

1. Describe the concepts of machines, mechanisms and related terminologies. Both

analysis and Synthesis are useful in obtaining desired relative motion for specific

engineering purpose like motion of automobile and operations of lathe machine.

2. Find out displacement of follower and they able to draw cam profile.

3. Find out gear toothed profile, concept of interference and gear train.

Course Content Basics of Mechanisms

Mechanism, machine, plane and space mechanisms, kinematic pairs, kinematic chains and their

classification, degrees of freedom, Grubler’s criterion, kinematic inversions of four bar

mechanism and slider crank mechanism, equivalent linkages, pantograph, straight line motion

mechanisms, Davis and Ackermann’s steering mechanisms, Hooke’s joint.

Kinematics of Linkage Mechanisms

Kinematic analysis of plane mechanisms using graphical and Cartesian vector notations: Planar

kinematics of a rigid body, rigid body motion, translation, rotation about a fixed axis, absolute

general plane motion. General case of plane motion, relative velocity method, velocity and

acceleration analysis, instantaneous center and its application, Kennedy’s theorem, relative

motion, Coriolis component of acceleration; velocity and acceleration analysis using complex

algebra (Raven’s) method.

Kinematics of Cam Mechanisms

Cams: Classification of followers and cams, radial cam nomenclature, analysis of follower

motion (uniform, modified uniform, simple harmonic, parabolic, cycloidal), pressure angle,

radius of curvature, synthesis of cam profile by graphical approach, cams with specified

contours.

Gears and Gear Trains

Gears: Classification of gears, nomenclature, involutes and cycloidal tooth profile properties,

synthesis of tooth profile for spur gears, tooth system, conjugate action, velocity of sliding, arc

of contact, path of contact, contact ratio, interference and undercutting, helical, spiral, bevel

and worm gears. Gear Trains: Simple, compound, epicyclic gear trains; determination of gear

speeds using vector, analytical and tabular method; torque calculations in simple, compound

and epicyclic gear trains.

Text/Reference Books 1. Rattan SS; Theory of machines; TMH

2. Ambekar AG; Mechanism and Machine Theory; PHI.

3. Sharma CS; Purohit K; Theory of Mechanism and Machines; PHI

18ME305 Kinematic of Machines

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Course Outcome Upon completion of this course, students will be able to understand the different conventional

and unconventional manufacturing methods employed for making different products

Course Content

Conventional Machining Processes Casting and moulding: Metal casting processes and equipment, Heat transfer and

solidification, shrinkage, riser design, casting defects and residual stresses.

Introduction to bulk and sheet metal forming, plastic deformation and yield criteria;

fundamentals of hot and cold working processes; load estimation for bulk forming (forging,

rolling, extrusion, drawing) and sheet forming (shearing, deep drawing, bending) principles

of powder metallurgy

Metal cutting: Single and multi-point cutting; Orthogonal cutting, various force components:

Chip formation, Tool wear and tool life, Surface finish and integrity, Machinability, Cutting

tool materials, Cutting fluids, Coating; Turning, Drilling, Milling and finishing processes,

Introduction to CNC machining

Additive manufacturing: Rapid prototyping and rapid tooling

Joining/fastening processes: Physics of welding, brazing and soldering; design

considerations in welding, Solid and liquid state joining processes; Adhesive bonding.

Unconventional Machining Processes Abrasive Jet Machining, Water Jet Machining, Abrasive Water Jet Machining, Ultrasonic

Machining, principles and process parameters.

Electrical Discharge Machining, principle and processes parameters, MRR, surface finish,

tool wear, dielectric, power and control circuits, wire EDM; Electro-chemical machining

(ECM), etchant &maskant, process parameters, MRR and surface finish.

Laser Beam Machining (LBM), Plasma Arc Machining (PAM) and Electron Beam

Machining

Text/Reference Books 1. Kalpakjian and Schmid, Manufacturing processes for engineering materials (5th Edition)-

Pearson India, 2014

2. Mikell P. Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and

Systems

3. Degarmo, Black &Kohser, Materials and Processes in Manufacturing

18ME306 Manufacturing Processes

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Semester – IV Semester IV B. Tech Mechanical Engineering

Sr.

No Couse Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/Wk. Theory Practical Total

Marks MS ES CE LW LE/ Viva

1 18ME401 Numerical Methods 2 0 2 3 4 20 50 30 25 25 150

2 18ME402 Fluid Mechanics 3 0 2 4 5 20 50 30 25 25 150

3 18ME403 Machine Design-I 3 1 0 4 4 20 50 30 100

4 18ME404 Dynamics of Machines 3 0 2 4 5 20 50 30 25 25 150

5 18ME405 Manufacturing

Technology 3 0 0 3 3 20 50 30 -- -- 100

6 18ME406 Economics & Principles

of Management 3 0 0 3 3 20 50 30 -- -- 100

7 18MC408 Student Industrial

Training- II 0 0 0 2 0 -- -- -- -- -- 100

Total 17 01 6 23 24 800

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

18ME401 Numerical Methods

Course Outcome 1. Find the most approximate roots of equations in one variables.

2. Solve system of linear equations.

3. Find approximate derivative and definite integration using numerical techniques.

4. Interpolation and curve fitting of data

Course Content Solution Algebraic and Transcendental Equations: Bisection, False position, Newton

Raphson Method, Secant Method. Solution using Matlab.

Solution of system of Linear Equations: Gauss Elimination method, LU decomposition

method, Gauss Seidel method. Solution using Matlab.

Interpolation: Newton’s forward and backward interpolation, Newton’s divided difference

interpolating polynomials, Lagrange Interpolating polynomials. Solution using Matlab.

Numerical Differentiation: First and second order differentiation Equations of Equally

Spaced Data.

Solution using Matlab.

Numerical Integration: Trapezoidal rule, Simpson’s one third and 3/8th rule. Solution using

Matlab.

Numerical methods for Solution of ordinary differential equation: Taylor’s

series method, Euler’s method, Modified Euler’s method, Runge Kutta forth ordered method,

Milne’s Predictor Corrector Method. Finite element method to solve second order ODE.

Solution using Matlab.

Curve Fittings: General Linear Least Squares, Fitting of quadratic and exponential curves.

Solution using Matlab.

Text/Reference Books 1. Grewal. B.S., and Grewal. J.S., "Numerical Methods in Engineering and Science", 9th

Edition, Khanna Publishers, New Delhi, 2007.

2. Johnson. R.A., and Gupta. C.B., "Miller and Freund’s Probability and Statistics for

Engineers, Pearson Education, 2011

3. Spiegel. M.R., Schiller. J., and Srinivasan. R.A., "Schaum’s Outlines on Probability

and Statistics", Tata McGraw Hill Edition, 2004.

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18ME402 Fluid Mechanics

Objectives After completion of the course, student will be able to

1. Create a vision of understanding the momentum transfer process.

2. Analyze fluid flow concepts.

3. Review the practical importance and relevance of fluid flow in process industry.

Course Content Introduction and Fluid Statics

Fuid and flow definitions and types; Properties of fluids i.e. mass density, specific weight,

specific gravity, viscosity etc.; Continuum concept; Lagrangian & Eulerian approach.

Pascal’s Law; Hydrostatic Law; Manometry; Forces on plane and curved surfaces; stability

of floating and submerged bodies; Relative equilibrium.

Fluids Kinematics and Dynamics

Classification of fluid flows; Flow lines; Continuity equation; Stream function; Potential

function; Rotational flow rotation and vorticity; Flow Nets. Concept of system and control

volume; Bernoulli’s equation; Euler Equation, Derivation of Navier Stokes’s equation;

Venturimeter, orificemeter, Rotameter and Mouthpieces; Pitot tube.

Boundary Layer

Boundary layer concept; Displacement; Momentum and Energy thickness; Von-Karman

momentum integral equation; Laminar boundary layer flows; Drag on a flat plate; Boundary

layer separation and control. Streamlined and bluff bodies; lift and drag on a cylinder and an

airfoil. Reynold’s experiments; Prandtl mixing length hypothesis; Velocity distribution in

pipes; Concept of smooth and rough pipes; Pipe friction factor relations.

Dimensional Analysis:

Dimensional analysis, dimensional homogeneity, use of Buckingham-pi theorem, calculation

of dimensionless numbers

Flows in Pipes and Open Channels Various losses in pipe line and their measurement; Hagen-Poiseuilli law; Total and Hydraulic

gradient line; Pipes in series and parallel; Concept of equivalent pipe; Power transmission

through pipes.

Text/Reference Books 1. Fluid Mechanics, Y. Cengel and J. Cimbala, McGraw Hill Education (India) Pvt. Ltd,

New Delhi, 2 Edition, 2010.

2. A Text Book of Fluid Mechanics, R. K. Rajput, S. Chand Limited, 2008.

3. Fluid Mechanics, A. K. Mohanty, PHI Learning Pvt. Ltd., 2001.

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18ME403 Machine Design-I

Course Outcome 1. Identify the national and international standards pertaining to machine drawing.

2. Apply limits and tolerances to assemblies and choose appropriate fits.

3. Basic designing procedure.

4. Design under static loading conditions.

5. Design of riveted joint, welded joints, power screws, shafts, keys and couplings,

pressure vessels etc.

1. INTRODUCTION: Design engineering, basic requirements and procedure of design,

design synthesis, selection of preferred sizes, aesthetic and ergonomic considerations in

design, concurrent engineering, Standardisation & Codes

2. DESIGN CONSIDERATIONS: Selection of manufacturing method, design and

manufacturing considerations of casting, forging, machining and welding, design for

manufacture and assembly

3. DESIGN AGAINST STATIC LOAD: Modes of failure, factor of safety, types of

loads and stresses, design of simple parts subjected to tension, compression, shear,

bending, torsion and combined loads such as cotter joint, knuckle joint, levers, axle

4. SCREWS AND THREADED FASTENERS: Types of screw threads, Indian

standard proportions, design of power screw, screw jack and C-clamp, bolt of uniform

strength, bolt under tension, eccentrically loaded bolted joint in shear, eccentric load

perpendicular and parallel to axis of bolt, selection of standard fasteners, design of turn

buckle

5. WELDED JOINTS: Advantages and limitations of welded joints, butt and fillet

welds, stresses in butt and fillet welds, strength of butt, parallel and transverse fillet

welds, axially loaded unsymmetrical welded joints, eccentric load in plane of welds,

welded joints subjected to bending and torsional moments, welded joints subjected to

fluctuating loads

6. RIVETED JOINTS: Advantages and limitations of riveted joints, types of riveted

joints, design of riveted joints, and efficiency of riveted joints.

7. SHAFTS, KEYS AND COUPLINGS: Shafts: types of shaft, material for shaft,

standard sizes, , shaft design based on strength and rigidity, A.S.M.E. code for shaft

design, Castigliano's theorem Keys: types of keys, design of sunk, saddle, tangent,

Kennedy and round keys, design of splines Couplings: types of couplings, design of rigid

and flexible couplings

8. MECHANICAL SPRINGS: Types, applications and materials for springs, stress and

deflection equations for helical compression springs, Wahl's factor and its use in spring

design, end conditions, surge in spring, springs in series and parallel, concentric springs,

design of helical torsion, spiral and leaf springs, shot pinning

9. THIN AND THICK CYLINDERS: Classification, design of thick cylinders, Lame,

Clavarino and Birnie equations, autofretage, compound cylinders subjected to internal

and external pressure.

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Text Books: 1. Design of Machine Elements - V. B. Bhandari, Tata McGraw-Hill Publishing Co. Ltd.

2. A text book of Machine Design - P. C. Sharma, D. K. Aggarwal, S. K. Kataria & Sons.

Reference Books: 1. Machine Design, An integral approach - Robert L. Norton, Pearson

Education Inc.

2. Design of Machine Elements - M. F. Spott, T. E. Shoup, L. E. Hornberger, S. R. Jayram,

C. V. Venkatesh, Pearson Education Inc.

3. Mechanical Engineering Design - J. E. Shigley, C. R. Mischke, McGraw-Hill Publishing

Co. Ltd.,

4. Design Data (PSG College of Engg. & Tech.), DVP Printers

18ME404 Dynamics of Machines

Course Outcome 1. Analyse the concepts of static and dynamic force analysis of planar mechanisms.

2. Understand the importance of turning moment diagrams, fly wheels and governors its

analysis.

3. Understand concepts of various balancing of rotary and reciprocating mass.

4. Understanding of the concepts of vibrations and simple problems on forced damped

vibrations.

Course Content Dynamics of Engine Mechanisms Displacement, velocity and acceleration of piston; turning moment on crankshaft, turning

moment diagram; fluctuation of crankshaft speed, analysis of flywheel.

Balancing of Inertia Forces and Moments in Machines Balancing of rotating masses, two plane balancing, determination of balancing masses

(graphical and analytical methods), balancing of rotors, balancing of internal combustion

engines (single cylinder engines, in-line engines, V-twin engines, radial engines, Lanchester

technique of engine balancing

Governor Mechanisms Types of governors, characteristics of centrifugal governors, gravity and spring controlled

centrifugal governors, hunting of centrifugal governors, inertia governors

Free Vibration

Basic features of vibratory systems, Degrees of freedom, single degree of freedom ,Free

vibration, Equations of motion ,Natural frequency , Types of Damping ,Damped vibration,

Torsion vibration of shaft , Critical speeds of shafts ,Torsion vibration Two and three rotor

torsion systems

Gyroscopic Action in Machines

Text/Reference Books 1. Ambekar, AG; Mechanism and Machine Theory; PHI

2. Rattan SS; Theory of machines; TMH

3. Sharma and Purohit; Design of Machine elements; PHI

4. Bevan; Theory of Machines;

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18ME405 Manufacturing Technology

Course Outcome Choose appropriate instruments for the measurement/ inspection of the specified applications

Course Content Tooling for conventional and non-conventional machining processes: Mould and die

design, Press tools, cutting tools; Holding tools: Jigs and fixtures, principles, applications and

design; press tools – configuration, design of die and punch; principles of forging die design.

Measurement Fundamentals: The process of measurement- significance, generalized

measuring system Characteristics of measuring instruments: Static characteristics - Precision,

Accuracy, Sensitivity, Repeatability, Reproducibility, Linearity, Errors- Systematic and

Random, Uncertainty of Measurement, Standards - National, Reference, Secondary, and

Working Standards, interchangeability, Bias, Calibration, calibration of machine tools

Traceability, Confidence level.

Geometrical Dimensioning and Tolerance: Symbols, tolerance frame, datum surface.

Surface roughness – Representation methods and direction of lay. Welding: Symbolic

representation, symbols and dimensioning.

Limits, Fits and Tolerances - Types and calculations. Fasteners - Forms of threads and

types.

Metrology: Linear Measurement: Usage, Internal/ External calipers, Vernier caliper, Vernier

Height gauge, Depth gauge, Gear tooth vernier, plunger dials, Slip gauges, Inside / Outside

Micrometer. Angular Measurement: Sine Bar, Bevel protractor. Form Measurement: Sprit

level, Straight edges, Surface plate, Dial indicators for squareness, V-Blocks, Measurement

of major diameter, minor diameter, flank angle, pitch and effective diameter of screw

thread.Surface finish Measurement: Surface Roughness, Symbols, sample length, cut off

cutoff length, Roughness comparison as per specimen, Ra, Rz, Rq, Rt, Rp, Rv - Principle and

operation of stylus probe instruments. Inspection using gauges: Types- limit gauges, Snap

gauge, Plain plug gauge, ring gauges, Radius gauges, Feeler gauges - Gauge design.

Comparator - Mechanical comparator, Electronic comparator, Optical comparators,

Pneumatic Air gauge, Electronic Air gauge. Roundness tester- Surface Roughness tester

(Stylus and Skid). Measuring Machines: Auto collimator, Laser interferometer, Coordinate

measuring machine (CMM).

Text/Reference Books 1. Kalpakjian and Schmid, Manufacturing processes for engineering materials (5th

Edition)- Pearson India, 2014.

2. Anand K Bewoor and Vinay A Kulkarni, “Metrology and Measurement”, Tata

McGraw Hill, 2009.

3. Engineering Metrology & Measurement, N V Raghavendra, Oxford Press, 2009

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18ME406 Engineering Economics & Management

Course Outcome At the end of the course, student will be able to learn

1. The different engineering economic principles and strategies

2. Principles of management & Modern management concepts

Course Content Engineering Economics

Introduction to Economics, Scope and Definition, Importance of Economics in Engineering,

Demand and supply laws, Economic optimization, Demand and Revenue Analysis, Law of

Demand, Demand Functions, Classification of Demand, Demand Forecasting, Methods of

Demand Forecasting, Demand curves, Factors affecting Demand Factors Influencing

Demand, Types of demand Forecasting

Supply Cost & Output

Supply, Supply schedule, Law of Supply, Types of Costs, MOC, Cost of material, product &

labour cost, requirements of good costing system, Price and output Determination, Objectives

of pricing, Price Fixation, Pricing methods, Pricing Policies, Factors governing Pricing

Policies, Estimation of Break Even Point, Break Even analysis, Usefulness of BEP

Management & Its Environment: Management

Definition – Functions, Evolution of Modern Management movement, Types and Forms of

Business Organization, Designing effective organizations, Individual ownership –

Partnership, Joint stock companies, Cooperative enterprises, Public Sector Undertakings

Modern management Concepts

Management by Objectives (MBO), Features, MBO-Principles and Steps, MBO- Advantages

and Disadvantages, Management by Exception (MBE), Strategic Management-Levels of

strategy, SWOT analysis, Enterprise Resource Planning (ERP), Supply Chain Management

(SCM), Activity Based Management (ABM)

Text/Reference Books 1. Sasmita Mishra, “Engineering Economics and Costing “Eastern Economy Edition “ ,

2009

2. Khanna, “Industrial Engineering and Management”, Dahnpatrai Publications, 1980

3. L.M. Prasad, “Principles and practice of management”, Sultan Chand and Sons, 2015

4. Richard Pettinger, “Mastering Organizational Behaviour”, Macmillan Press, London,

2007

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Semester – V Semester V B. Tech Mechanical Engineering

Sr.

No Couse Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/

Wk.

Theory Practical Total

Marks MS ES CE LW LE/

Viva

1 18ME501 Computer Aided Design 0 0 4 2 4 -- -- -- 50 50 100

2 18ME502 Heat Transfer 3 0 2 4 5 20 50 30 25 25 150

3 18ME503 Machine Design-II 3 1 0 4 4 20 50 30 -- -- 100

4 18ME504 Industrial Engineering 3 1 0 4 4 20 50 30 -- -- 100

5 18ME505 Turbomachinery 3 0 2 4 5 20 50 30 25 25 150

6 18ME506 Professional Elective – I

(Odd) 3 0 0 3 3 20 50 30 -- -- 100

7 18ME507 Student Industrial

Training - III 0 0 0 2 0 -- -- -- -- -- 100

Total 15 02 08 23 25 800

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

Professional Elective – I (Odd) A Finite Element Analysis

B Design for Manufacturing

C Elements of Mechatronics

D Product Design & Value

Engineering

18ME501 Computer Aided Design

Course Outcome 1. Design a part or assembly of parts using Computer-Aided Design software.

2. Use parametric modeling techniques to reflect engineering requirements.

3. Apply top-down design principles to model a design.

4. Use motion and interference checking to ensure that parts will not interfere

throughout their complete range of motion.

5. Use CAD software collaboratively when designing in a team.

Course Content

Introduction: I.S Code of practice for machine drawing - Use of scales, types of lines.

Sectional views – full section, half section, revolved, removed section and hatching of

sections. Representation of materials and tolerances. Symbols of springs and gears.

Machining capabilities - dimensional accuracy and surface roughness values produced by

common production processes, Graphic User Interface, System Requirement, Basics and

User Interface, Command Manager, Managing CAD Environment

Sketching

Create and Edit Sketch, Sketch Selection Method, Basic Sketch Entities: Line, Circle,

Rectangle, Arc, Slot, Ellipse, Polygon, Geometric Relations and Dimension, Intermediate

Sketch Tools: Fillet, Chamfer, Mirror, Linear Sketch Pattern, Circular Sketch Pattern, Design

Intent, Sketching Guidelines, Practical Exercises

Basic Part Modeling

Basic Modeling, Terminology, Sketch Based Feature: Extrude, Extrude Cut, Revolve,

Revolve Cut, Swept, Swept Cut, Loft, Hole Wizard, Applied Based Feature: Fillet, Chamfer,

Shell, Evaluation Tools: Mass Properties: Calculating Weight/Mass and Other Geometric

Properties, Export/Import CAD Files, Practical Exercises

Advanced Part Modeling

Ribs, Draft, Configuration and Design Tables, Material Library and Assigning Material,

Library Features and Smart Fasteners, Boolean Operation, Design

Bottom-Up Assembly, Creating New Assembly, Positioning, Adding and Mating

Components, Using Part Configuration in Assemblies, Sub-Assemblies, Inserting Sub-

Assemblies Top-Down Assembly, Feature Manager, Design Tree and Symbols, Interference

Detection and Misalignment of Holes, Exploding Assemblies and Adding Explode Lines,

Generate Detail Drawing from Model

Drafting Overview, Drafting Sheet and Views, Adding Drawing Views, View Setting and

Drawing Properties, Annotation and Symbols, Sheet Format and Templates, Ballooning for

Nomenclature, Adding Bill of Material and Tables

Assembly drawing (Part to assembly) - Screw jack, Swivel bearing and Drilling Jig.

Component drawing (Assembly to part) - Steam Stop valve, Machine vice. Detailed

drawings - Piston, Die set, milling fixture.

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18C502 Heat Transfer

Course Outcome 1. Understand and calculate the conduction heat transfer in different geometries (plane

wall, cylinder, sphere).

2. Understand the heat transfer in natural and forced convection conditions, boiling and

condensation.

3. Understand and calculate the radiation heat transfer in different geometries.

Course Content Basic Concepts

Modes of heat transfer, Fourier’s law, Newton’s law, Stefan Boltzman law; thermal resistance

and conductance, analogy between flow of heat and electricity, combined heat transfer process;

Conduction: Fourier heat conduction equation, its form in rectangular, cylindrical and spherical

coordinates, thermal diffusivity, linear one dimensional steady state conduction through a slab,

tubes, spherical shells and composite structures, electrical analogies, critical-insulation-

thickness for pipes, effect of variable thermal conductivity.

Extended surfaces (fins)

Heat transfer from a straight and annular fin (plate) for a uniform cross section; error in

measurement of temperature in a thermometer well, fin efficiency, fin effectiveness,

applications; Unsteady heat conduction: Transient and periodic conduction, heating and

cooling of bodies with known temperatures distribution, systems with infinite thermal

conductivity, response of thermocouples.

Convection Introduction, free and forced convection; principle of dimensional analysis, Buckingham ‘pie’

theorem, application of dimensional analysis of free and forced convection, empirical

correlations for laminar and turbulent flow over flat plate and tubular geometry; calculation of

convective heat transfer coefficient using data book.

Heat exchangers Types- parallel flow, counter flow; evaporator and condensers, overall heat transfers

coefficient, fouling factors, log-mean temperature difference (LMTD), method of heat

exchanger analysis, effectiveness of heat exchanger, NTU method;

Mass transfer: Fick’s law, equi-molar diffusion, diffusion coefficient, analogy with heat

transfer, diffusion of vapour in a stationary medium.

Thermal radiation Nature of radiation, emissive power, absorption, transmission, reflection and emission of

radiation, Planck’s distribution law, radiation from real surfaces; radiation heat exchange

between black and gray surfaces, shape factor, analogical electrical network, radiation shields.

Boiling and condensation: Film wise and drop wise condensation; Nusselt theory for film wise

condensation on a vertical plate and its modification for horizontal tubes; boiling heat transfer

phenomenon, regimes of boiling, boiling correlations.

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Text/Reference Books 1.Dr. Ds Kumar BASICS OF HEAT AND MASS TRANSFER SK Kataria & sons

2. Sukhatme SP; Heat and mass transfer; University Press Hyderabad

3. Holman JP; Heat transfer; TMH

4. Nag PK; heat and Mass Transfer; TMH

5. Dutta BK; Heat Transfer Principles And App; PHI Learning

6. Mills AF and Ganesan V; Heat transfer; Pearson

7. Cengel Yunus A; Heat and Mass transfer;TMH

18C503 Machine Design-II

Course Outcome 1. Upon completion of this course, students will get detailed overview of the design

methodologies employed for the design of various machine components.

2. Apply limits and tolerances to assemblies and choose appropriate fits.

3. Detailed designing procedure.

4. Design under fatigue loading conditions.

5. Design of bearings, gears, clutched, flywheel, brakes, gear box etc.

Course Content 1. DESIGN AGAINST FLUCTUATING LOAD: Stress concentration – causes and

remedies, stress concentration factors, fluctuating stresses, fatigue failure, S-N curve,

endurance limit, notch sensitivity, design for finite and infinite life, Soderberg and Goodman

lines, modified Goodman diagrams, Gerber equation, and introduction to wear and creep

failures.

2. ROLLING CONTACT BEARINGS: Bearings, types of rolling contact bearings,

selection of bearing type, static and dynamic load carrying capacity, equivalent bearing load,

bearing life, load factor, design for cyclic loads and speeds, probability of survival, mounting,

failure causes and remedies

3. SLIDING CONTACT BEARINGS: Basic modes of lubrication, bearing characteristic

number, viscous flow through rectangular slot, design of hydrostatic bearing, design of

hydrodynamic journal bearings, bearing materials, failure causes and remedies, comparison

of rolling and sliding contact bearings

4. BRAKES: Design of block brake with shoe, pivoted block brake, internal expanding

brake, simple and differential band brake, caliper disk brake, friction material lining and

pressures

5. SPUR GEARS: Overview of gear drive terminology, standard systems of gear tooth,

interference and undercutting, backlash, gear material selection, force analysis, minimum no.

of teeth, estimation of module based on beam and wear strength for gears

6. HELICAL GEARS: Terminology, virtual number of teeth, force analysis, beam and wear

strength, herringbone gear design, crossed helical gears

7. BEVEL AND WORM GEARS: Terminology, proportions of worm gears, force analysis,

spiral bevel gears, friction in worm gears, material selection

8. DESIGN OF GEAR BOXES: Basic considerations in design of drives, determination of

variable speed range, preliminary steps in the design of multi speed gear box, structure

diagram, graphical representation of ray and speed diagram, rules and guidelines for layout.

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9. FLY WHEELS: Flywheel material, torque analysis, co-efficient of fluctuation of energy

and speed, design of solid disc and rimmed flywheels

10. FRICTION CLUTCHES: Classification, torque transmission capacity of plate clutches,

cone clutch and centrifugal clutch, friction material, thermal considerations in clutches

Text Books:

1. Design of Machine Elements - V. B. Bhandari, Tata McGraw-Hill Publishing Co. Ltd.

2. A text book of Machine Design - P. C. Sharma, D. K. Aggarwal, S. K. Kataria & Sons.

Reference Books: 1. Machine Design, An integral approach - Robert L. Norton, Pearson Education Inc.

2. Design of Machine Elements - M. F. Spott, T. E. Shoup, L. E. Hornberger, S. R. Jayram,

C. V. Venkatesh, Pearson Education Inc.

3. Mechanical Engineering Design - J. E. Shigley, C. R. Mischke, McGraw-Hill Publishing

Co. Ltd.,

4. Design Data (PSG College of Engg. & Tech.), DVP Printers

18C504 Industrial Engineering

Course Outcome At the end of the course, the students will be able to understand

1. The techniques and procedures of work study.

2. Plant layout and Material handling

3. Ergonomics of work design, production and productivity measurement

4. Concept of Production Planning and Control

Course Content Work measurement &Work Study: Introduction to Work measurement and its Techniques,

Production study and Time study, Standard time, Rating factors and Work sampling,

Techniques of Work study, Human factors of Work study, Method study, Techniques and

procedures of Productivity, Charging Techniques. Motion economy principles, SIMO chart,

Ergonomics and Industrial design.

Plant Layout and Material Handling: Plant location and site selection, Types, need, factors

influencing the plant layout, Tools and techniques for developing layout, process chart, flow

diagram, string diagram, Template and Scale models, Layout Planning procedure, Assembly

line balancing, Material Handling, scope and importance, Types of material handling

systems, Factors influencing material handling, Methods of material handling.

Work Design, Ergonomics, Production & Productivity: Introduction to work design, Work

design for increased productivity, The work system, design Introduction to job design,

Environmental factors, organizational factors & behavioural factors influencing effective job

design, Ergonomics, Objectives system approach of ergonomic, model, Man machine system

Production and Productivity, Definition of production, function and type of production,

Definition of productivity and productivity measurement.

Production Planning & Control: Objectives and Functions of PPC, Aspects of product

development and design, Process Planning, Principles of Standardization, Specialization and

Simplification, Group Technology, Optimum Batch size, ABC analysis, Value Engineering

Text/Reference Books 1. Khanna.O.P, “Industrial Engineering and Management”, DhanpatRai Publications Pvt

Ltd, 2010

2. Samuel Eilon, “Elements of Production Planning and Control”, McMillan andCo.,

Digitized, 2007.

3. Maynard.H, “Industrial Engineering Hand Book”, McGraw Hill Book Co.,

NewYork, 2010

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18C505 Turbomachinery

Course Outcome After learning the course, the students should be able:

1. Learn the benefits and limitations of fluid power compared with other power

transmission technologies.

2. Understand the operation and use of different hydraulic machines like hydraulic

crane, fluid coupling and fluid torque convertor etc.

3. Formulate and analyze models of hydraulic components.

4. Design and predict the performance of fluid power components.

Course Content INTRODUCTION Introduction to impact of jet. Theory of turbo machines and their

classification, Elements of hydro-electric power plant, Impulse Turbine: - principle,

constructional features, Installation of Pelton Turbine, Velocity Diagram and Analysis,

working proportions, Design parameters, Performance characteristics, Governing.

REACTION OR PRESSURE TURBINE principles of operation, Degree of reaction,

comparison over Pelton Turbine, Development of reaction turbine, Classification, Draft tube,

Cavitation in Turbine, Francis Turbine, Propeller Turbine, Kaplan Turbine: - Types,

Constructional features, Installations, Velocity Diagram and analysis, working proportions,

Design parameters, Performance characteristics, Governing, selection of turbines. Unit

quantities, HYDRODYNAMIC PUMP Classification and Applications, Centrifugal pumps:-

Principle of operation, Classification, Component of Centrifugal Pump installation, Priming

methods, Fundamental equation, Various heads, Velocity heads, Velocity triangles and their

analysis, slip factor, Effect of outlet blade angle, Vane shapes, Losses and Efficiencies of

pumps, Multi staging of pumps, Design Consideration, Working proportions, N.P.S.H.,

Cavitation in pumps, Installation and operation, Performance characteristics, Pump and

system matching and Introduction to self-priming pumps. POSITIVE DISPLACEMENT

PUMP Basic principle, Classification, Reciprocating Piston / Plunger Pumps:- Types, Main

Components, Slip, Work Done, Indicator Diagram, cavitation, Air vessels, Gear pump, Screw

pump, Vane pump Compressors: Reciprocating Compressors Construction and working,

Multistage conditions for minimum work, Intercooling, Efficiency and control of air

compressors Rotary Compressors: Introduction, Classification, roots blower, Vane type,

Screw compressor, Scroll compressor Centrifugal Compressors: Essential parts, Static and

total head properties, Velocity diagram, Degree of reaction, surging and choking, Losses in

centrifugal compressor Axial Flow Compressors: Construction of an axial flow compressor,

Aero foil blading, Lift and drag, Performance characteristics

Text/Reference Books 1. Sonntag, R. E, Borgnakke, C. and Van Wylen, G. J., 2003, 6th Edition, Fundamentals

of Thermodynamics, John Wiley and Sons.

2. Jones, J. B. and Duggan, R. E., 1996, Engineering Thermodynamics, Prentice-Hall of

India

3. Moran, M. J. and Shapiro, H. N., 1999, Fundamentals of Engineering

Thermodynamics, John Wiley and Sons

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Semester – VI Semester VI B. Tech Mechanical Engineering

Sr.

No

Couse

Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/

Wk.

Theory Practical Total

Mark

s MS ES CE LW LE/

Viva

1 18ME601 Operation Research 3 1 0 4 4 20 50 30 -- -- 100

2 18ME602 Manufacturing System 3 1 0 4 4 20 50 30 -- -- 100

3 18ME603 Thermal Engineering 3 0 2 4 5 20 50 30 25 25 150

4 18ME604 Refrigeration & Air

Conditioning 3 0 2 4 5 20 50 30 25 25 150

5 18ME605 Professional Elective – II

(Even) 3 0 0 3 3 20 50 30 -- -- 100

6 18OE Open Elective 3 0 0 3 3 20 50 30 -- -- 100

7 18ME607 Student Industrial Training -IV 0 0 0 2 0 -- -- -- 50 50 100

Total 18 2 4 24 24 800

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

Professional Elective – II (Even)

A Advance Manufacturing Processes

B Industrial Robotics & Automation C Vibration & Condition Monitoring D IC Engine

Open Electives

01 Advanced Process Safety (Chemical

Engineering)

02 Corrosion Engineering (Chemical Engineering)

03 Nanotechnology (Mechanical Engineering)

04 Renewable Energy (Mechanical Engineering)

05 Sustainable Building Technology (Civil

Engineering)

06 Heat Ventilation & Air Condition System of

Building (Civil Engineering)

07 Soft Skills and Interpersonal Communication

(Humanities & Social Science)

08 Professional Ethics (Humanities & Social

Science)

09 Introduction to Account & Finance for Engineers

(Management)

10 Innovation, Business Models and

Entrepreneurship (Management)

11 Project Management

12 Total Quality Management

18C601 Operation Research

Course Outcome Upon completion of this course, the students would be able to:

1. Formulate and solve linear programming problems.

2. Solve the problems on networks models such as Transportation, Assignment, Shortest

path, minimal spanning tree, and Maximal flow.

3. Solve the problems of Project Management using CPM and PERT.

Course Content Scope of Operations Research: Introduction to linear and non-linear programming

formulation of different models. Linear Programming: Geometry of linear programming,

Graphical method, Linear programming (LP) in standard form, Solution of LP by simplex

method, Exceptional cases in LP, Duality theory, Dual simplex method, Sensitivity analysis.

Integer Programming: Branch and bound technique. Transportation and Assignment

Problem: Initial basic feasible solutions of balanced and unbalanced

transportation/assignment problems, Optimal solutions. Project Management: Construction of

networks, Network computations, Floats (free floats and total floats), Critical path method

(CPM), Crashing. Game Theory: Two-person zero-sum game, Game with mixed strategies,

Graphical method and solution by linear programming.

Inventory Control: Deterministic models; safety stock inventory control systems.

Text/Reference Books Taha H.A., Operations Research-An Introduction, PHI (2007).

Swarup, K., Gupta, P. K., Mammohan, Operations Research, Sultan Chand & Sons, (2010).

Pant J. C., Introduction to optimization: Operations Research, Jain Brothers (2004)

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18ME602 Manufacturing System

Course Outcome 1. Explain role of computers and information technology in manufacturing systems

2. Develop an FMS (Flexible Manufacturing System) layout for given simple part

family, using group technology concepts to and make proper grouping as per their

attributes.

3. Basic of CNC machines and part programming

4. Identify and use of manufacturing support system

5. To gain knowledge about recent trends in manufacturing

Course Content Overview of Manufacturing: Manufacturing Industries & Products, Manufacturing

Operation, Production Facilities, Product/Production Relationships, Production Performance

Metrics, Manufacturing Costs,

Basic elements of automated system, Level of Automations

Computer Numerical Control: Fundamentals of NC Technology, application, Analysis of

Positioning Systems, NC Part Programming

Manufacturing System

Flexible Manufacturing System: concept, definition and comparison with other

manufacturing systems. Major elements of FMS and their functioning: Tool handling system,

Material handling system, Automated guided vehicles (AGV), Automated storage and

retrieval system (AS/RS).

Manufacturing Support Systems: Process planning–Computer Aided Process planning,

types. Production Planning- Master production schedule, bill of material, inventory record,

working of Material Requirements Planning and its outputs. Shop floor control – phases of

shop floor control, factory data collection system.

Recent Trends: Computer Integrated Manufacturing (CIM): need, block diagram, functional

areas covered and their importance. Protocols in CIM- their features, functions and

applications, Artificial intelligence- concept, definition and application areas, neural network:

working principles, applications and limitations. Lean manufacturing - concept, sources of

waste, benefits and applications. Factory of future (FOF).

Text/Reference Books 1. Mikell P. Groover, “Automation, Production systems and computer integrated

manufacturing”, Prentice Hall of India Private Ltd., New Delhi, 2007.

2. Mikell P. Groover, Emory W. Zimmers Jr., “CAD/CAM:Computer Aided Design

and Manufacturing”, Prentice Hall of India Private Ltd., New Delhi, 2008.

3. Hans B. Kief and Frederick Waters, T., “Computer Numerical Control - A

CNCReference Guide”, Macmillan / McGraw-Hill, New York, 1992.

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18ME603 Thermal Engineering

Course Outcome 1. Identify and understand construction and working of thermal system.

2. Develop understanding of boilers, nozzles and compressors.

3. Demonstrate skills required for assessment of efficiency of thermal system.

4. Understanding of gas dynamics fundamentals.

Course Content Steam generators: classification, conventional boilers, high-pressure boilers performance and

rating of boilers, equivalent evaporation, boiler efficiency, heat balance sheet, combustion in

boilers, super critical boilers, fuel and ash handling, boiler draught, overview of boiler codes.

Phase Change Cycles: Vapor Carnot cycle and its limitation, Rankin cycle, efficiency of

ranking cycle, modified Rankin cycle, reheat cycle, perfect regenerative cycle, Ideal and actual

regenerative cycle with single and multiple heaters, regenerative-reheat cycle, binary-vapor

cycle, work done and efficiency calculations.

Gas dynamics: speed of sound, in a fluid mach number, mach cone, stagnation properties,

onedimensional isentropic flow of ideal gases through variable area duct-mach number

variation, area ratio as a function of mach number, mass flow rate and critical pressure ratio,

effect of friction, velocity coefficient, coefficient of discharge, diffusers, normal shock.

Reciprocating compressors, staging of reciprocating compressors, optimal stage pressure

ratio, effect of intercooling, minimum work for multistage reciprocating compressors.

(a) Steam nozzles: isentropic flow of vapors, flow of steam through nozzles, condition for

maximum discharge, effect of friction, super-saturated flow. (b) Steam condensers, cooling

towers: introduction, types of condensers, back pressure and its effect on plant performance air

leakage and its effect on performance of condensers, various types of cooling towers.

Text/Reference Books 1. Arasu Valan A; Thermal Engineering; TMH

2. Nag PK; Basic and applied Thermo-dynamics; TMH

3. Nag PK; Power plant Engineering; TMH

4. Rathakrishnan E; Gas Dynamics; PHI Learning

5. Balachandran P; Gas Dynamics for Engineers; PHI Learning

6. Yahya SM; Fundamentals of Compressible flow; New Age

7. Gordon J. Van Wylen; Thermodynamics 8. R.Yadav Thermal Engg.

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18ME604 Refrigeration & Air Conditioning

Course Outcome 1 Illustrate the fundamental principles and applications of refrigeration and air conditioning

system

2 Obtain cooling capacity and coefficient of performance by conducting test on vapor

compression refrigeration systems

3 Present the properties, applications and environmental issues of different refrigerants

4 Calculate cooling load for air conditioning systems used for various applications

5 Operate and analyse the refrigeration and air-conditioning systems.

Course Content Introduction: Principles and methods of refrigeration, unit of refrigeration, coefficient of

performance, vortex tube & thermoelectric refrigeration, adiabatic demagnetization; air

refrigeration cycles- Joule’s cycle Boot-strap cycle, reduced ambient cycle and regenerative

cooling cycles.

Vapour compression system: Vapor compression cycle, deviations from theoretical cycle,

sub-cooling and super heating, effects of condenser and evaporator pressure on cop; multi-

pressure system: removal of flash gas, multiple expansion & compression with flash inter

cooling; low temperature refrigeration: production of low temperatures, cascade system, dry

ice, production of dry ice, air liquefaction system.

(a) Vapour absorption system: Theoretical and practical systems such as aquaammonia,

electrolux & other systems;

(b) Steam jet refrigeration: Principles and working, simple cycle of operation, description

and working of simple system,

(c) refrigerants: nomenclature & classification, desirable properties, common refrigeration,

comparative study, leak detection methods, environment friendly refrigerants and refrigerant

mixtures, brine and its properties

Psychrometric: Calculation of psychrometric properties of air by table and charts;

psychrometric processes: sensible heating and cooling, evaporative cooling, cooling and

dehumidification, heating and humidification, mixing of air stream, sensible heat factor;

principle of air conditioning, requirements of comfort air conditioning, ventilation standards,

infiltrated air load, fresh air load human comfort, effective temperature & chart, heat

production & regulation of human body,

Air conditioning loads: calculation of summer & winter air conditioning load, bypass factor

of coil, calculation of supply air rate & its condition, room sensible heat factor, grand sensible

heat factor, effective sensible heat factor, dehumidified air quantity. Problems on cooling load

calculation. Air distribution and ventilation systems

Text/Reference Books

1. Arora C. P., Refrigeration and Air Conditioning, Tata McGraw-Hill

2. Manohar Prasad, Refrigeration and Air Conditioning, Willey Eastern Ltd, 1983

3. McQuiston, ― Heating Ventilating and air Conditioning: Analysis and Design‖ 6th

Edition, Wiley India

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4. Arora and Domkundwar, Refrigeration & Air Conditioning, Dhanpatrai & Company,

New Delhi

5. Khurmi R.S. and Gupta J.K., Refrigeration and Air conditioning, Eurasia Publishing

House Pvt. Ltd, New Delhi,1994.

6. Ballaney P.L., Refrigeration and Air conditioning, Khanna Publishers, New Delhi,

1992

Semester – VII Semester VII B. Tech Mechanical Engineering

Sr.

No

Couse

Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/Wk.

Theory Practical Total

Marks MS ES CE LW LE/

Viva

1 18ME701 Energy Management

System 3 0 2 4 5 20 50 30 25 25 150

2 18ME702 Fluid Power Control 3 0 0 3 3 20 50 30 -- -- 100

3 18ME703 Professional Elective - III

(Odd) 3 0 0 3 3 20 50 30 -- -- 100

4 18OE Open Elective 3 0 0 3 3 20 50 30 -- -- 100

5 18ME704 B. Tech Project 0 0 8 4 6 -- -- -- -- -- 100

Total 12 0 10 17 20 550

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

Professional Elective – I (Odd)

A Finite Element Analysis

B Design for Manufacturing

C Elements of Mechatronics

D

Product Design & Value

Engineering

Open Electives

01 Advanced Process Safety (Chemical

Engineering)

02 Corrosion Engineering (Chemical Engineering)

03 Nanotechnology (Mechanical Engineering)

04 Renewable Energy (Mechanical Engineering)

05 Sustainable Building Technology (Civil

Engineering)

06 Heat Ventilation & Air Condition System of

Building (Civil Engineering)

07 Soft Skills and Interpersonal Communication

(Humanities & Social Science)

08 Professional Ethics (Humanities & Social

Science)

09 Introduction to Account & Finance for Engineers

(Management)

10 Innovation, Business Models and

Entrepreneurship (Management)

11 Project Management

12 Total Quality Management

18C701 Energy Management System

Course Outcome 1. Identify and assess the energy conservation/saving opportunities in different mechanical

system.

2. Identify and assess energy conservation opportunities in thermal system.

3. Demonstrate skills required for energy audit and management.

4. Suggest cost-effective measures towards improving energy efficient and energy

conservation.

Course Content Energy Audit Methodology and recent trends. General Philosophy, need of Energy Audit and

Management, EC Act, Definition and Objective of Energy Management, General Principles

of Energy Management. Energy Management Skills, Energy Management Strategy.

Economics of implementation of energy optimization projects, it’s constraints, barriers and

limitations, Financial Analysis: Simple Payback, IRR, NPV, Discounted Cash flow; Report-

writing, preparations and presentations of energy audit reports, Post monitoring of energy

conservation projects, MIS, Case-studies / Report studies of Energy Audits. Guidelines for

writing energy audit report, data presentation in report, findings recommendations, impact of

renewable energy on energy audit recommendations. Instruments for Audit and Monitoring

Energy and Energy Savings, Types and Accuracy. Case studies of implemented energy cost

optimization projects in electrical utilities as well as thermal utilities. 11 25-30% 3. Thermal

Systems: Boilers- performance evaluation, Loss analysis, Water treatment and its impact on

boiler losses, integration of different systems in boiler operation. Advances in boiler

technologies, FBC and PFBC boilers, and Heat recovery Boilers- its limitations and

constraints. Furnaces- Types and classifications, applications, economics and quality aspects,

heat distributions, draft controls, waste heat recovering options, Heat saving and application

criteria. Steam Utilization Properties, steam distribution and losses, steam trapping,

Condensate, Flash steam recovery. 10 20-25% System Audit of Mechanical Utilities: Pumps,

types and application, unit’s assessment, improvement option, parallel and series operating

pump performance. Energy Saving in Pumps & Pumping Systems. Bloomers (Blowers) types

& application, its performance assessment, series & parallel operation applications &

advantages. Energy Saving in Blowers Compressors, types & applications, specific power

consumption, compressed air system,& economic of system changes. Energy Saving in

Compressors & Compressed Air Systems Cooling towers, its types and performance

assessment & limitations, water loss in cooling tower. Energy Saving in Cooling

Towers .Study of 4 to 6 cases of Energy Audit & Management in Industries (Boilers, Steam

System, Furnaces, Insulation and Refractory, Refrigeration and Air conditioning,

Cogeneration, Waste Heat recovery etc.)Study of Energy Audit reports for various Industries

and Organizations

Text/Reference Books 1. Energy Audit and Management, Volume-I, IECC Press

2. Energy Efficiency in Electrical Systems, Volume-II, IECC Press

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3. Energy Management: W.R.Murphy, G.Mckay, Butterworths Scientific

4. Energy Management Principles, C.B.Smith, Pergamon Press

5. Industrial Energy Conservation, D.A. Reay, Pergammon Press

6. Energy Management Handbook, W.C. Turner, John Wiley and Sons, A Wiley

Interscience

7. Industrial Energy Management and Utilization, L.C. Witte, P.S. Schmidt, D.R.

Brown, Hemisphere Publication, Washington, 1988

8. Hand Book of Energy Audits, Albert Thumann, P.E., C.E.M. William J. Younger,

C.E.M., CRC Press

18C702 Fluid Power Control

Course Outcome After completion of the course, student will be able to

1. Classify the properties of pneumatic and hydraulic systems and their applications

2. Classify and select the pumps and motors for the required applications

3. Design the fluid systems with speed, pressure and direction control

4. Design the hydraulic and pneumatic circuits for the given application.

Course Content Introduction to Hydraulic and Pneumatics, Fluids for Hydraulic System, Distribution of Fluid

Power, Energy Losses in Hydraulic System, Hydraulic Actuators, Direction Control Valves,

Pressure Control Vales, Flow Control Valves, Hydraulic Circuit Design, Servo Valves,

Accumulators, Accessories used in Fluid Power System, Introduction to Pneumatics,

Cooling, Drying, Conditioning, and Distribution of Compressed Air, Pneumatic Actuators,

Pneumatic Control Valves, Single and Multi-Actuator Circuit, Pneumatic Circuit Design.

Text/Reference Books 1. Anthony Esposito, “Fluid Power with applications”, Prentice Hall International, 2009

2. Majumdar.S.R, “Oil Hydraulic Systems: Principles and Maintenance”, Tata McGraw

Hill, 2006.

3. Majumdar.S.R, “Pneumatic systems – principles and maintenance”, Tata McGraw-

Hill, New Delhi, 2006\

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18C704 B. Tech Project

Project is a course requirement wherein under the guidance of a faculty member,

a final year student is required to do an innovative work with application of

knowledge earned while undergoing various courses and laboratories in the

curriculum of mechanical engineering. The project can be based on industrial

defined/ user defined project. Through project work the student has to exhibit

both analytical and practical skills. The project is done in two semesters, i.e. 7 th

and 8th, on a continuous problem.

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Semester – VIII

Semester VIII B. Tech Mechanical Engineering

Sr.

No

Couse

Code Course Name

Teaching Scheme Exam Scheme

L T P C Hrs/Wk

.

Theory Practical Total

Mark

s M

S

E

S

C

E

L

W

LE/

Viva

1 18ME801 Power Plant Engineering 3 1 0 4 4 20 30 50 -- -- 100

2 18ME802 Professional Elective – IV

(Even) 3 0 0 3 3 20 30 50 -- -- 100

3 18ME803 B. Tech Project - II 0 0 8 4 8 -- -- -- -- -- 100

4 18ME804 MOOC Courses - - - 1 - - - - - - 50

Total 6 1 8 12 15 350

MS - Mid Semester, ES - End Semester, CE - Continuous Evaluation, LW - Laboratory Work, LE - Laboratory Exam

Professional Elective - II

A Advance Manufacturing Processes

B Industrial Robotics & Automation

C Vibration & Condition Monitoring D IC Engine

18C801 Power Plant Engineering

Course Outcome 1. Able to familiar with power plant systems, terms and definitions and basic power

plant engineering design calculations

2. Familiar with the proper design and application of power plant related equipment

3. Able to prepare and present topical issues relevant to power plant design and

operations

Course Content Introduction to Power Plants and Boilers Layout of Steam, Components, Selection - Steam Boilers and Cycles – High Pressure and

Super Critical Boilers – Fluidized Bed Boilers. Combined Power Cycles - Load Duration

Curves – Comparison and Selection.

Steam Power Plant Fuel and Ash Handling, Combustion Equipment for burning coal, Mechanical Stokers,

Pulveriser, Electrostatic Precipitator, Mechanical Collectors, Draught – different types,

Surface Condenser Types, Cooling Towers, Pollution controls

Nuclear and Hydel Power Plants Nuclear Energy – Fission, Fusion Reaction, Layout - Types of Reactors, pressurized water

reactor, Boiling Water Reactor, Waste Disposal and safety. Hydel Power Plant – Layout -

Essential Elements, pumped storage - Selection of Turbines, Governing of Turbines

Diesel and Gas Turbine Power Plants Layout and types of Diesel Plant, Components, Selection of Engine Type, applications. Gas

Turbine Power Plant – Layout - Fuels - Gas Turbine Material – Open and Closed Cycles –

Reheating – Regeneration and Intercooling

Other Power Plants and Economics of Power Plants

Geo thermal – OTEC – Tidal - Solar thermal –Wind energy - Wind turbines- MHD Plants.

Cost of Electric Energy – Fixed and operating Costs – Economics of load sharing,

Text/Reference Books

1. S. C. Arora and S. Domkundwar, A course in Power Plant Engineering, Dhanpatrai &

Sons, New Delhi, 2008.

2. M. M. EI-Wakil, Power Plant Technology, Tata McGraw Hill Publishing Company

Pvt Ltd., New Delhi,1985.

3. P. K. Nag, Power plant Engineering, Tata McGraw Hill Company Pvt Ltd., New

Delhi,2007.

4. G. R. Nagpal, Power Plant Engineering, Khanna Publishers, New Delhi,2002.

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Professional Elective - I & III (Odd Elective)

Professional Elective – I (Odd)

A Finite Element Analysis

B Design for Manufacturing

C Elements of Mechatronics

D

Product Design & Value

Engineering

A Finite Element Analysis

Course Outcome After completion of the course, student will be able to use FEA package for analysis and

simulation

Course Content Force and stress analysis using the link elements in trusses- 1D analysis

Stress analysis of flat plates – 2D analysis

Stress analysis of axi-symmetric components – Using symmetry to reduce the analysis time

for 3D analysis

Thermal Stress and heat transfer analysis of plate – Thermal Stress Coupled analysis

Vibration Analysis – Model analysis for Natural Frequency and Forced frequency

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B Design for Manufacturing

Course Outcome Student will be able to study the various factors influencing the manufacturability of

components.

Course Content Introduction

Need Identification and problem definition, Concept Generation and evaluation, embodiment

design, Ergonomics

Selection of Material and Shapes

Properties of engineering material, selection of material, selection of shapes, co-selection of

material and shapes, case studies

Selection of Manufacturing Process

Design for casting, design for bulk deformation processes, design for sheet metal forming

processes, design for machining, design for powder metallurgy, design for polymer

processing, co-selection of material and processes, case studies

Design for Assembly

Review of assembly processes, design for welding, design for brazing and soldering, design

for adhesive bonding, design for joining of polymers, design for heat treatment, case studies

Design for Reliability and Quality

Failure mode and effect analysis, design for quality, design for reliability, approach for

robust design, design for optimization

Text/Reference Books 1. M F Ashby and K Johnson, Materials and Design - the art and science of material

selection in product design, Butterworth-Heinemann, 2003.

2. G Dieter, Engineering Design - a materials and processing approach, McGraw Hill,

NY, 2000.

3. M F Ashby, Material Selection in Mechanical Design, Butterworth-Heinemann, 1999.

4. T H Courtney, Mechanical Behavior of Materials, McGraw Hill, NY, 2000.

5. K G Swift and J D Booker, Process selection: from design to manufacture, London:

Arnold, 1997.

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C Elements of Mechatronics

Course Outcome This is an industry applied course. The course will enable students to gain an insight into the

various components that define the field of Mechatronics. The course exposes the students to

the working, application and the selection process of various components. The course also

introduces students to various manufacturers in the related field. The included case studies

give students a better understanding and appreciation of this field of engineering.

At the end of this course the student will have the awareness and understanding of the

components used in creating a mechatroic system, and its relevance in modern day engineering.

Course Content Introduction to the field of mechatronics and the components used to build them.

Application examples.

Introduction to linear and rotary motion mechanisms (LM guides and rotary tables)

Study of contact and non-contact type bearings (mechanical, hydro, aero, magnetic)

Drive mechanisms like belt, chain, screw.

Drive power like motors, their types and their selection & sizing process

Introduction to controllers: PLC, PC, motor controllers for speed and direction.

Sensors & Transducers: limit, proximity, position, temperature, machine vision.

Sensor signal types: Analogue (voltage & current) Vs Digital

Introduction to data acquisition and analysis.

Introduction and demonstration of a software used for industrial DAQ.

Familiarity with prominent manufacturers of mechatronic components

Component specification sheet – what they are and how to use them.

Case studies

Text/Reference Books

1. Bolton, W., (2010), Mechatronics, 4th Edition, Addison Wesley

2. Bradley, D. A., Dawson, D., Burd, N. C. & Loader, A. J., (1993), Mechatronics,

Chapman and Hall Publications

3. Fraden, J., (2004), Handbook of Modern Sensors Physics, Designs and Applications,

3rd Edition, Springer Verlag

4. Class notes and presentations.

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D Product Design & Value Engineering

Course Outcome Confidence to create new product based on mechanical design engineering.

Students will have knowledge of all mechanical aspects of product design by

incorporating concept, creativity, structural, manufacturing, esthetic etc.

Students will have ability to solve open-ended problem belongs to design engineering

that meet the requirements.

Course Content Product Design

Introduction, Product life cycles, Characteristics of Successful Product development, Design

and development of Products, Types of Design and Redesigns, Engineering Designs,

Duration and cost of product development, the challenges of Product development.

Product Design for Manufacturing and Assembly

Methods for designing for manufacturing and assembly, design for Maintainability, Design

for Environment, Legal factors and social issues, Engineering Ethics and Issues of society

related to design of products, Design for safety, Vision and Illumination design: Climate,

Noise, Motion, Sound and Vibration, Product Costing.

Product Development Processes and Product Planning

A Generic development process, concept development, the front end process, adopting the

generic product development process, The Product Planning Process,

Product Analysis and Material Selection

Tools and charts used for product analysis like bill of materials, gozinto chart, performance

characteristics of materials, material selection process, sources of information on material

properties, economics of materials, evaluation methods for material selection

Value Engineering

Definition, Value Engineering Function: Approach of Function, Evaluation of Function,

Determining Function, Classifying Function, Evaluation of costs, Evaluation of Worth,

Determining Worth, Evaluation of Value, FAST Diagramming

Text/Reference Books Product Design, by Kevin Otto, Kristin wood, Pearson Education Inc.

Product design and development, by K.T. Ulrich and S.D. Eppinger, Tata McGraw

Hill

Product Development, by Chitale & Gupta, Tata McGraw Hill

Value Engineering A how to Manual S. S. Iyer, New age International Publishers

Value Engineering: A Systematic Approach by Arthur E. Mudge - Mc GrawHill

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Professional Elective - II & IV (Even Elective)

Professional Elective – I (Even)

A Advance Manufacturing Processes

B Industrial Robotics & Automation

C Vibration & Condition Monitoring

D IC Engine

A Advance Manufacturing Processes

Course Outcome At the end of the course, student will be able to understand the

1. Advanced techniques in casting

2. Fabrication of microelectronic devices

3. Manufacturing of composites

4. Rapid prototyping

Course Content Advances in casting & welding: Newer casting techniques - Expendable pattern casting -

Plaster mold and ceramic mold casting – Vacuum casting - Squeeze casting, Electron beam

Welding, laser Beam Welding, Ultrasonic Welding.

Fabrication of microelectronic devices: Semiconductors and silicon-Introduction, Structure

of silicon, Properties, Crystal growing and wafer preparation, Film deposition-Evaporation,

Sputtering, CVD, Oxidation-Dry oxidation, Wet oxidation, Lithography-Photolithography

Process, Etching-wet chemical etching, dry plasma etching, Cryogenic Dry Etching,

Diffusion, Drive-in Diffusion and ion implantation, Metallization and testing, Bonding and

packing

Manufacturing of composites: Introduction to Composite materials, Advantages,

Disadvantages, Applications, Fibre reinforced Composite materials-Design variations,

Classification, Fiber Alignment, Metal matrix-Fiber, Matrix, Properties, Applications,

Ceramics matrix composites- Fiber, Matrix, Properties, Applications, Nano composites

Structure, Properties, Manufacturing processes of composite materials

Rapid prototyping: Rapid prototyping- overview, Techniques-Stereo lithography,

Laminated object manufacturing, Selective laser sintering, fused deposition modeling, solid

ground curing, 3D ink jet printing-Applications of rapid prototyping-Rapid tooling-Rapid

manufacturing-Future development-Virtual prototyping.

Text/Reference Books 1. Mikell Groover “Modern Manufacturing Techniques”, 4th Edition

2. Madou.M.J, “Fundamentals of micro fabrication”, CRC Press, USA, 1997

L T P C

3 0 0 3

B Industrial Robotics & Automation

Course Outcome This is an industry applied course. The course focus is on the design, configuration and

working of an automation system. On the successful completion of the course, students will

be able to comprehend and understand PLC’s SCADA, HMI’s and robots. They will

appreciate the role of each element in a factory automation environment. The student will

develop an understanding about the types of robots, their configuration, design, and the

mathematical models for control.

Course Content Introduction to factory automation

Case studies showing factory automation with robots in use

Components of factory automation and their integration

Study of PLC’s and prominent manufacturers

How PLC’s are programmed & various industry standards and protocols

What is SCADA and HMI and their role in industry automation

Introduction to robots, their types & configuration.

Mathematical models for robot control

Robot manipulators and sensors

Case studies of industry applications

Introduction to Industry 4.0 “Smart Factory”, “Lights-out” production, and other current

industry trends.

Text/Reference Books 1. M. P. Groover, Industrial Robotics – Technology, Programming and Applications,

Tata McGraw Hill Publishing Company Pvt Ltd., New Delhi, 2001.

2. D. Richard, Klafter, A. Thomas, Chmielewski and Michael Negin, Robotics

Engineering – An Integrated Approach, Prentice Hall of India , New Delhi, 2001.

3. Class notes and presentations

L T P C

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C Mechanical Vibration & Noise Engineering

Course Outcome To be learned fundamental information about vibration phenomenon, to be gained skills of

modelling of vibration problems encountered in application and examining vibration response,

establishing relation between real system and physical model, and to be formed mathematical

model from physical model, methods used to examine of vibrations and its usage fields.

Experience in solution of mathematical model and to be interpreted of its results. To be having

general information about definition and finding remedy of the vibration problems encountered

in machineries.

Course Content Fundamental Aspects of Vibrations: Vibration, main causes, advantages and disadvantages;

engineering applications of vibration and noise; vector method of representing harmonic

motion; characteristics of vibration, harmonic analysis and beats phenomenon, work done by

harmonic forces on harmonic motion; periodic, non-harmonic functions- Fourier series

analysis; evaluation of coefficients of Fourier series; elements of vibratory system; lumped and

distributed parameter systems.

Undamped Free Vibrations: Derivation of differential equation of motion: the energy

method, the method based on Newtons second law of motion, and Rayleigh’s method. Solution

of differential equation of motion: Natural frequency of vibration. Systems involving angular

oscillations: the compound pendulum.

Damped Free Vibrations: Viscous damping: coefficient of damping; damping ratio; under

damped, over damped and critically damped systems; logarithmic decrement; frequency of

damped free vibration; Coulomb or dry friction damping; frequency, decay rate and

comparison of viscous and Coulomb damping; solid and structural damping; slip or interfacial

damping.

Harmonically excited Vibration: One degree of freedom- forced harmonic vibration; vector

representation of forces; excitation due to rotating and reciprocating unbalance; vibration

Isolation, force and motion transmissibility; absolute and relative motion of mass (Seismic

Instruments). Whirling Motion and Critical Speed: Whirling motion and Critical speed:

Definitions and significance. Critical -speed of a vertical , light flexible shaft with single rotor :

with and without damping .Critical speed of a shaft carrying multiple discs (without damping ),

Secondary critical speed.

Systems with Two Degrees of Freedom: Un-damped free vibration of 2 d.o.f and Principal

modes of vibration; torsion vibrations; Forced, Un-damped vibrations with harmonic

excitation; Coordinate coupling; Dynamic vibration absorber; torsion Vibration Absorber;

Pendulum type of dynamic vibration.

Noise Engineering -Subjective response of sound: Frequency and sound dependent human

response; the decibel scale; relationship between, sound pressure level (SPL), sound power

level and sound intensity scale; relationship between addition, subtraction and averaging,

sound spectra and Octave band analysis; loudness; weighting networks; equivalent sound level,

auditory effects of noise; hazardous noise, exposure due to machines and equipment’s; hearing

conservation and damage risk criteria, daily noise doze.

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Noise: Sources, Isolation and Control: Major sources of noise on road and in industries,

noise due to construction equipments and domestic appliances, industrial noise control,

strategies- noise control at source (with or without sound enclosures), noise control along the

path (with or without partitions and acoustic barriers ); noise control at the receiver, ear

defenders, earplugs, semi-insert protect

Reference 1- Ambekar A.G.,’ Mechanical Vibrations and Noise Engineering; PHI

2- Meirovitch Leonard; Element of Vibration Analysis; TMH

3- Dukikipati RV Srinivas J Text book of Mechanical Vibrations; PHI

4- Kelly SG and kudari SK; Mechanical Vibrations; Schaum Series;TMH

5- Thomson , W.T., Theory of Vibration with Applications , C.B.S Pub & distributor

Grading System 2013 - 14

6- Singiresu Rao, “Mechanical Vibrations , Pearson Education .

7- G.K. Grover, “ Mechanical Vibration , Nem chand and Bross , Roorkee.

D IC Engine

Course Outcome Students who have done this course will have a good idea of the basics of IC engines and

how different parameters influence the operational characteristics of IC Engines

Course Content Review of ideal cycles; Details of fuel-air cycles. Combustion in SI and CI engines,

Combustion stages, Combustion chambers and Abnormal combustion. Fuel supply systems

in SI and CI engines, carburettors, Port fuel injection, Direct injection and Common rail

injection. Ignition system, Lubrication system and Cooling system. Turbocharging and

Supercharging, Testing of IC engines. Engine emissions and control. Advanced IC Engine

concepts.

Text/Reference Books Obert E. F, "Internal Combustion Engines and Air Pollution", Harper and Row

Publication Inc. NY, 1973.

Heisler H, "Advanced Engine Technology", Edward Arnold, 1995.3. Heywood J. B,

"Internal Combustion Engine Fundamentals", McGraw Hill Book Co. NY, 1989

L T P C

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Open Elective

Open Electives

01 Process Safety (Chemical Engineering)

02 Corrosion Science (Chemical Engineering)

03 Nanotechnology (Mechanical Engineering)

04 Renewable Energy (Mechanical Engineering)

05 Sustainable Building Technology (Civil

Engineering)

06 Heat Ventilation & Air Condition System of

Building (Civil Engineering)

07 Soft Skills and Interpersonal Communication

(Humanities & Social Science)

08 Professional Ethics (Humanities & Social

Science)

09 Introduction to Account & Finance for Engineers

(Management)

10 Project Management

11 Total Quality Management

01 Process Safety

Course Outcome On completion of this course, students will know the relevance of safety in design of process

plant.

Course Content Hazards: Introduction, typical hazards, hazardous materials, sources of ignition, Explosions,

Safety considerations in developing the initial design, Reactions, Critical examination and

value analysis, Process choice.

Safety and equipment & piping design: Operating limits, Mechanical design restrictions,

design considerations, standards and codes, Documentation, General environmental hazards to

personnel.

Plant availability and process reliability: Plant availability, Ways of improving availability,

simple reliability criteria, Decision trees, Plant availability assessment, Monte Carlo

simulation, Reliability of systems tested at intervals, Intermediate tanks-availability formulae

Major deviations of plant: Normal start up/shutdown of plant, emergency

shutdown/maintenance & inspection, Construction and Pre-commissioning.

Operating deviations and operability studies: Introduction, examples of deviations

(pressure, flow, temperature, level, and general deviations), Common cause failures,

Operability studies and checklist/guidelines.

Organizational aspects of safety studies: Responsibilities, Feasibility study, Design & safety

reviews (line diagram/area classification/ relief & blow down review/layout/Hazard &

operability study), Hazard survey, General Information (documentation & safety audits).

Formal safety studies: Introduction, Accidents involving fatalities (criteria of acceptability,

casualties, public risk), Preliminary hazard analysis, failure mode and effect analysis, hazard

analysis (cause-consequence analysis).

Hazard level limitation and control: Process relief (relief valves, discharge of relief systems,

design considerations), safety relief system, control (Monitoring requirements, operability and

reliability) condition monitoring.

Safety studies : Process engineering exercise on a process flow diagram( solid handling,

reaction section, distillation section) ,safety exercise on an engineering line diagram( furnace

& over temperature problem), dispersion of a gas vented to atmosphere from relief valves. Seal

failure on a pump, radiation from a pool fire in a storage tank.

Damage minimization and control layout: site & plant layout, safe distances between plant

items, escape of liquid, escape of vapour, vapour cloud studies, hazardous zone, explosions-

safe area/distances.

Damage minimization and control – containment, fire-protection and other measures:

Containment, Air contamination control, loading and discharge of dangerous substances,

BLEVEs, Emergency depressurizing, Fire protection introduction.

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Text/Reference Books 1. Safety in Process Plant Design by G.L. Wells, John Wiley & Sons, New York &

Toronto.

2. Guidelines for Engineering for Process Design Safety , Center for Chemical Process

Safety , 1993 American Institute of Chemical Engineers.

02 Corrosion Science

Course Outcome On completion of this course, students will know the relevance of corrosion in process

industries.

Course Content Forms of Corrosion, Designing for Corrosion Resistance, Intergranular Corrosion in Iron &

Nickel base Alloys, Corrosion in Iron, Carbon Steel and Low Alloy steels in process industries,

Stress corrosion cracking of Metals, Effect of Hydrogen on Metals, Use of Titanium,

Zirconium, Tantalum in Chemical Environments, Use of Copper, Aluminium Alloys in

chemical environments.

Calculation of Economic appraisals of corrosion control measures, Electrodeposited metal

coatings, coatings & linings for Immersion Service, electrochemical techniques of corrosion

control, corrosion testing , evaluation and Monitoring, paints, elastormeric linings and

corrosion control and Acid Brickwork systems

Corrosive materials in transportation , Corrosion & material handling of hydrochloric acid,

phosphoric acid, hydrofluoric acid , sulfuric and nitric acid. Corrosion & material handling of

Alkalies, Organic acids Hypochlorites and halogens. Cooling water treatment

Failure of metals, Evaluation and failure analysis of coatings, fracture analysis diagram

procedures for fracture Safe engineering design of Steel structures, case studies of major

industrial hazards due to corrosion/metal failure.

Text/Reference Books 1. Process industries corrosion, NACE publication, (1975).

2. Denny A Jones, Principles and Prevention of Corrosion (second edition), Prentice-

Hall, N. J., (1996).

3. M. G. Fontana, Corrosion Engineering (Third Edition) McGraw-Hill Book Company

(NY), (1987).

4. H. H. Uhlig and R. W. Revie, Corrosion and Corrosion Control, Wiley (NY), (1985). 5. L. L. Shreir, Corrosion. Vol I and II, Butterworths, Kent, (1976).

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03 Nanotechnology

Course Outcome At the end of the course

Students are familiar with nanomaterials and their application.

Able to learn different types of techniques used to develop nanomaterials.

Able to understand the various application of nanomaterials in day-to-day life.

Course Content Introduction classification of nanostructures, nanoscale architecture – effects of the nanometer length scale

– changes to the system total energy, changes to the system structures– effect of nanoscale

dimensions on various properties – structural, thermal, chemical, mechanical, magnetic,

optical and electronic properties.

Nanomaterials Synthesis Methods

Fabrication methods – top down processes – milling, litho graphics, machining process –

bottom-up process – vapor phase deposition methods, plasma-assisted deposition process,

colloidal and solgel methods – methods for templating the growth of nanomaterials –

ordering of nanosystems, self-assembly and self-organization.

Nano Characterization Techniques

General classification of characterization methods – analytical and imaging techniques –

microscopy techniques - electron microscopy, scanning electron microscopy, transmission

electron microscopy, atomic force microscopy – diffraction techniques – spectroscopy

techniques-X-ray spectroscopy.

Nanodevices And Applications

Organic photovoltaic cells- carbon nano tubes- structure, synthesis and electronic properties

-applications- fuel cells- nano motors -bio nano particles-nano – objects.

Text/Reference Books

1. Robert W. Kelsall, Ian W. Hamley, Mark Geoghegan, Nanoscale Science and

Technology, John Wiley and Sons Ltd, 2005.

2. T. Pradeep, NANO: The Essentials Understanding Nanoscience and Nanotechnology,

McGraw – Hill Education (India) Ltd, 2007.

3. Michael Kohler, Wolfgang Fritzsche, Nanotechnology: An Introduction to

Nanostructuring Techniques, Wiley-VCH Verlag GmbH & Co.2004.

4. William Goddard, Donald .W.Brenner, Handbook of Nano Science Engineering and

Technology, CRC Press, 2004.

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04 Renewable Energy

Course Outcome

After completion of the course, students will be Able to understand how renewable energy can be used to help reducing greenhouse

gases.

Able to understand the principles of solar energy and wind energy.

Able to understand the challenges and problems associated with the use of various

energy sources, including fossil fuels, with regard to future supply and the

environment

Course Content Solar Energy The sun as a perennial source of energy; flow of energy in the universe and the cycle of

matter in the human ecosystem; direct solar energy utilization - solar thermal applications –

water heating systems, space heating and cooling of buildings, solar cooking, solar ponds,

solar green houses, solar thermal electric systems;

Ocean Energy and Geothermal EnergyWave energy – Energy from waves; energy potential,

Conversion devices; Tidal Energy – Basic principle, energy potential, Conversion systems,

Ocean thermal energy conversion – Methodology, Applications. Geothermal energy -

classification of geothermal resources; schematic of geothermal power plants, operational and

environmental problems

Wind Energy

Basic principles of wind energy conversion – classification of wind turbines - Types of

rotors ; Design of windmills – wind turbine rotor, regulating system for rotor, wind power

generation curves - wind data and energy estimation; site selection considerations – Merits

and demerits of wind energy systems

Bio-Energy Bio mass resources – Conversion technologies – Biochemical conversion – Biomass

gasification; Biogas – production, Factors affecting bio gas production – Biogas plants;

Energy recovery from Urban waste, power generation from liquid waste – Biomass

cogeneration - Bio-fuels

Emerging Technologies

Fuel cell – types –– Comparison of Electrolysis and the Fuel cell process; Hydrogen energy

– hydrogen production - hydrogen storage – types, using nano-crystalline magnesium based

nickel hydride; alcohol energy; nuclear fusion; cold fusion; application Merits and demerits

Text/Reference Books

D. P. Kothari, K. C. Singal and Rakesh Ranjan, Renewable Energy Sources and

Emerging Technologies, Prentice Hall of India , New Delhi, 2009.

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05 Sustainable Building Technology

Course Outcome Upon completion of this course, the candidate will be able to:

1. Identify the key components of the LEED® Rating System

2. Describe key green building concepts.

3. Know design principles and techniques for sustainable buildings.

4. Use Sustainable Building Materials and assess their impact.

5. Know various water management systems

Course Content Concept of Green Building: Sustainable Development concept, Buildings and climate, important considerations for the

design of a sustainable buildings. Green Building Assessment, Current version of the LEED

rating system.

Energy and Buildings: The design of a sustainable building, Lighting - day lighting; Ventilation - natural ventilation;

Indoor air quality; Passive and Active systems for energy production and conservation,

Elements of successful design of a building envelope.

Sustainable Building Materials: Environmental issues related to building materials, Local Building Materials from a)

Agricultural waste: Rice husk, Coconut wastage, Banana leaves. b) Industrial waste: Red mud,

Blast furnaces slag, Fly Ash. Their Physical Characteristics and effects on properties of

concrete.

Cost Effective Techniques for Sustainable Building: Stabilized Mud blocks, Stone masonry blocks, solid and Hollow concrete blocks, Selection of

building blocks. Ferro- Concrete, Properties and Uses, Practical aspects.

Alternative sustainable Roofing Systems: Concepts in Roofing alternatives, Filler slab roofs, Composite Slab panel roofs, hollow block

roofs, Masonry Domes.

Environmental Techniques: Waste water Management, Rain water harvesting and conservation, recycling, waste water

treatment processes, external drainage system in building. Lightening in building, Fire

protection of building, Thermal environment inside the building, systems of air conditioning

Noise pollution: Sources and control measures Noise pollution-sources and control measures

Text/Reference Books 1. K.S.Jagadish, B.V.V.Reddy ,“Alternative Building Materials and Technologies”, New

Age International Publishers

2. “Sustainable building design Manual” by Energy research institute Delhi.

3. Gevorkian, ”Green Buildings” Mc Graw hill.

4. “Fiber reinforced Cement Composites”, P. N. Balaguru and S.P. Shah, McGraw Hill,

5. The engineering guide to LEED- new construction-sustainable construction for

engineers’ haselbach.

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06 Heat, Ventilation & Air Condition System of

Building

Course Outcome 1. Understand the basic concepts of refrigeration and air conditioning systems in a

building.

2. Understand the basic concepts of refrigeration and air conditioning systems

3. Apply scientific and engineering principles to analyze and design aspects of

engineering systems that relate to refrigeration and air conditioning of a building.

Course Content Introduction to HVAC:

Scope, Concepts of air conditioning system, Central air conditioning system, Components of

AHU and its components,

Refrigerant: Types, Evaporating and condensing

Load Estimation: Basics of heat transfer in building, Understanding of outdoor & indoor

conditions, Sources of heat gain, Heat loss calculations

Components of air distributing system

Ventilation system: Introduction, Restaurant and kitchen ventilation system design

Chilled water system design:

Introduction, Classification, Chiller arrangements, cooling tower arrangements, types of

cooling tower & expansion tank connections, Pumps required in chilled water system, Chilled

water system pipe designing

Erection of equipment:

Installation of Chillers, Installation of Air handling units, Installation of Package units,

Installation of Fan coil units, Installation of condensing units

Estimation of systems Understanding the tendering requirements, Quantity take off, Preparing inquiry for suppliers

& finalizing the suppliers, Final billing & quotations finalization

Drafting of HVAC systems: Introduction, preparation of floor drawings

Project work: Load calculation, Duct designing

Text/Reference Books ASHRAE Handbook

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07 Soft Skill & Interpersonal Communication

Course Outcome 1. Understands and developed soft and interpersonal skills.

2. Understands and developed professional communication skills.

Course Content Self-analysis & Creativity: Strength, Weakness, Opportunity and Threats (SWOT) analysis, Creative thinking.

Attitude & Etiquettes:

Factors influencing Attitude, Challenges and lessons, Telephonic skills, Social & Dining

Etiquettes, Netiquettes, Cross cultural differences, Presentation Skills & strategies.

Goals & Motivation:

Types of motivation & Factors related to motivation, Goal setting, persistence & effort. Time-

bound (SMART) goal accomplishment, Time Management, Significance & Problem-solving,

Planning and prioritizing work.

Leader Ship & Team Work:

Understanding the relationship between Leadership Networking & Team work. Assessing

Interpersonal Skills & Behavioral Management, Necessity of Team Work Personally, Socially

and Educationally, Skills for a good Leader, Assessment of Leadership Skills.

Art of Small talks: Instructing, Negating, Persuading, Agreeing & disagreeing.

Speeches:

Extempore, Public speaking, Situational speeches & Role Plays.

Stress Management:

Causes of Stress and its impact, Stress Mitigation, Circle of control, Introduction and

importance of Emotional Intelligence, Emotion Scales, and Managing Emotions.

Decision Making & conflict resolution:

Importance and necessity of Decision Making, Process and practical ways of Decision Making,

Weighing Positives & Negatives. Conflicts in Human Relations – Reasons Case Studies,

Approaches to conflict resolution.

Interview Skills (campus recruitment): Why an Interview? Interview Questions, Types of

Interview, How to answer the Questions, Reasons for selecting & rejecting a candidate, how

to present well in the Interview?

Group Discussion: Why Group discussion? Skills required in Group discussion, Areas to be

concentrated while preparing for Group discussion, Techniques to initiate a Group discussion.

Difference between Group Discussion & Debate

Text/Reference Books

1. Effective Technical Communication by M Ashraf Rizvi, The McGraw-Hill

companies.

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2. Daniel Coleman, Emotional Intelligence, Bantam Book, 2006.

3. Soft skills, 2015, Career Development Centre, Green Pearl Publications.

4. Carnegie Dale, How to win Friends and Influence People, New York: Simon &

Schuster, 1998.

5. Covey Sean, Seven Habit of Highly Effective Teens, New York, Fireside Publishers,

1998.

6. Thomas A Harris, I am ok, you are ok, New York-Harper and Row, 1972.

7. The Functional Aspects of Communication Skills- Prasad, P., Delhi.

8. Business Correspondence and Report Writing- R C Sharma Krishna Mohan - 2002

9. An introduction to Professional English and Soft Skills by B. K. Das et al.,

Cambridge University Press (Facilitated by BPUT)

10. Cambridge English Pronouncing Dictionary, Cambridge University Press, India, 2012

08 Professional Ethics

Course Outcome Understands the ethics in engineering and infuse them with confidence to apply the same in

their professional life. Course Content MORALS AND ETHICS IN ENGINEERING

Senses of ‘Engineering Ethics’ – Variety of moral issues – Types of inquiry – Moral dilemmas

– Moral Autonomy – Kohlberg’s theory – Gilligan’s theory –Indian Theory-Consensus and

Controversy – Professions and Professionalism – Professional Ideals and Virtues – Uses of

Ethical Theories

ENGINEERING AS SOCIAL EXPERIMENTATION

Engineering as Experimentation – Engineers as responsible Experimenters – Research Ethics

- Codes of Ethics – Industrial Standards - A Balanced Outlook on Law – The Challenger Case

Study – Titanic disaster as Case Study

ENGINEER’S RESPONSIBILITY FOR SAFETY

Safety and Risk – Assessment of Safety and Risk – Risk Benefit Analysis – Reducing Risk –

The Government Regulator’s Approach to Risk – Disasters at Chernobyl and Bhopal - Case

Studies

RESPONSIBILITIES, RIGHTS AND ACCOUNTABILITY

Collegiality and Loyalty – Respect for Authority – Collective Bargaining – Confidentiality –

Conflicts of Interest – Occupational Crime – Professional Rights – Employee Rights –

Intellectual Property Rights (IPR) – Discrimination

GLOBAL ISSUES

Multinational Corporations – Business Ethics - Environmental Ethics – Computer Ethics - Role

in Technological Development – Weapons Development – Engineers as Managers –

Consulting Engineers – Engineers as Expert Witnesses and Advisors – Honesty – Moral

Leadership – Sample Code of Conduct

Text/Reference Books

1. Mike Martin and Roland Schinzinger, “Ethics in Engineering”, McGraw Hill, New

York, 2005.

2. Charles E Harris, Michael S Pritchard and Michael J Rabins, “Engineering Ethics

oncepts and Cases”, Thompson Learning, 2000.

3. Charles D Fleddermann, “Engineering Ethics”, Prentice Hall, New Mexico, 1999.

4. John R Boatright, “Ethics and the Conduct of Business”, Pearson Education, 2003.

5. Edmund G Seebauer and Robert L Barry, “Fundamentals of Ethics for Scientists and

Engineers”, Oxford University Press, 2001.

6. Prof. (Col) P S Bajaj and Dr. Raj Agrawal, “Business Ethics – An Indian Perspective”,

Biztantra, New Delhi, 2004.

7. David Ermann and Michele S Shauf, “Computers, Ethics and Society”, Oxford

University Press, 2003.

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09 Introduction to Account & Finance for

Engineers

Course Outcome Student understands the basic accounting and finance terms and methods.

Course Content Fundamentals of Accountancy:

Meaning, Scope and Utility of Accounts, Methods of keeping Books of Accounts, Difference

between Book Keeping and Accountancy, Users of Accounts, Fundamental Accounting Equation,

Types of Accounts, Rules of Debit and Credit, Types of Transactions.

Capital & Revenue Accounts:

Capital, Revenue, Deferred Revenue Expenses, Reserves, Provisions And Contingent Liability

Meaning and difference between Capital and Revenue Incomes and Expenses, Identification of

Capital and Revenue Expenses and Incomes, Meaning of Deferred Revenue Expense, Difference

between Reserves and Provisions, meaning of Contingent Liability

Accounting Principles: Accounting Concepts, Conventions & Principles Generally Accepted Accounting Principles, and

Identification of different Accounting concept applied in various transactions, its accounting entries

and its presentation in Annual Financial Statement

Accounting for Non-Trading Concerns:

Meaning of Non-Trading Concern, Annual Financial Statements of Non Trading Concerns (NTC),

and How NTC differs from Trading Concern, Identification of Capital and Revenue Items for non-

trading organizations, Receipts and Payments Account, Income and Expenditure Account, Balance

Sheet, Concept of different funds and their accounting treatment. (Practical Examples of Clubs &

Hospitals)

Accounting for Sole Proprietors: Final Accounts of Sole Proprietary Concern, Preparation of Final account of sole Trading.

Accounting Entries in Tally 7.2 Using Vouchers, Relevant vouchers in printed/physical form to be

provided to students as documentary evidence and accounting entries in Tally 7.2 (accounts only) to

be passed and it will be evaluated on the basis of Day Book, Trial Balance, Profit and Loss Account

and Balance Sheet. Opening balances of certain Ledger Accounts may also be given in case of

continuing firm.

Text/Reference Books 1. Accounting for Managers – J. Made Gowda – Himalaya Publishing House

2. Introduction to Accountancy – T. S. Grewal & S. C. Gupta – S. Chand – 8th Edition

3. Modern Accountancy - Hanif Mukerji – TMH

4. Financial Accounting by Dr. Kaustubh Sontake – 1st Edition – Himalaya Publishing

House

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10 Project Management

Course Outcome After completion of the course, student will be able to understand

1. Project types and the need for project portfolio management

2. Need for aligning the projects to the company’s strategy

Course Content Modern Project Management Definition; project life cycle; challenges; benefits; integrated approach; portfolio

management; technical & sociocultural dimensionsOrganization Strategy and Project

Selection: Projects and Strategy; strategic management process; Project Portfolio

Management Problems; A Portfolio Management System; project selection criteria; Project

Proposals

Organization

Structure and Culture: Project management Structures; Choosing appropriate project

management structures; Organisational culture; Implications of Organisational culture for

organising projectsDefining the Project: Steps; WBS &OBS; Responsibility matrices;

Communication Plan

Estimating Project Times and Costs

Factors influencing estimation; Guidelines for estimating, Time; Cost & Resources; Macro

v/s Micro Estimation; Methods for estimating Time & Cost; Developing budgets; Refining

estimates; Creating database for estimationDeveloping a Project Plan: Developing the

Project Network; From Work package to Network; Constructing a Project Network; Activity

–on-Node Fundamentals; Network Computation Process; Using the Forward & Backward

Pass Information; Practical Considerations

Managing Risk

Risk Management Process; Steps of risk managementScheduling Resources and Costs: The

scheduling Problem; Types of Project Constraints; Classification of a Scheduling Problem;

Resource Allocation Methods; Splitting / Multitasking; Benefits of Scheduling Resources;

Assigning Project Work; Multiproject Resource SchedulesReducing Project Duration:

Rationale; Options for accelerating; Project Completion; Cost Duration Graph; Constructing

a Project Cost-Duration Graph; Practical Considerations

Progress and Performance Measurement and Evaluation

Structure of a Project Monitoring Information System; The Project Control Process;

Monitoring Time Performance; Integrated Information System; Developing a Status Report;

Indexes to Monitoring Process; Forecasting Final Project Cost; Other Control IssuesProject

Audit and Closure: Project Audits; The Project Audit Process; Project Audits: The Bigger

Picture; Project Closure; Team, Team Member, and PM Evaluations

References

1. Jack Meredith, Samuel J. Mantel Jr. “Project Management- A Managerial Approach”,

John Wiley and Sons

2. John M Nicholas “Project Management For Business And Technology” Prentice Hall

of India Pvt Ltd

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11 Total Quality Management

Course Outcome 1. Understand the philosophy and core value to TQM and to determine the voice of

customers and its impact on quality.

2. Apply and evaluate best practices for attainment of total quality.

3. Understand the methodologies to enhance the management process such as bench

marking, business process reengineering.

4. Choose the framework to evaluate the performance excellence of organization, human

resource and to determine the set of performance indicators.

5. Identify the areas for quality improvement through QFD and FMEA.

Course Content Overview of TQM: Introduction-Definition, Basic Approach, Contribution of Gurus – TQM

framework, Historical Review, Benefits of TQM, TQM organization.

Tools and Techniques in TQM: 7 basic tools of quality control, Kaizen, Re-engineering, 6

sigma, Benchmarking, Definition, Process of benchmarking, 5S, Poke yoke, 3M, Pareto

diagram, Process flow diagram.

Building and Sustaining Total Quality Organizations: Making the commitment to TQ,

Organizational culture and Total Quality, Change management, sustaining the quality

organization, quality assurance, concepts and objectives of quality assurance. Quality

Management Systems: Quality management systems through ISO standards.

Quality Function Deployment and Failure Modes Effects Analysis: Introduction to QFD and

QFD process, Quality by design, Rationale for implementation of quality by design, FMEA,

Design FMEA and process FMEA

Text/Reference Books Total Quality Management: G. Nagalingappa, Manjunath.V.S, Publisher- Excel books, First

edition, New Delhi,2010.

Total Quality Management: Dale H. Besterfiel

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