PROGRAMME: B.TECH CHEMICAL ENGINEERING CURRICULUM · B.E. / B.Tech REGULAR xxvi REGULATIONS 2015 PROGRAMME: B.TECH CHEMICAL ENGINEERING CURRICULUM SEMESTER 1 Sl. No. SUB.CODE COURSE

SATHYABAMA UNIVERSITY FACULTY OF BIO AND CHEMICAL ENGINEERING

B.E. / B.Tech REGULAR xxvi REGULATIONS 2015

PROGRAMME: B.TECH CHEMICAL ENGINEERING

CURRICULUM SEMESTER 1

Sl. No. SUB.CODE COURSE L T P C Pg.No.

1. SCH1101 Environmental Science and Engineering 3 0 0 3 16-17

2. SMT1101 Engineering Mathematics –I 3 1 0 4 2

3. SPH 1101 Physics of Engineering Materials 3 0 0 3 9-10

4. SCY1101 Engineering Chemistry 3 0 0 3 12

5. SEE1103 Basic Electrical and Electronics Engineering 3 0 0 3 27

6. SCS1102 Fundamentals of Programming 3 0 0 3 18

PRACTICAL

7. SPH 4051 Engineering Physics Lab 0 0 2 1 126

8. SCY4051 Engineering Chemistry Lab 0 0 2 1 126

9. SCS4101 Programming in C Lab 0 0 4 2 126

TOTAL CREDITS: 23

SEMESTER 2


1. SHS1101 English for Science and Technology 3 0 0 3 1

2. SMT1105 Engineering Mathematics – II 3 1 0 4 4

3. SPH 1103 Engineering Physics 3 0 0 3 11

4. SCY1105 Physical Chemistry 3 0 0 3 15

5. SCS1202 Object Oriented Programming 3 0 0 3 19

6. SCH1102 Material Science and Engineering 3 0 0 3 95

PRACTICAL

7. SME 4053 Engineering Graphics 0 0 6 2 128

8. SCS4201 Object Oriented Programming Lab 0 0 4 2 127

TOTAL CREDITS: 23

L - LECTURE HOURS, T – TUTORIAL HOURS, P – PRACTICAL HOURS, C – CREDITS

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B.E. / B.Tech REGULAR xxvii REGULATIONS 2015

SEMESTER 3

Sl. No. SUB.CODE COURSE L T P C Pg.No. 1. SMT1201 Engineering Mathematics – III 3 1 0 4 6 2. SCH1201 Mechanical Operations 3 0 0 3 97 3. SCH1202 Chemical Engineering Thermodynamics-I 3 0 0 3 98 4. SCH1203 Fluid Mechanics 3 0 0 3 99 5. SCH1204 Chemical Process Calculations 3 1 0 4 100 6. SCH1205 Energy Engineering 3 0 0 3 101

PRACTICAL 7. SCH4051 Technical Analysis & Instrumentation Lab 0 0 4 2 143 8. SCH4052 Organic Chemical Processes & Thermodynamics Lab 0 0 4 2 143

TOTAL CREDITS: 24 SEMESTER 4

Sl. No. SUB.CODE COURSE L T P C Pg.No. 1. SMT1204 Engineering Mathematics – IV 3 1 0 4 8 2. SCH1206 Mass Transfer -I 3 1 0 4 102 3. SCH1207 Chemical Engineering Thermodynamics-II 3 1 0 4 103 4. SCH1208 Chemical Reaction Engineering - I 3 1 0 4 104 5. SCH1209 Bio Chemical Engineering 3 0 0 3 105 6. SCH1210 Heat Transfer 3 0 0 3 106

PRACTICAL 7. SCH4053 Fluid Mechanics Lab 0 0 4 2 144 8. SCH4054 Mechanical Operations Lab 0 0 4 2 144 9. S19PT1 Professional Training-I 0 0 10 5


Sl. No. SUB.CODE COURSE L T P C Pg.No. 1. SCH1301 Computational Methods in Chemical Engineering 3 1 0 4 110 2. SCH1302 Mass Transfer -II 3 0 0 3 111 3. SCH1303 Chemical Reaction Engineering - II 3 1 0 4 112 4. SCH1304 Chemical Process Technology 3 0 0 3 113 5. SCH1305 Instrumentation and Process Control 3 0 0 3 114 6. SCH1306 Process Engineering 3 0 0 3 115

PRACTICAL 7. SCH4055 Process Dynamics and Control Lab 0 0 4 2 144 8. SCH4056 Heat Transfer Lab 0 0 4 2 145

TOTAL CREDITS: 24

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B.E. / B.Tech REGULAR xxviii REGULATIONS 2015

SEMESTER 6


1. SCH1307 Process Equipment Design 3 1 0 4 116

2. SCH1308 Petroleum and Petro Chemical Technology 3 0 0 3 117

3. SCH1309 Transport Phenomena 3 1 0 4 118

4. SCH1310 Environmental Pollution and Control 3 0 0 3 119

5. SCH1311 Industrial Safety and Hazard Analysis 3 0 0 3 120

6. Elective – I 3 0 0 3

PRACTICAL

7. SCH4057 Mass Transfer Lab 0 0 4 2 145

8. SCH4058 Chemical Reaction Engineering Lab 0 0 4 2 145

9. S19PT2 Professional Training-II 0 0 10 5



1. SCH1401 Process Modelling and Simulation 3 0 0 3 123

2. SCH1402 Optimization of Chemical Processes 3 1 0 4 124

3. Elective – III 3 0 0 3

4. Elective – IV 3 0 0 3

PRACTICAL

5. SCH4059 Matlab 0 0 4 2 146

6. SCH4060 Process Simulation Lab 0 0 4 2 146

7. Project Work-Phase-1



1. SCH1403 Process Engineering Economics 3 0 0 3 125

2. SBA1101 Principles of Management and Professional Ethics 3 0 0 3 20

3. Elective – IV 3 0 0 3

PRACTICAL

4. S19PROJ Project Work-Phase - I & II 0 0 30 15

TOTAL CREDITS: 24

TOTAL CREDITS FOR THE PROGRAMME: 195

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B.E. / B.Tech REGULAR xxix REGULATIONS 2015

LIST OF ELECTIVES DEPARTMENT ELECTIVES

S. No. SUB.CODE COURSE L T P C PAGE No.

GROUP-1

1. SCH1601 Computer Applications in Chemical Engineering 3 0 0 3 188

2. SCH1602 Computational Fluid Dynamics 3 0 0 3 189

3. SCH1603 Instrumental Methods of Analysis 3 0 0 3 190

4. SCH1604 Fertilizer Technology 3 0 0 3 191

5. SCH1605 Novel Separation Processes 3 0 0 3 192

6. SCH1606 Industrial Catalysis 3 0 0 3 193

7. SCH1607 Fluidization Engineering 3 0 0 3 194

8. SCH1608 Multicomponent Separation System 3 0 0 3 195

GROUP-2

9. SCH1609 Food Technology 3 0 0 3 196

10. SCH1610 Polymer Technology 3 0 0 3 197

11. SCH1611 Oils and Fats Technology 3 0 0 3 198

12. SCH1612 Drugs and Pharmaceutical Technology 3 0 0 3 199

13. SCH1613 Nanoscience and Technology 3 0 0 3 200

14. SCH1614 Corrosion Engineering 3 0 0 3 201

15. SCH1615 Electrochemical Engineering 3 0 0 3 202

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B.E. / B.Tech REGULAR xxx REGULATIONS 2015

UNIVERSITY ELECTIVES

1. SHS 1601 Life and Employability Skills 3 0 0 3 204

2. SHS 1602 Technical Writing for Scientists 3 0 0 3 205

3. SHS 1603 Professional Communication & Advanced Rhetoric 3 0 0 3 206

4. SCI 1619 Disaster Management 3 0 0 3 207

5. SBI 1101 Introduction to Bioinformatics 3 0 0 3 33

6. SBI 1207 PERL Programming 3 0 0 3 40

7. SBI 1605 Python 3 0 0 3 164

8. SBM 1304 Biomaterials 3 0 0 3 65

9. SBM 1404 Hospital Management 3 0 0 3 73

10. SBM 1606 Biomems and Nanotechnology 3 0 0 3 171

11. SBT1610 GMP and Quality Concepts 3 0 0 3 186

12. SBT 1611 Biology for Engineers 3 0 0 3 187

13. SCH 1616 Environmental Impact Assessment 3 0 0 3 203

14. SCY 1601 Spectroscopy 3 0 0 3 208

15. SCY 1602 Energy Sources 3 0 0 3 209

16. SPH 1601 Energy Physics 3 0 0 3 210

17. SPH 1602 Geophysics 3 0 0 3 211

18. SPH 1603 Space Physics 3 0 0 3 212

19. SPH 1604 Astrophysics 3 0 0 3 213

20. SPH 1605 Atomic and Nuclear Physics 3 0 0 3 214

21. SIT 1402 Mobile Application Development 3 0 0 3 215

22. SIT 1606 Big Data 3 0 0 3 216

23. SIT 1609 Game Programming 3 0 0 3 217

24. SIT 1608 Green Computing 3 0 0 3 218

25. SCS 1302 Computer Graphics and Multimedia Systems 3 0 0 3 219

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B.E. / B.Tech REGULAR 16 REGULATIONS 2015

SCH1101 ENVIRONMENTAL SCIENCE AND ENGINEERING

(Common to ALL Branches of B.E/ B. Tech.) L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the issues related to environment and to emphasize the importance of a clean environment

UNIT 1 INTRODUCTION TO ENVIRONMENTAL STUDIES AND NATURAL RESOURCES 10 Hrs. Definition, scope and importance, need for public awareness, forest resources: use and over-exploitation, deforestation, case studies. Timber extraction, mining, dams, floods, drought, conflicts over water, dams-benefits and problems, mineral resources: use effects on forests and tribal people. water resources: use and over-utilization of surface and ground water, exploitation, environmental effects of extracting and using mineral resources, case studies food resources: world food problems, changes caused by agriculture and overgrazing, effects of modern agriculture, fertilizer-pesticide problems, water logging, salinity, case studies. Energy resources: growing energy needs, renewable and non renewable energy sources, use of alternate energy sources: Case studies. Land resources: land as a resource, land degradation, man induced landslides, soil erosion and desertification, role of an individual in conservation of natural resources, equitable use of resources for sustainable lifestyles.

UNIT 2 ECOSYSTEMS AND BIODIVERSITY 10 Hrs. Concept of an ecosystem, structure and function of an ecosystem - producers, consumers and decomposers - energy flow in the ecosystem, ecological succession, food chains, food webs and ecological pyramids. Introduction, types, characteristic features, structure and function of the (a) forest ecosystem (b) grassland ecosystem (c) desert ecosystem (d) aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries). Introduction to biodiversity, definition: genetic, species and ecosystem diversity - biogeographical classification of India - value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values, biodiversity at global, national and local levels. India as a mega-diversity nation, hot-spots of biodiversity, threats to biodiversity: habitat loss, poaching of wildlife, man-wildlife conflicts, endangered and endemic species of India, conservation of biodiversity, in-situ and ex-situ conservation of biodiversity.

UNIT 3 ENVIRONMENTAL POLLUTION 9 Hrs. Definition - causes, effects and control measures of: (a) air pollution (b) water pollution (c) soil pollution (d) marine pollution (e) noise pollution (f) thermal pollution (g) nuclear hazards. Solid waste management: causes, effects and control measures of urban and industrial wastes, role of an individual in prevention of pollution, pollution case studies, disaster management: floods, earthquake, cyclone and landslides.

UNIT 4 SOCIAL ISSUES AND THE ENVIRONMENT 8 Hrs. 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, Key initiatives of Rio declaration, Vienna convention, Kyoto protocol, Johannesburg summit and public awareness.

UNIT 5 HUMAN POPULATION AND THE ENVIRONMENT 8 Hrs. Population growth, variation among nations, population explosion, family welfare programme, environment and human health, human rights, value education, HIV / AIDS, women and child welfare, role of information

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SMT1101 ENGINEERING MATHEMATICS - I (Common to ALL branches except BIO GROUPS)

L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE The ability to identify, reflect upon, evaluate and apply different types of information and knowledge to form independent judgments. Analytical, logical thinking and conclusions based on quantitative information will be the main objective of learning this subject.

UNIT 1 MATRICES 12 Hrs. Characteristic equation of a square matrix - Eigen values and Eigen vectors of a real matrix- properties of Eigen values- Cayley-Hamilton theorem (without proof) - verification , finding inverse and power of a matrix - Diagonalisation of a matrix using orthogonal transformation - Reduction of quadratic form to canonical form by orthogonal transformation.

UNIT 2 GEOMETRICAL APPLICATIONS OF DIFFERENTIAL CALCULUS 13 Hrs. Curvature -centre, radius and circle of curvature in Cartesian coordinates - Evolutes - Envelope of family of curves with one and two parameters. - Evolute as envelope of normals.

UNIT 3 FUNCTIONS OF SEVERAL VARIABLES 11 Hrs. Introduction to partial derivatives - Jacobians - Taylor’s expansion - Maxima and minima of functions of two variables - Constrained maxima and minima using Lagrange’s multiplier method.

UNIT 4 ORDINARY DIFFERENTIAL EQUATIONS 11 Hrs. First order exact differential equations - Second order linear differential equations with constant coefficients - Particular Integral for eax, sinax or cosax, xn, xneax, eaxsinbx or eaxcosbx - Equations reducible to linear equations with constant co-efficients using x = et - Simultaneous first order linear equations with constant coefficients - Method of Variation of Parameters

UNIT 5 THREE DIMENSIONAL ANALYTICAL GEOMETRY 13 Hrs. Direction cosines and ratios - Plane - Plane through intersection of two planes - Straight Line - Coplanar lines - Planes and Straight lines - Shortest distance between two Skew lines - Sphere -Plane section of a sphere - Great Circle.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Veerarajan T, Engineering Mathematics for First Year, II Edition, Tata McGraw Hill Publishers, 2008. 2. Kandaswamy P & co., Engineering Mathematics for First Year, IX revised edition, S.Chand & Co Pub., 2010. 3. Moorthy M.B.K, Senthilvadivu K ,Engineering mathematics-I, Revised Edition, VRB Pub., 2010, 4. Arumugam S & co. Engineering Mathematics Vol-I , Revised Edition, SciTech Pub., 2010 5. Venkataraman M.K., Engineering Mathematics - First Year (2nd edition), National Publishing Co., 2000. 6. Kreyszig. E, Advanced Engineering Mathematics, 10th edition, John Wiley & Sons, Singapore, 2012. 7. Grewal B. S, Higher Engineering Mathematics, 41th Edition, Khanna Publications, Delhi,2011.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SPH1101 PHYSICS OF ENGINEERING MATERIALS (Common to ALL Branches of B.E/ B. Tech.)


COURSE OBJECTIVE To expose the students to different classes of materials and present the fundamentals of materials science; to develop the understanding of the behaviour of materials, their properties and structures; to facilitate selection of suitable material for particular engineering application.

UNIT 1 CHARACTERIZATION OF MATERIALS 9 Hrs. Introduction, Structural characterization - X-ray diffraction, Bragg’s law, Determination of crystal structure - powder X-ray diffractometer (Debye Scherrer camera) and Single crystal XRD with principle, construction and working, Microstructural characterization - Introduction, electromagnetic lens system, Determination of surface morphology by Scanning Electron Microscope (SEM), Transmission Electron Microscope (TEM) and Atomic Force Microscope (AFM) with principle, construction and working. Microhardness testing -Determination of microhardness by Vickers hardness test, Knoop hardness test and Nanohardness test with principle, construction, and working.

UNIT 2 MAGNETIC MATERIALS 9 Hrs. Introduction, Origin of magnetic moment - orbital, spin and nuclear magnetic moments; Bohr magneton; Classification of magnetic materials based on spin- dia, para, ferro, antiferro and ferri- Curie temperature, Neel temperature.; Magnetic domains- Domain theory of Ferro magnetism (Weiss theory) - Observation of domain (bitter powder pattern), Energies involved in domain formation - magnetostatic energy, anisotropic energy, magnetostrictive energy and domain wall energy; Hysteresis Curve -based on domain theory; Types of magnetic materials - soft and hard magnetic materials; Magnetic bubbles - formation and propagation of magnetic bubbles-T-bar, read/write operation.

UNIT 3 SUPERCONDUCTING MATERIALS 9 Hrs. Introduction to superconductivity- Properties of superconductor - electrical resistance, Meissner Effect, effect of heavy magnetic field, effect of heavy current (Silsbee’s rule), effect of high pressure , isotope effect, entropy, specific heat capacity, energy gap, London Penetration depth, Coherence Length, Ginzburg Landau Parameter, Flux Quantization and thermal conductivity. Theory of superconductivity - London Theory (Macroscopic), Bardeen, Cooper and Schrieffer Theory (Microscopic) - explanation based on formation of Cooper pairs and existence of energy gap. Types of superconductors - Type I and Type II superconductors, D.C. and A.C Josephson Effect, I-V Characteristics and applications of Josephson junction. Applications - cryotron, magnetic levitation train and SQUIDS. Problems of Part-A type.

UNIT 4 OPTICAL MATERIALS 9 Hrs. Introduction, refractive index, absorption and dispersion, reflections. Classification of optical materials, absorption in metals, semiconductors and insulators (dielectrics), Excitons- Frenkel and Mott-Wannier excitons, Point detects -Frankel and Schottky defects, Traps - trapping and recombination centres - Colour Centres - types - F-Centre, R-Centre, V-Centre (V1 and V2), M -Centre. Luminescence - Principle and classification - Mechanism and working of Photo luminescence (Fluorescence and Phosphorescence). Problems of Part-A type.

UNIT 5 SEMICONDUCTING MATERIALS 9 Hrs. Introduction - Band theory (qualitative), types of semiconductors- intrinsic semiconductor - carrier concentration and Fermi level in intrinsic semiconductor - extrinsic semiconductor - carrier concentration and Fermi level in extrinsic semiconductor (p type and n type) - Experimental determination Band gap of semiconductor -Hall Effect - experimental determination of Hall Voltage, Applications of Hall effect. Problems of Part-A type.

MAX. 45 HOURS

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SCY1101 ENGINEERING CHEMISTRY (Common to ALL Branches of B.E/ B. Tech.)


COURSE OBJECTIVES To understand the properties and various synthetic methods for the preparation of nanomaterials and their

applications. To know about the quality parameters of water and methods to estimate the toxic elements and softening methods. To give an overview about types of batteries and fuel cells, corrosion mechanisms and preventive methods. To have a basic idea about polymers and various moulding techniques.

UNIT 1 SYNTHESIS OF NANOMATERIALS 9 Hrs. Introduction: Nanomaterials: Definition - Classification based on dimensions - Size dependent properties. Types of nanomaterials: Nanoparticles: Synthesis by chemical reduction method. Nanoporous materials: Synthesis by sol-gel method. Nanowires: Synthesis by VLS mechanism. Carbon Nanotubes (CNTs): Single walled and multi walled nanotubes - Mechanical and electrical properties of CNTs - Applications of CNTs - Synthesis of CNTs by electric arc discharge method and laser ablation method.

UNIT 2 WATER TECHNOLOGY 9 Hrs. Introduction: Water quality parameters - Contamination of water by arsenic, lead, fluoride, mercury and their removal. Hardness: Types - Expression - Units. Estimation of hardness of water by EDTA method - Problems. Estimation of iron, calcium and magnesium: AAS method. Water softening: Zeolite process - Demineralization process. Desalination: Reverse osmosis - Electrodialysis.

UNIT 3 ELECTROCHEMICAL POWER SOURCES 9 Hrs. Electrochemistry: Galvanic cell - Electrochemical cell representation - EMF series and its significance. Batteries: Terminology - Lead-acid accumulator - Nickel-cadmium batteries. Lithium batteries: Li/SOCl2 cell - Li/I2 cell - Lithium ion batteries. Fuel Cells: Hydrogen-oxygen fuel cells - Solid oxide fuel cell (SOFC).

UNIT 4 CORROSION SCIENCE 9 Hrs. Introduction: Definition. Types: Dry corrosion: Mechanism - Pilling-Bedworth rule - Wet Corrosion: Mechanism. Types: Galvanic corrosion and differential aeration cell corrosion. Galvanic series and its significance. Factors influencing corrosion. Corrosion prevention: Material selection and design - Cathodic protection. Protective coatings: Paints - Constituents. Mechanism of drying of drying oils.

UNIT 5 POLYMER CHEMISTRY 9 Hrs. Introduction to polymers: Nomenclature - Functionality. Types of polymerization. Mechanism of polymerization: Free radical mechanism - Cationic mechanism - Anionic mechanism. Plastics: Types - Thermoplastics and thermosetting plastics. Properties: Strength - Crystalline and amorphous state - Average molecular weight - Polydispersity. Compounding of plastics. Moulding of plastics: Compression moulding - Injection moulding - Extrusion moulding. Introduction to conducting polymers.

MAX. 45 HOURS TEXT / REFERENCE BOOKS 1. Jain P.C. and Monica Jain, Engineering Chemistry, 15th Edition Dhanpat Rai Publishing Co., 2009. 2. Dara S.S., Text Book of Engineering Chemistry, S. Chand & Co, 2008. 3. Sheik Mideen A., Engineering Chemistry (I & II),13th Edition, Shruthi Publishers, 2010. 4. Kuriakose J.C. and Rajaram J., Chemistry in Engineering and Technology". Vol.1 & 2, 5th reprint, Tata McGraw Hill

Publishing Company (P) Ltd., 2010. 5. Sharma B.K., Engineering Chemistry, 2nd Edition, Krishna Prakasam Media (P) Ltd., 2001. 6. Mars G Fontana, Corrosion Engineering, 3rd Edition, Tata McGraw Hill, 2008. 7. David Linden, Thomas B Reddy, Handbook of Batteries, 4th Edition, McGraw-Hill, 2010.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks. 60 Marks (Out of 80 marks, maximum of 10% problems may be asked)

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SEE1103 BASIC ELECTRICAL AND ELECTRONICS

ENGINEERING (for Chem)

L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVES To impart the basic knowledge on the analysis and application of electrical and magnetic circuits To impart the basic Knowlrdge in the operation of the basic electronic devices

UNIT I C. & A.C CIRCUITS 12 Hrs Electrical quantities, Ohm’s Law, Resistors - Series and parallel combinations, Kirchoff’s laws, Sinusoidal functions - RMS (effective) and Average values - Phasor representation - J operator - sinusoidal excitation applied to purely resistive, inductive and capacitive circuits - RL , RC and RLC series circuits - power and power factor.

UNIT 2 MAGNETIC CIRCUITS 7 Hrs. Definition of MMF, Flux and reluctance -- Electromagnetic induction - Fleming’s rule - Lenz’s law - Faraday’s laws - statically and dynamically induced EMF - Self and mutual inductance - Analogy of electric and magnetic circuits.

UNIT 3 INTRODUCTION TO MACHINES 8 Hrs. Construction and principle of DC Generator - Emf equation - Types, Principle of DC Motor - Types, Construction and principle of single phase Transformer, Stepper motor, AC and DC servomotor.

UNIT 4 SEMICONDUCTOR DEVICES AND LOGIC GATES 9 Hrs. Discrete devices - PN junction diodes - Zener diodes - Tunnel diodes- Thermistor - Bipolar junction transistors - Field effect transistors (FET and MOSFET) - Uni junction transistors - Silicon controlled rectifiers and Triacs. Universal Gates - Half Adder - Full Adder.

UNIT 5 RECTIFIERS, AMPLIFIERS AND OSCILLATORS 9 Hrs. Half and full wave rectifiers- Capacitive and inductive filters- ripple factor- PIV-rectification efficiency. CB, CE and CC Configuration - RC coupled amplifier- positive and negative feedback - Barkhausen criterion for oscillations - RC and LC oscillators.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. B.N.Mittle, Aravind Mittle, “Basic Electrical Engineering” , Tata McGraw Hill”, 2nd Edition Sep 2005. 2. B.L.Theraja, “Fundamentals of Electrical Engineering and Electronics”, S.Chand & Co., First Multi colour Edition, 2006,

(Reprint 2009). 3. Smarajit Ghosh, “Fundamentals of Electrical and Electronics Engineering” , PHI Learning Private Ltd, 2nd Edition, 2010. 4. P.V.Prasad, S.Sivanagaraju & R.Prasad, “ Basic Electrical and Electronics Engineering”, Cengage Learning India pvt Ltd.,

Original Edition, 2013 5. C.L.Wadhwa, “Basic Electrical Engineering” , New Age International, 4th Edition, 2007, Reprint June 2010. 6. Abhijit Chakrabarti, Sudipta nath & Chandan Kumar Chanda, “Basic Electrical Engineering”, Tata McGraw Hill, 1st Edition,

2009. 7. T.Thyagarajan, “Fundamentals of Electrical and Electronics Engineering”, Sci Tech Publications, Fifth Edition, Reprint Jan

2010. 8. Sedha.R.S, A Text book of Applied electronics, 2nd Edition, S.Chand & company, 2005. 9. Dr.Sanjay Sharma, Electronic Devices and Circuits, 2nd , S.K.Kataria & Sons, 2012.

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks 60 Marks (Distribution may be 80% Theory & 20 % Numerical)

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SCS1102 FUNDAMENTALS OF PROGRAMMING (Common to ALL Branches of B.E/ B. Tech.)


3 0 0 3 100

COURSE OBJECTIVES To understand the basic programming concepts. To understand the concept of arrays, functions and pointers. To gain knowledge about memory management.

UNIT 1 INTRODUCTION 9 Hrs. Introduction: Algorithms, Pseudocodes & flowcharts, Overview of C, features of C, Structure of C program, Compilation & execution of C program. Identifiers, variables, expression, keywords, data types, constants, scope and life of variables, and local and global variables. Operators: arithmetic, logical, relational, conditional and bitwise operators. Special operators: sizeof () & comma (,) operator. Precedence and associativity of operators & Type conversion in expressions. Basic input/output and library functions: Single character input/output i.e. getch(), getchar(), getche() & putchar(). Formatted input/output: printf() and scanf().

UNIT 2 CONTROL STRUCTURES AND FUNCTIONS 9 Hrs. Control structures: Conditional control (if, nested if, switch case), Loop control (for, while, do while) and Unconditional control structures (goto) Functions: The Need of a function, user defined and library function, prototype of a function, calling of a function, function argument, passing arguments to function, return values, nesting of function, recursion. Library Functions: Concepts, mathematical and string functions.

UNIT 3 ARRAYS AND STRINGS 9 Hrs. Arrays: Single and multidimensional arrays, array declaration and initialization of arrays, array as function arguments. Strings: Declaration, initialization and string handling functions. Structure and Union: Defining structure, declaration of structure variable, accessing structure members, nested structures, array of structures, structure assignment, structure as function argument, function that returns structure, union.

UNIT 4 STORAGE CLASSES AND POINTERS 9 Hrs. Storage class specifier - auto, extern, static & register Pointers: The ‘&’ and ’*’ operators, pointers expressions, pointers Vs arrays

UNIT 5 MEMORY MANAGEMENT 9 Hrs. Pointer to functions, Function returning pointers Direct Memory Access functions: malloc(), calloc(), sizeof(), free() and realloc(). Preprocessor directives. Command line arguments Max. 45 Hours TEXT / REFERENCE BOOKS 1. Balaguruswami. E., Programming in C, TMH Publications,1997 2. Yashavant P. Kanetkar., Let us C, Fifth Edition, .2013 3. Gottfried , Programming with C, Schaums Outline Series, TMH publications,1997 4. Mahapatra , Thinking in C, PHI publications,2nd Edition,1998. 5. Subburaj . R , “Programming in C” , Vikas Publishing, First Edition, 2000


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SPH4051 ENGINEERING PHYSICS LAB

(Common for all branches of B.E/B.Tech) L T P Credits Total Marks

0 0 2 1 50

SUGGESTED LIST OF EXPERIMENTS 1. Quincke’s method – Determination of magnetic susceptibility of a liquid. 2. Semiconductor diode - Determination of the forbidden energy gap. 3. Optical Fibre – Determination of Numerical aperture and attenuation loss. 4. Torsional pendulum – Determination of Moment of inertia and Rigidity modulus of the wire. 5. Young’s modulus – non-uniform bending- Determination of Young’s modulus of the material of beam. 6. Spectrometer – Hallow prism – Determination of Refractive index of a liquid. 7. Copper Voltameter – determination of electrochemical equivalent of copper. 8. Lees Disc – Determination of thermal conductivity of bad conductor. 9. LASER grating – Determination of wavelength of laser light. 10. Newton’s Rings – Determination of Radius of Curvature of convex lens.

SCY4051 ENGINEERING CHEMISTRY LAB (Common for all branches of B.E/B.Tech)


0 0 2 1 50

SUGGESTED LIST OF EXPERIMENTS 1. Estimation of ferrous ion by potentiometric method. 2. Determination of pKa value of glycine using pH meter. 3. Estimation of mixture of acids by conductometric method. 4. Estimation of Nickel by using photocolorimeter. 5. Determination of viscosity of polymers by using Ostwald’s viscometer. 6. Estimation of total hardness of water sample by EDTA / AAS method.

SCS4101 PROGRAMMING IN C LAB L T P Credits Total Marks

0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Program to understand the basic data types and input/output functions. 2. Program for Looping and decision statements. 3. Program on Functions. 4. Program on Arrays. 5. Program on String Manipulations 6. Program on Structures and Union. 7. Program on Pointers. 8. Program to demonstrate the Command Line Arguments. 9. Program using Dynamic memory allocation. 10. Program to implement the Random Access in Files. 11. Program to implement math function. 12. Program to Implement sorting algorithms 13. Program to Implement searching algorithms 14. Programs to solve some of the Engineering applications.

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SHS1101 ENGLISH FOR SCIENCE AND TECHNOLOGY (Common to ALL branches of B.E/B.Tech)


COURSE OBJECTIVE To equip the learners with English communicative skills to handle the present and future needs by exposing them to situations and tasks in the areas of LSRW, genre and register related to EST by following content based teaching.

UNIT 1 BASIC COMMUNICATION 9 Hrs. Listening for specific information, Self Introduction, Reading Comprehension, Kinds of Sentences, Parts of Speech, Tenses & its Types, Impersonal Passive, Elements of Effective Writing, Letter Writing, Concord, Prefixes & Suffixes

UNIT 2 NUANCES OF EST 9 Hrs. Listening for inference, Describing a process, Cloze Reading and its types, Transcoding - Encoding & Decoding, Flow Chart, Bar chart, Pie Chart, Tabular Column, Tree Diagram, Technical Definitions, Connectives & Discourse Markers, Word Association- connotations

UNIT 3 EST NOW AND THEN 9 Hrs. Listening and Note taking, Role-play, Reading and interpreting visual material (pictures/newspapers) Essay Writing - Note Making - WH questions - Question Tags - Types of sentences - Compound Nouns, Technical Definitions.

UNIT 4 APPLICATIONS OF EST 9 Hrs. Listening and Classifying information, Group discussion, Reading and identifying the topic sentence, - Writing a Project Proposal, Recommendations and Instructions - Manual Writing, Use of abbreviations and acronyms, Editing (Spelling, Grammar, Punctuation) Idioms & Phrases.

UNIT 5 PREPARING FOR FUTURE 9 Hrs. Listening and summarizing, Making presentations on given topics - Giving impromptu talks Reading and Summarizing, E-mail writing, Rearranging the Jumbled sentences Reported Speech, Homophones/Homonyms, Creative Writing & Poster making using similes/metaphors.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Sangeetha Sharma & Meenakshi Raman, Technical Communication: Principles and Practice. Oxford University Press, New Delhi, 2011. 2. Sanjay Kumar & Pushp Lata, Communication Skills, 2nd Edition, Oxford University Press, New Delhi, 2011. 3. Nira Konar, Communication Skills for Professionals, PHI Publishers, Eastern Economy Edition, New Delhi, 2011. 4. Sharon J Gerson & Steven M Gerson, Technical Communication: Process and Product, 8th Edition, Orient Longman, 2013. 5. Tyagi Kavita and Misra Padma, Basic Technical Communication PHI Publishers, Eastern Economy Edition, New Delhi, 2011. 6. Nagini,P S et al. Excellence Through communication, Shri Jai Publications, Chennai, 2005.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; with equal distribution to each unit -(10 x 2) 20 Marks

(Task types can include Multiple choice, open ended, gap filling, completion and rewriting the sentences, matching type etc.)

PART B : 2 questions from each unit with internal choice; each carrying 12 marks (5 X 10) 60 Marks (Questions types should testing vocabulary, grammar, reading and writing with equal

distribution to all. For example Reading Comprehension type can include skimming, scanning, comprehensive with evaluative, inferential and hypothetical question/ fixed type questions or cloze exercise , Academic paragraph writing based on Flow chart, Tree diagram, Bar diagram, Table and Pie chart to describe process, comparative and contrast, differentiate , Formal letter writing - Application for a Job & Resume Preparation/ Email- Letter inviting a dignitary-Accepting/Declining (or) Rearranging the jumbled sentences in the right order, (or) Requesting for Practical Training/ Letter to the Editor. Writing a Project Proposal / Project Report (or) Essay Writing- Writing an Essay on a given topic, Summary writing or Making notes in the standard format with title. Grammar Rearranging the jumbled sentences in the right order or editing the paragraph for errors based on syllabus)

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SMT1105 ENGINEERING MATHEMATICS - II (Common to ALL branches except BIO Groups)


COURSE OBJECTIVE Analytical, logical thinking and conclusions based on quantitative information will be the main objective of learning this subject.

UNIT 1 MULTIPLE INTEGRALS 13 Hrs. Double integrals in cartesian and polar co-ordinates - Change the order of integration - Change of variables from cartesian to polar coordinates- Area of plane curves using double integrals- Triple integrals - Volume using triple integrals in cartesian co-ordinates (simple applications).

UNIT 2 BETA AND GAMMA INTEGRALS 11 Hrs. Properties of definite Integrals and problems - Beta and Gamma integrals - Relation between them - Properties of Beta and Gamma integrals with proofs - Evaluation of definite integrals in terms of Beta and Gamma function - Simple applications (evaluation of double integrals).

UNIT 3 VECTOR CALCULUS 12 Hrs. Gradient, divergence and curl - Directional derivative - Irrotational and Solenoidal vector fields - Vector Integration - Simple problems on line, surface and volume Integrals, Green’s theorem in a plane, Gauss divergence theorem and Stoke’s theorem (without proofs)- Simple applications involving cubes and rectangular parallelopipeds.

UNIT 4 LAPLACE TRANSFORMS 14 Hrs. Laplace transform - Transforms of standard functions - properties- Transforms of derivatives and integrals - Transforms of the type eatf(t), tf(t), f(t)/t - Transform of periodic functions - Transform of unit step function and impulse function - Inverse Laplace transforms - Convolution theorem - Initial and final value theorems

UNIT 5 APPLICATIONS OF LAPLACE TRANSFORM 10 Hrs. Llinear ordinary differential equation with constant co-efficients - Integral equations - Integral equations of convolution type -simultaneous linear differential equations with constant co-efficients.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Kreyszig. E, Advanced Engineering Mathematics, 10th edition, John Wiley & Sons, Singapore, 2012. 2. Grewal B. S, Higher Engineering Mathematics, 41th Edition, Khanna Publications, Delhi,2011. 3. Bali N.P and Manish Goyal, A Text book of Engineering Mathematics, Eigth Edition, Laxmi Publications Pvt Ltd.,

2011. 4. Venkatraman M.K, Engineering Mathematics, National Publishing Company, 2000. 5. NarayananS., Manicavachagom Pillay T.K., Ramanaiah G., Advanced Mathematics for Engineering students,

Volume I, 2nd Edition, S. Viswanathan Printers and Publishers, 1992.


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SPH1103 ENGINEERING PHYSICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide the students with fundamental knowledge in Cryogenics and Acoustics, Properties of Matter such as Elasticity and Viscosity; and enable them to apply relevant principles to solve real world engineering problems.

UNIT 1 LOW TEMPERATURE PHYSICS 9 Hrs. Properties of cryogenic fluids- oxygen, nitrogen, helium and hydrogen - Joule Thomson effect - Porous plug experiment -Production of low temperatures- adiabatic demagnetisation of a paramagnetic salt - Cascade process - Practical applications of low temperatures -Refrigeration and Air conditioning machines - Super fluidity and its applications ( elementary ideas only)

UNIT 2 ELASTICITY 9 Hrs. Introduction-stress and strain diagram -Hooke’s law- types of elasticity- Young’s modulus, Bulk modulus, Rigidity modulus. Poisson ratio - Twisting couple on a cylinder (wire) - torsional pendulum - determination of rigidity modulus. Bending of beams - expression for bending moment of a beam - expression for the depression of the cantilever loaded at the free end - uniform and non-uniform bending-theory and experiment- I form of girders.

UNIT 3 VISCOSITY 9 Hrs. Streamline and turbulent motion, coefficient of viscosity - equation of continuity, Euler’s equation, critical velocity, Reynolds’s number, Poiseuille’s equation for flow of a liquid through a capillary tube - Stoke’s law (statement only)- terminal velocity, Bernoulli’s theorem and applications, Lift of an Aeroplane, Atomizer, Venturi meter, filter pump and Pitot’s tube.

UNIT 4 METAL ALLOYS 9 Hrs. Introduction, classification of metal alloys-Ferrous and Non Ferrous Alloys, Ferrous Alloys- classification, composition, properties and applications; Synthesization of alloy steels-Electric Arc Furnace process (Heroult furnace); Non-Ferrous Alloys - Aluminium, Copper, Titanium, Magnesium alloys - composition, properties and applications. Shape Memory Alloys - Shape memory effect, mechanism, transformation temperature, types of SMA - one way and two way shape memory effect; General applications of SMA.

UNIT 5 ACOUSTICS OF BUILDINGS 9 Hrs. Introduction - musical sound and noise, characteristics of musical sound - pitch, loudness, quality - Weber-Fechner law, decibel scale, sound intensity level and sound pressure level. Sound absorption-OWU, sound absorption coefficient and its measurements - Reverberation - Reverberation time - Standard Reverberation time - Sabine’s formula to determine the Reverberation time (Jaegar method), Factors affecting the acoustics of a building and the remedies, Principles to be followed in the acoustical design of a good auditorium.

MAX. 45 HOURS TEXT / REFERENCE BOOKS 1. Mathur D.S, Heat and Thermodynamics, Reprint, S. Chand and Co. 2004. 2. Christian Enss and Siegfried Hunklinger, Low temperature Physics, 1st Edition, Springer, 2005. 3. Mathur D.S, Elements of Properties of Matter, Reprint, S.Chand and Co. 2005. 4. Srinivasan M.R, Physics for Engineers, 2nd Edition, New Age international Publishers, 2005. 5. Gaur. R.K. and Gupta. S.L., Engineering Physics, 8th Edition, Dhanbat Rai Publications, 2007. 6. Avadhanulu. M.N. and. Kshirsagar. P.G, Engineering Physics, 2nd Edition, S. Chand and Company, 2007. 7. Willam D Callister, Materials Science and Engineering an introduction, 6th Edition, john-Wiley and Sons, 2004. 8. Rajendran.V, Marikani A., Materials Science, 8th Reprint, Tata McGraw-Hill, 2008. 9. Rajagopal.K, Text book of Engineering Physics, Part-I, 1st Edition, Prentice Hall of India, 2008 10. Kinsler L.E, Frey A.R., Coppens A.B. and Sanders J.V., Fundamentals of Acoustics, 4th Edition, John-Wiley and sons, 2005.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; 2 questions from each of the five units. 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks. 60 Marks (Applications” mentioned in the syllabus refer to the ba8sic applications and not to any specific case.) (Maximum of 20 % problems may be asked.)

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SCY1105 PHYSICAL CHEMISTRY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To understand the fundamentals related to the phase diagrams and their applications. To know about the types and properties of solutions. To expose the students for various separation techniques for the purification of compounds. To provide an idea about the chemical kinetics in terms of order, molecularity and their derivations involved. To give an overview about the advanced electrochemical applications.

UNIT 1 PHASE RULE 9 Hrs. Phase diagram - Information from phase diagram - Terminology used in phase diagram. Gibb’s phase rule - Derivation. One component system: Water system. Two component alloy systems: Classification - Reduced phase rule - Thermal analysis. Simple eutectic system: Lead-silver system. Congruent System: Zinc-magnesium system. Incongruent system: Sodium-potassium system. Phase diagram of simple three component system.

UNIT 2 SOLUTIONS 9 Hrs. Introduction: Solid solution - Hume Rothery’s rule. Types of solid solutions: Liquid solutions: Solubility of partially miscible liquids - Phenol-water system. Colligative properties: Lowering of vapour pressure. Raoult’s law: Derivation - Osmotic pressure - Isotonic solution - Relationship between osmotic pressure and vapour pressure. Depression in freezing point - Derivation. Elevation in boiling point - Derivation - Problems.

UNIT 3 SEPARATION TECHNIQUES 9 Hrs. Distillation techniques: Fractional distillation - Steam distillation - Vacuum distillation. Chromatography: Elution analysis - Paper chromatography - Thin layer chromatography - Liquid chromatography - High performance liquid chromatography (HPLC) - Gas chromatography (GC).

UNIT 4 CHEMICAL KINETICS 9 Hrs. Introduction: First and second order reactions: Integration - Integration of nth order reaction. Methods of determining order and molecularity. Collision theory of bimolecular gaseous reactions - Activated complex of bimolecular reactions - Lindemann theory of unimolecular equation - Kinetics of complex reactions: Reversible reaction - Consecutive reaction - Chain reactions - Autocatalysis - Problems.

UNIT 5 ADVANCED ELECTROCHEMISTRY 9 Hrs. Introduction: Cell constant - Equivalent conductance - Molar conductance. Ionic mobility: Transport number - Moving boundary method - Hittorff’s method. Debye Huckel theory of strong electrolytes. Concentration cells: Types - Concentration cells without transference and with transference. Potentiometric tritrations: Redox titration. Polarography - Applications of polarography. Max. 45 HOURS

TEXT / REFERENCE BOOKS 1. Puri B.R., Sharma L. R., Madan. S.Pathania, Principles of Physical Chemistry, 41st Edition , Vishal Publishing co., 2004. 2. Keith J. Laidler, Chemical Kinetics, Third Edition, Pearson education limited, 2004. 3. Atkins P. W., Physical Chemistry, 6th edition, Oxford University press, 1998. 4. Barrow G. M., Physical Chemistry, 5th edition, McGraw-Hill, 1988. 5. Glasstone S., A Text book of Physical Chemistry, Macmillan Ltd, 1976. 6. Jayakumar V., Engineering Metallurgy, ARS publications, 2012.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks. 60 Marks (Out of 80 marks, maximum of 10% problems may be asked)

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SCS1202 OBJECT ORIENTED PROGRAMMING (Common to ALL Branches of B.E/ B. Tech.)


COURSE OBJECTIVES To understand the fundamental concepts of object oriented programming. Be familiar with concepts like abstraction, inheritance, polymorphism. To understand the concept of Classes.

UNIT 1 INTRODUCTION TO OBJECT ORIENTED PROGRAMMING 9 Hrs. Object Oriented Programming Paradigms - Comparison of Programming Paradigms - Object Oriented Languages - Benefits of Object Oriented Programming - Comparison with C - Overview of C++ -Pointers- Functions - Scope and Namespaces - Source Files and Programs.

UNIT 2 CLASSES AND OBJECTS 9 Hrs. Working with classes - Classes and objects - Class specification-Class objects-Accessing class members-Defining class members-Inline functions-Accessing member functions within class-Data hiding-Class member accessibility-Empty classes,

UNIT 3 CONSTRUCTORS AND OVERLOADING 9 Hrs. Default constructors-Parameterized constructors-Constructor overloading-Copy constructors-new, delete operators-”this” pointer-friend classes and friend functions-Function overloading- Unary Operator overloading -Binary Operator overloading.

UNIT 4 INHERITANCE 9 Hrs. Base class and derived class relationship-Derived class declaration-Forms of inheritance-Inheritance and member accessibility- Constructors in derived class-Destructors in derived class-Multiple inheritance-Multi level inheritance-Hybrid inheritance-Virtual base classes-Member function overriding-Virtual functions-Abstract classes-Pure Virtual functions.

UNIT 5 I/O AND LIBRARY ORGANIZATION 9 Hrs. I/O Stream - File I/O - Exception Handling - Templates - STL - Library Organization and Containers - Standard Containers - Overview of Standard Algorithms-Iterators and Allocators.

MAX. 45 HOURS

TEXT / REFERENCE BOOKS 1. Balagurusamy, ”Object Oriented Programming with C++”, Tata McGraw Hill,4th Edition,2010 2. Venu Gopal.K.R, Ravishankar.T, and Raj kumar, ”Mastering C++”, Tata McGraw Hill,1999. 3. Bjarne Stroustrup, ”The C++ programming language”, Addision Wesley, 3rd Edition,1998. 4. John R Hubbard, “Programming with C++”, Schaums Outline Series, McGraw Hill, 2nd edition, 2009. 5. James Martin & James J.Odell,”Object Oriented methods-A foundation”,Prentice Hall,1997.


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SCH1102 MATERIAL SCIENCE AND ENGINEERING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To acquire basic understanding of advanced materials, their functions and properties for technological

applications and emphasize the significance of materials selection in the design process

UNIT 1 NATURE OF MATERIALS 9 Hrs. Selection process of engineering materials (General aspects), Chemical and physical properties of materials, chemical structure, Micro and macro structure, corrosion resistance, chemical reactivity. Mechanical properties, stress, strain, strength, hardness, malleability, ductility, elasticity, plasticity, toughness, thermal stability. Types of deformation: Plastic, viscous; plastic deformation of single crystal, poly crystalline metals, slip, twinning, dislocations, viscoelasticity, creeps in metals, amorphous materials.

UNIT 2 METALLURGY 9 Hrs. Extractive Metallurgy: Hydro, pyro and electro metallurgy, refining of metals. Powder Metallurgy: methods of production of metal powder, mixing of metal powders, compaction of powders - applications. Extraction process of Iron: manufacture of pig iron, blast furnace operations, chemistry of reactions. Manufacture of cast iron, varieties of cast iron, effect of impurities. Production of steel , Bessemer process ,open-hearth process ,L D methods. Classification of steel, effect of impurities. Heat treatment process: annealing, hardening, tempering, normalizing and gas carburizing. Fe- Carbon phase diagram.

UNIT 3 COMPOSITES AND ADHESIVES 9 Hrs. Polymer composites: Introduction, Types of composites, particle reinforced, fiber reinforced, structural composites, examples. Matrix materials, reinforcement materials-, Kevlar, Polyamides, fibers, glass, carbon fibers, ceramics and metals. Techniques for producing FRP, applications..

UNIT 4 BIOMATERIALS 9 Hrs. Classification of bio-materials (based on tissue response) ,Comparison of properties of some common biomaterials , Metallic implant materials (stainless steel, cobalt-based and titanium-based alloys) , Polymeric implant materials (Polyamides, polypropylene, Acrylic resins and Hydro gels) ,Tissue replacement implants , Soft and hard tissue replacements ,Skin implants , Tissue engineering, Biomaterials for organ replacement (Bone substitutes), Biosensor.

UNIT 5 MODERN ENGINEERING MATERIALS 9 Hrs. Smart materials , Shape memory alloys, Electrostatics, Irreversible Marten sites, Domain Walls, Nature of Shape Memory, Shape Memory Alloy Materials, Ferromagnetic Shape Memory Alloys, Relation to Shape Memory Alloys, Actuator and Sensor Materials Chromic materials (Thermo, Photo and Electro) ,Rheological fluids , Metallic glasses.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Thiruvadigal. J. D, Ponnusamy. ,Sudha.D, and Krishnamohan. M., Materials Sciences , 2nd Edition, Vibrant Publication,

Chennai, 2013. 2. Rajendran. V., Materials Science, 3rd Edition, Tata McGraw- Hill,New Delhi,2011 3. Khanna. O.P, A Text book of Material science and Metallurgy, 4th Edition, Danpat Rai Publications, 1999. 4. Dara .S.S, A text book of Engineering Chemistry, 2nd Edition, S.Chand and company Ltd., 2003 . 5. Rajput. R.K., A Text book of Material Science and Engineering, 3rd Edition, S.K Kataria & sons, Delhi, 2003 . 6. Agarwal. C.V, Chemistry of Engineering materials, 4th Edition, Tata McCraws Hill, 1997 . 7. William F.Smith, Foundation of Materials Science and Engineering, 2nd Edition, Tata McCraw Hill, 1998 .

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks 60 Marks

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SME 4053 ENGINEERING GRAPHICS

(Common to CSE, IT, BIO, Chemical & Circuit Branches)


0 0 6 2 100

The student is expected to acquire the drafting proficiency depending on the operational function in order to perform the day to day activity.

Fundamentals Use of drafting instruments – BIS – Letttering – Vertical and Inclined – Dimensioning – Aligned and Unidirectional systems – Scaling – Importance of graphics in engineering applications.

Geometrical Constructions Dividing a given straight line into any number of equal parts – Bisecting a given angle – Trisecting a right angle – Drawing a regular pentagon and hexagon given one side – Conic sections – Construction of ellipse, parabola and hyperbola by Eccentricity method.

Projection of Points and Lines Types of projection - Introduction to orthographic projection – Orthographic projection of points lying in four quadrants – Orthographic projection of lines in first quadrant – Parallel to both the planes – Perpendicular to one plane – Parallel to one plane and inclined to the other plane – Inclined to both the planes.

Projection of Planes and Solids Projection of rectangular, square and circular planes - Orthographic projection of prisms, pyramids, cone and cylinder in first quadrant – Axis perpendicular to HP – Axis perpendicular to VP – Axis inclined to only one plane of projection – Change of position method only.

Section of Solids and Development of Surfaces Sectioning of prisms, pyramids, cylinder and cone in simple vertical positions with cutting planes perpendicular to one plane and parallel or inclined to other plane - Need for development of surfaces – Development of prisms, pyramids, cylindrical and conical surfaces.

Isometric Projection and Orthographic Projection Isometric scale – Isometric View and Isometric Projection of simple solids and combination of solids - Drawing orthographic views (plan, elevation and profile) of objects from their isometric views.

TEXT / REFERENCE BOOKS 1. Natarajan, K.V., A text book of Engineering Graphics, Dhalakshmi Publishers, 2006 2. Bhatt, N.D. and Panchal, V.M., Engineering Drawing, Charotar Publishing House, 2010 3. Venugopal, K. and Prabhu Raja, V., Engineering Drawing and Graphics + AutoCAD, New Age International, 2009. 4. SP 46: Engineering Drawing Practice for schools and colleges, Bureau of Indian Standards.

Outcome At the end of the course, the students will be efficiently able to visualize the engineering components. Chosen problems will be solved to illustrate the concepts clearly.

End Semester Examination Question Paper Pattern By using mini drafter: 100 marks Note: Only after submission of all drawing sheets prescribed by staff member, the students will be allowed for university practical examination.

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SCS4201 OBJECT ORIENTED PROGRAMMING LAB L T P Credits Total Marks

0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Develop a C++ program to implement a class, object creation, member function invocation concept. 2. Develop a C++ program to implement the various constructors and destructor concept. 3. Develop a C++ program to implement a friend function, Inline function. 4. Develop a C++ program to implement an operator (Unary & Binary) overloading concept. 5. Develop a C++ program to implement a function overloading concept. 6. Develop a C++ program to implement a run time polymorphism. 7. Develop a C++ program to implement the following inheritance types.

a) Single b) Multiple c) Multilevel d) Hierarchical e) Hybrid

8. Develop a C++ program to implement an Abstract class concept. 9. Develop a C++ program to implement a Virtual function. 10. Develop a C++ program to find the number of characters in a file. 11. Develop a C++ program to handle the exceptions.

Case Study 1. Categorization of living beings as humans, animals, birds, insects, etc.., using inheritance. 2. Develop user defined manipulator for the following named

a) Rupees for displaying Rs. and sets the precision to 2. b) Dollar for displaying $.

SIT4106 JAVA PROGRAMMING LAB L T P Credits Total Marks

0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Write a java program to implement contructor overloading. 2. Write a java program to implement multilevel inheritance. 3. Write a java program to implement interfaces. 4. Write a java program to implement packages with all access specifiers. 5. Write a java program to implement runtime polymorphism. 6. Write a java program to demonstrate priority of threads. 7. Write a java program to demonstrate nested class. 8. Write a java program to demonstrate clonable interface. 9. Write a java program to implement mouse events. 10. Write a java program to calculate the simple interest by geting input from the user using Streams. 11. Create a student form in an applet window using AWT controls and update the database. 12. Write a java program to include controls using cardlayout manager. 13. Write a java program to include checkbox,radio button, tabbed panes in a window using swings. 14. Write a java program to print the address and name of local machines. 15. Develop a simple java bean using BDK.

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SMT1201 ENGINEERING MATHEMATICS - III (Common to ALL branches except BIO GROUPS, CSE & IT)



UNIT 1 COMPLEX VARIABLES 11 Hrs. Analytic functions - Cauchy- Riemann equations in cartesian and polar form - Harmonic functions - properties of analytic functions - Construction of analytic functions using Milne - Thompson method - Bilinear transformation.

UNIT 2 COMPLEX INTEGRATION 12 Hrs. Cauchy’s integral theorem - Cauchy’s integral formula - problems - Taylor’s and Laurent’s series - Singularities - Poles and Residues - Cauchy’s residue theorem and problems.

UNIT 3 FOURIER TRANSFORMS 12 Hrs. The infinite Fourier transform - Sine and Cosine transform - Properties - Inversion theorem - Convolution theorem - Parseval’s identity - Finite Fourier sine and cosine transform.

UNIT 4 PARTIAL DIFFERENTIAL EQUATIONS 13 Hrs. Formation of equations by elimination of arbitrary constants and arbitrary functions - Solutions of PDE - general, particular and complete integrals - Solutions of First order Linear PDE ( Lagrange’s linear equation ) - Solution of Linear Homogeneous PDE of higher order with constant coefficients.

UNIT 5 THEORY OF SAMPLING AND TESTING OF HYPOTHESIS 12 Hrs. Test of Hypothesis - test of significance - Large samples - Z test - single proportion - difference of proportions - Single mean - difference of means - Small samples - Student‘s t test - single mean - difference of means -Test of variance - Fisher’s test - Chi square test - goodness of fit - independence of attributes.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Kreyszig, E., Advanced Engineering Mathematics (8th Edition), John Wiley and Sons (Asia)Pvt. Ltd., Singapore, 2001. 2. Grewal,B.S., Higher Engineering Mathematics, Tata Mcgraw Hill Publishing Co., New Delhi, 1999. 3. Kandasamy, P., Thilagavathy, K., and Gunavathy, K., Engineering Mathematics, (4th Revised Edition), S.Chand&Co., New

Delhi, 2001. 4. Veerarajan,T., Engineering Mathematics Tata Mcgraw Hill Publishing Co., NewDelhi, 1999. 5. S.C. Gupta, V.K. Kapoor, Fundamentals of Mathematical Statistics, S.Chand & Company, 2012.


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SCH1201 MECHANICAL OPERATIONS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE This course is concerned with the properties, modification and separation of particulate solids.

UNIT 1 PARTICLE SIZE AND SHAPE 9 Hrs. Introduction:-Scope & Application of Solid Fluid Operation. Particle Size Analysis:-Particle Size Measurement & Distribution, Sieve Analysis- Differential and Cumulative screen analysis, Specific surface area, Particle population, Different mean diameters for a mixture of particles. Particle size measurement, Surface area measurements, Statistical mean diameters, Screening Equipments : Size separation, Screening, Industrial screens, Grizzly, Gyratory and Vibratory screens, Revolving screens, Trommels, Capacity and Effectiveness of screens, Relevant equations and problems.

UNIT 2 INTRODUCTION TO SIZE REDUCTION EQUIPMENTS 9 Hrs. Principles of Comminution - Laws of crushing & Power Requirement in Milling Operations, Crushing and Grinding efficiency, Description and working of size reduction equipment, Jaw and Roll crushers, Hammer mill, Gyratory crushers, Ball mills, Revolving mills, Attrition mills, Fluid energy mill, Cutting machines, Open and Closed circuit grinding, Wet and Dry grinding, Grindability Index.

UNIT 3 SEDIMENTATION, STORAGE AND CONVEYING OF SOLIDS 9 Hrs. Batch sedimentation, Equipments for sedimentation, Kynch theory of sedimentation, Calculation of area and depth of continuous thickeners, Batch thickeners and Continuous thickeners. Phase separation: Centrifugal separation, Electrostatic precipitators and Magnetic separation. Gas-solid separation: Gravity settling, Impingement separators, Cyclone separators, Bag filters, Scrubbers, Mineral jig, Cyclone separator, Hydro cyclone types and Centrifuges, Centrifugal clarifier Storage and Conveying of Solids: Introduction to storage and conveying of solids, Bins, Hoppers and Silos, Flow out of bins, design consideration of bins, loading and unloading of solids. Bucket elevators, Apron conveyors. Belt conveyors: Types of Belt conveyors, Selection considerations.

UNIT 4 FILTRATION 9 Hrs. Filter media and filter aids, Classification of filtration, Pressure drop through filter cake, Filter medium resistance, Specific cake resistance, Continuous Filtration, Washing and Dewatering of filter cakes, Centrifugal filtration.

UNIT 5 MIXING AND AGITATIONS 9 Hrs. Necessity of mixing & agitation in chemical industries, Types of Impellers & propellers, Different flow patterns in mixing, Calculation of power requirement of mixing equipment, Mixing equipment of pastes & viscous material, Solid - Solid Mixing, Agitator selection.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Warren L. Mccabe, Julian C. Smith and peter Harriott, Unit Operations of Chemical Engineering, 8th Edition, McGraw Hill

International Edition., New York 2009. 2. Badger and Banchero, Introduction to Chemical Engineering, 2nd Edition, McGraw Hill, 2001. 3. Coulson J.M., Richardson J.F., Backhurst J.R. and Harker J.M., Coulson & Richardson’s Chemical Engineering, Vol. II, 5 th

Edition,Butter worth Heinemann, Oxford, 2002. 4. Brown, G.G., Unit Operations, 2nd Edition, CBS Publishers & Distributors, New Delhi, 2005.


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SCH1202 CHEMICAL ENGINEERING THERMODYNAMICS - 1 L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To acquire basic understanding of concepts and laws of thermodynamics, volumetric properties of fluids and

thermodynamic properties of fluids

UNIT 1 BASIC CONCEPTS & FIRST LAW OF THERMODYNAMICS 9 Hrs. The terminologies of thermodynamics - Work, energy, heat, internal energy, extensive & intensive properties, equilibrium, the variables and quantities of thermodynamics, categorization of systems and processes. Energy classifications, point and path properties, reversible and irreversible processes, Zeorth law of thermodynamics, statements of first law for the non flow and flow systems, enthalpy and heat capacity, limitations of the first law.

UNIT 2 LAWS OF THERMODYNAMICS 9 Hrs. Statements of the second law of thermodynamics, Heat Engines, Heat pumps, Carnot principle, The entropy function, Calculation of entropy changes - for phase change, processes involving ideal gas, adiabatic mixing process, isothermal mixing of ideal gases, chemical reactions, clausius inequality, applications of the second law. Third law of thermodynamics.

UNIT 3 THERMODYNAMIC EQUATIONS OF STATE 9 Hrs. The PVT behaviour of pure fluids, laws of corresponding states and equation of states approaches to the PVT relationships of real gases - Vander waals equation, Redlich Kwong Equation, Bertholet equation, Virial equation, compressibility factors, generalized equations of state, property estimation via generalized equation of state.

UNIT 4 THERMODYNAMIC FORMULATIONS 9 Hrs. Measurable quantities, basic energy relations, Maxwell relations, thermodynamic formulations to calculate enthalpy, internal energy and entropy as function of pressure and temperature, other formulations involving Cp and Cv, complex thermodynamic formulations, thermodynamic properties of an ideal gas, entropy change in reversible and irreversible process.

UNIT 5 APPLICATIONS OF THE LAWS OF THERMODYNAMICS 9 Hrs. Flow Processes - Continuity Equation, Energy Equation, Flow through nozzles, Ejectors , compression process, classification of compression processes, the work expression for different situations, the effect of clearance volume, multistage compression, Refrigeration- Vapor compression and Vapor absorption refrigeration, Choice of refrigerant, Liquefaction processes.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Smith, J.M., and Van Ness, H.C., Introduction to Chemical Engineering Thermodynamics, 6th Edition Mc-Graw-Hill, 2004. 2. Narayanan K.V ,A Text Book of Chemical Engineering Thermodynamics, 3rd Edition Prentice Hall of India Pvt. Ltd. 2001. 3. Hougen, O.A., Watson, K.M., and Ragatz, R.A., Chemical Process Principles, PART II, Thermodynamics, 3rd Edition, John

Wiley 1970. 4. Gopinath Halder, Introduction to Chemical Engineering Thermodynamics, 2nd Edition, PHI Learning Private Limited, 2009. 5. Rao Y.V.C., Chemical Engineering Thermodynamics, 1st Edition, University Press (I) Ltd., Hyderabad, 1997.


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SCH1203 FLUID MECHANICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To understand the governing principles of momentum transport in chemical process systems.

UNIT 1 FLUID FLOW PHENOMENA 9 Hrs. Nature of fluids-properties of fluids, incompressiblee and compressible, hydrostatic equilibrium. Manometers U-Tube and inclined. Potential flow, boundary layer, the velocity field, laminar flow, Newtonian and Non Newtonian fluids, Newton’s law of viscosity, turbulence. Reynolds number and transition from laminar to turbulent flow, Eddy viscosity, flow in boundary layers

UNIT 2 KINEMATICS OF FLUID FLOW 9 Hrs. Streamlines and stream tubes, equation of continuity, Bernoulli equation. Flow of incompressible fluids in conduits and thin layers: friction factor, relationships between skin friction parameters, average velocity for laminar flow of Newtonian fluids, Hagen-Poiseuille equation, hydraulically smooth pipe, von Karman equation, roughness parameter, friction-factor chart, equivalent diameter.

UNIT 3 FLOW PAST IMMERSED BODIES AND FLUIDIZATION 9 Hrs. Drag and drag coefficients. Ergun equation, terminal settling velocity, free and hindered settlings, Stokes’ law, Newton’s law. Fluidization, conditions for fluidization, minimum fluidization velocity.

UNIT 4 TRANSPORTATION OF FLUIDS 9 Hrs. Introduction to pipe and tubing, joint and fittings, stuffing boxes, mechanical seals, gate valves and globe valves, plug cocks and ball valves. Classification and selection of pumps, Reciprocating and Centrifugal pumps, developed head, power requirement, suction lift cavitation and pump work in Bernoulli equation, characteristic curves.

UNIT 5 METERING OF FLUIDS 9 Hrs. Constructional features and working principles of Venturi meter, Orifice meter, Area meters-Rota meter, Point velocity-Pitot tube, V-element meter, Target meter-ultrasonic meters, vortex shredding meter, Turbine meter.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. McCabe, W.L, Smith J.C and Harriot. P., Unit Operations in Chemical Engineering, 7th Edition, Mc-Graw-Hill, 2009. 2. Noel de Nevers, Fluid Mechanics for Chemical Engineers, 2nd Edition, McGraw-Hill, 1991. 3. Coulson J.M. and Richardson J.E.,Chemical Engineering, Volume 1, 3rd Edition, Pergamon Press, 2000. 4. Shames, I.H., Mechanics of Fluids, 3rd Edition, McGraw-Hill Inc., 1992. 5. White, F.M., Fluid Mechanics, 4th Edition, McGraw-Hill Inc., 1999.

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks 60 Marks

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SCH1204 CHEMICAL PROCESS CALCULATIONS L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE To perform stoichiometric calculations for chemical and non-chemical systems and to understand quantitative relationships between matter and energy involved in physiochemical processes.

UNIT 1 INTRODUCTION 12 Hrs. Units and Dimensions, Basic and derived units, use of model units in calculations, Methods of expressing, compositions of mixture and solutions. Gas Calculations: Ideal and real gas laws,Gas constant ,Calculations of pressure, volume and temperature using ideal gas law. Use of partial pressure and pure component volume in gas calculations, applications of real gas relationship in gas calculation.

UNIT 2 MATERIAL BALANCE WITHOUT CHEMICAL REACTION 12 Hrs. Application of material balance to unit operations like distillation, evaporation, crystallization, extraction, absorption and stripping, drying, mixing.

UNIT 3 MATERIAL BALANCE WITH CHEMICAL REACTION 12 Hrs. Stoichiometric principles, Limiting and excess reactant, conversion, selectivity and yield. Application of material balance to systems with recycle, bypass and purging.

UNIT 4 FUELS AND COMBUSTION 12 Hrs. Determination of Composition by Orsat analysis of products of combustion of solid, liquid and gaseous fuels - Calculation of excess air from orsat technique, problems on sulphur and sulphur containing compounds.

UNIT 5 ENERGY BALANCE 12 Hrs. Heat capacity of solids, liquids and gases, mean heat capacity, sensible heat and latent heat, evaluation of enthalpy, Standard heat of reaction, heat of formation, combustion, solution, mixing etc.,calculation of standard heat of reaction ,Effect of pressure and temperature on heat of reaction - Energy balance for systems with and without chemical reaction

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Himmelblau, D.M., Basic Principles and Calculations in Chemical Engineering, 6th Edition, Prentice Hall Inc., 2003 (with CD

containing programmes and problems). 2. Houghen. O.A., Watson. K.M and Ragatz. R.A, Chemical Process Principles, PART I,2nd Edition, John Wiley and Asia

Publishing, 1970. 3. Venkataramani, V and Anantharaman.N., Process Calculations, 2nd Edition, Prentice Hall of India Pvt. Ltd., 2003 4. Bhatt, B.L., Vora, S.M., Stoichiometry, 4th Edition, Tata McGraw-Hill, 2004. 5. Richard M. Felder, Ronald W. Rousseau, Elementary Principles of Chemical Processes, 3rd Edition,John Wiley & Sons,

Inc.Singapore, 2000.


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SCH1205 ENERGY ENGINEERING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart in depth understanding of the issues related with renewable energy and their development

UNIT 1 INTRODUCTION TO CONVENTIONAL & NON-CONVENTIONAL ENERGY SOURCES 9 Hrs. Conventional energy sources; non-conventional energy sources; Energy sources, Coal, Oil, Natural gas, nuclear fuels, Hydro power advantages. Classification of fuels. Solar Energy, Solar radiation and its measurement, solar constant, solar radiation at earth’s surface, solar radiation geometry, solar radiation measurement. Introduction to solar energy. Applications, solar water heating, space heating, space cooling, solar thermal electric conversion. Agriculture and industrial process heating, solar distillation, solar pumping, solar cooking.

UNIT 2 ENERGY FROM BIOMASS (BIO - ENERGY): INTRODUCTION 9 Hrs. Biomass conversion Technologies. Wet processes, Dry processes. Biogas generation. Factors affecting biodigestion or generation of gas. Classification of biogas plants. Advantages and disadvantages of floating drum plant. Advantages and disadvantages of fixed dome type plant. Types of biogas plants (KVIC model & Janata model). Selection of site for biogas plant.

UNIT 3 BIO - ENERGY (THERMAL CONVERSION) AND ELECTRICAL CONDUCTION (MHD) 9 Hrs. Methods of obtaining energy from biomass, Thermal gasification of biomass, Classification of biomass gasifiers, Chemistry of gasification process, Applications of the gasifiers. Magneto hydrodynamic generator, electrical conductivity and formation of MHD, performance

UNIT 4 WIND ENERGY: INTRODUCTION 9 Hrs. Basic components of WECS (wind energy conversion system): Classification of WECS, Types of wind machines, horizontal axis machines, vertical axis machines. Applications of wind energy. Energy from the oceans: Introduction, Ocean thermal electric conversion (OTEC), Methods of ocean thermal electric power generation, Open cycle OTEC system, Closed or Anderson OTEC cycle, hybrid cycle. Application of energy from oceans.

UNIT 5 FUEL CELLS BASICS-ENERGY CONSERVATION 9 Hrs. Fuel Cells, Difference between batteries and fuel cells, Components of fuel cells, Principle of working of fuel cells, Fuel cell types: Alkaline fuel cells. Polymer electrolyte fuel cells, Phosphoric acid fuel cells, Molten carbonate fuel cells, Solid oxide fuel cells, Types of solid acid fuel acid fuel cells, Applications. Co-generation- waste heat recovery and heat pump.

Max.45 Hours.

TEXT / REFERENCE BOOKS 1. Rai G.D., Solar Energy Utilisation, 3rd Edition, Khanna Publishers, New Delhi, 2000. 2. Rai G.D., Non Conventional Energy Sources, 3rd Edition, Khanna Publishers, New Delhi, 2000. 3. Rao S.S., Energy Technology, 3rd Edition, Khanna Publishers, New Delhi, 2006 4. Rused C.K., Elements of Energy Conservation, 4th Edition, McGraw Hill, 1985. 5. Christopher H. and Armsteed H., Geothermal Energy, 2nd Edition, John Wiley, New York, 1978.


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SCH4051 TECHNICAL ANALYSIS & INSTRUMENTATION LAB


SUGGESTED LIST OF EXPERIMENTS 1. Determination of Inversion of Sucrose by using Rudolf Polarimeter 2. Determination of Liquid Vapor Equilibrium in a Binary System by using Abbe' Refractometer 3. Determination of Eutectic temperature and composition of a simple Eutectic system. 4. Determination of critical solution temperature of phenol-water system. 5. Determination of molecular weight by Rast’s method. 6. Determination of partition coefficient of Iodine between two immiscible solvents. 7. Determination of cell constant & to verify Ostwald’s dilution law. 8. Determination of Hardness of water for the given sample. 9. Determination of available chlorine in bleaching powder. 10. Determination of Saponification value of oil. 11. Determination of TFM & Alkalinity of given soap. 12. Determination of MnO2 in the given ore.

SCH4052 ORGANIC CHEMICAL PROCESSES & THERMODYNAMICS LAB


SUGGESTED LIST OF EXPERIMENTS 1. Organic Preparations -Synthesis of compounds involving the following reactions

a. Reduction b. Bromination c. Acetylation d. Hydrolysis e. Nitration

2. Qualitative Analysis -Analysis of following classes of compounds a. Aldehydes b. Ketones c. Acids d. Alcohols e. Amines f. Esters

3. Quantitative Analysis -Analysis of following classes of compounds a. Fertilizer b. Cement c. Sugar d. Drugs e. Proximate analysis of coal

4. Thermodynamics Experiments a. Heat of solution b. Heat of Neutralization c. Heat of Ionization

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SMT1204 ENGINEERING MATHEMATICS - IV (Common to ALL branches except BIO Groups, CSE & IT)



UNIT 1 FOURIER SERIES 13 Hrs. Definition- Dirichlets conditions- coefficients- Fourier series for the function defined in [c, c+2π],[c, c+2l] - Parseval’s identity ( without proof) - Half range cosine series and sine series of f(x) defined in [0,π],[0,l] - simple problems - Harmonic Analysis.

UNIT 2 APPLICATIONS OF PARTIAL DIFFERENTIAL EQUATIONS 13 Hrs. One dimensional wave equation - Transverse vibrating of finite elastic string with fixed ends- Boundary and initial value problems - Fourier solution - one dimensional heat equation - steady state problems with zero boundary conditions- Two dimensional heat equation - steady state heat flow in two dimensions- Laplace equation in Cartesian form( No derivations required).

UNIT 3 ALGEBRAIC AND TRANSCENDENTAL EQUATIONS 11 Hrs. Solution of Algebraic equation by Regula Falsi Method , Newton Raphson Method - Solution of simultaneous linear algebraic equations - Gauss Elimination Method , Gauss Jacobi & Gauss Seidel Method.

UNIT 4 INTERPOLATION , NUMERICAL DIFFERENTATION & INTEGRATION 11 Hrs. Interpolation- Newton forward and backward interpolation formula- Lagranges formula for unequal intervals- Numerical differentiation- Newton’s forward and backward differences to compute first and second derivatives- Numerical integration - Trapezoidal rule - Simpson’s one third rule and three eighth rule.

UNIT 5 NUMERICAL SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS AND PARTIAL DIFFERENTIAL EQUATIONS 12 Hrs.

Ordinary differential equations - Taylor series method - Runge Kutta method for fourth order- PARTial differential equations - Finite differences - Laplace equation and its solutions by Liebmann’s process- Solution of Poisson equation - Solutions of parabolic equations by Bender Schmidt Method - Solution of hyperbolic equations.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Kreyszig, E., Advanced Engineering Mathematics, (8th Edition), John Wiley and Sons (Asia)Pte Ltd., Singapore, 2001. 2. Grewal,B.S., Higher Engineering Mathematics, Tata Mcgraw Hill Publishing Co., New Delhi, 1999. 3. Kandasamy, P., Thilagavathy, K., and Gunavathy, K., Engineering Mathematics, (4th Revised Edition), S.Chand&Co., New

Delhi, 2001. 4. Veerarajan,T., Engineering Mathematics, Tata Mcgraw Hill Publishing Co., NewDelhi, 1999


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SCH1206 MASS TRANSFER - I L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE To impart the knowledge on fundamentals of mass transfer principles, concept of mass transfer coefficients and

basic mass transfer operations.

UNIT 1 DIFFUSION 12 Hrs. Molecular and Eddy diffusion in gases and liquids, Measurement and calculation of diffusivity, Equimolar and Unicomponent diffusion in gases and liquids, Diffusion in Multicomponent gaseous mixtures, Wilke Lee correlation Diffusion in solids and its applications - Steady state diffusion under stagnant and laminar flow conditions.

UNIT 2 MASS TRANSFER CO-EFFICIENTS 12 Hrs. Concept of mass transfer co-efficient,Mass transfer under laminar and turbulent flow past the solids, Boundary layers, Introduction to convective mass transfer, Correlation of mass transfer co-efficient, Analogies between momentum, heat and mass transfer, Reynolds, Prandtl, Von karman, Chilton and colburn analogy, Theories of mass transfer and their application, Interphase and overall mass transfer co-efficient in binary systems.

UNIT 3 DISTILLATION 12 Hrs. Vapor liquid equilibria, Raoult’s law and deviations from ideality, Methods of distillation - Batch, Continuous, Flash, Vacuum,Azeotropic, Extractive and Molecular distillation. Design method - McCabe Thiele method, Ponchon Savarit method, Fenske equation, Introduction to multi-component distillation.

UNIT 4 ABSORPTION 12 Hrs. Equilibrium and operating line concept in absorption calculations, Calculation of NTU, HTU, Number of stages, Packed and plate type absorbers. Absorption with chemical reaction, HETP Operating characteristics of stage wise and differential contactors. Absorption equipment - Packed and Plate towers, Centrifugal Absorbers and spray towers.

UNIT 5 MEMBRANE SEPARATION PROCESS 12 Hrs. Solid and liquid membranes, Membrane fouling, Concept of Osmosis, reverse osmosis, Dialysis, Electrodialysis, Ultrafiltration, Microfiltration, Nanofiltration, Pervaporation, Thermal and Sweep diffusion process, Ion Exchange, Zone Refining, Industrial application of membrane process.

Max. 60 Hours.

TEXT / REFERENCE BOOKS 1. Treybal, R.E, Mass Transfer Operations, 3rd Edition, McGraw Hill, 2004. 2. McCabe and Smith, Unit Operations of Chemical Engineering, 7th Edition, McGraw Hill, 2009 3. Coulson J.M. and Richardson J.F., Chemical Engineering, Vol - II, 6th Edition, Pergamon Press, 2002. 4. Sherwood T.K., Pigford R.L. and Wilke C.R., Mass Transfer, 2nd Edition, McGraw Hill, 1960.


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SCH1207 CHEMICAL ENGINEERING THERMODYNAMICS - II


COURSE OBJECTIVE This course helps the students to be proficient in applying thermodynamic principles to various chemical

engineering processes involving energy flow, phase and reaction equilibrium

UNIT 1 PROPERTIES OF SOLUTIONS 12 Hrs. Introduction to ideal and non-ideal solutions, Partial molar properties, chemical potential, effect of temperature and pressure on chemical potential, fugacity and fugacity coefficient in solution and ideal solution , Lewis Randell rule , Raoult’s law Henry’s law , activity and activity coefficients in solutions ,effect of temperature and pressure on activity coefficients , Gibbs Duhem equations, applications ,property changes on mixing ,heat effects of mixing processes , enthalpy composition diagrams, excess properties , relation between excess Gibbs free energy and activity coefficient , standard states definition and choice.

UNIT 2 PHASE EQUILIBRIA 12 Hrs. Criteria for equilibrium between phases in single and multi component non-reacting systems in terms of chemical potential and fugacity, phase rule & its application, Duhem’s theorem, vapour-liquid equilibrium, phase diagrams for homogeneous systems and for systems with a miscibility gap, VLE in ideal solutions ,non-ideal solutions , positive and negative deviation , azeotropes, effect of temperature and pressure on azeotrope composition, Pxy and Txy diagrams.

UNIT 3 CORRELATION AND PREDICTION OF PHASE EQUILIBRIA 12 Hrs. Simple models for VLE , VLE at low pressures , Wohl‟s equation ,Van Laar equation ,Wilson equation, application of activity coefficient equations in equilibrium calculations , basic idea on NRTL, UNIQUAC and UNIFAC , Dewpoint and bubblepoint calculations with Raoult’s law for binary mixtures, Henry’s law, VLE by modified Raoult’s law, VLE from K-value Correlations.

UNIT 4 APPLICATION OF PHASE EQUILIBRIA 12 Hrs. Excess Gibbs free energy model, thermodynamic consistency of phase equilibria, application of the correlation and prediction of phase equilibria in distillation process. Liquid-liquid equilibrium , binary and ternary equilibrium diagrams ,use of triangular diagrams for ternary equilibrium ,Different types of ternary systems and their representation on triangular coordinates. Introduction to VLLE, solid vapor equilibrium, solid liquid equilibrium.

UNIT 5 CHEMICAL REACTION EQUILIBRIA 12 Hrs. Chemical reaction equilibria ,reaction stoichiometry , criteria of chemical equilibrium , equilibrium constant ,standard free energy change , standard state , feasibility of reaction ,effect of temperature on equilibrium constant , presentation of free energy data,Giauque Functions , evaluation of K , equilibrium conversion in gas phase reactions ,effect of pressure on equilibrium constant,effect of pressure, Inert materials, excess of reactants & products on equilibrium composition. phase-rule for reacting systems

Max.60 Hours

TEXT / REFERENCE BOOKS 1. Smith, J.M., and Van Ness, H.C., Introduction to Chemical Engineering Thermodynamics, 6th Edition Mc-Graw-Hill, 2004. 2. Narayanan K.V ,A Text Book of Chemical Engineering Thermodynamics, 3rd Edition Prentice Hall of India Pvt. Ltd. 2001. 3. Hougen, O.A., Watson, K.M., and Ragatz, R.A.,Chemical Process Principles PART II, Thermodynamics, 3rd Edition John

Wiley 1970. 4. Gopinath Halder., Introduction to Chemical Engineering Thermodynamics, 2nd Edition, PHI Learning Private Limited, 2009. 5. Rao Y.V.C., Chemical Engineering Thermodynamics, 3rd Edition, University Press (I) Ltd., Hyderabad, 1997.


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SCH1208 CHEMICAL REACTION ENGINEERING -I L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE To impart knowledge on the kinetics of isothermal and non-isothermal reactions for simple and multiple reactors

UNIT 1 INTREPRETATION OF REACTOR DATA 12 Hrs. Classification of reactions, reaction rate, rate constant, order, molecularity, concentration dependent term of rate equation, temperature dependent term of rate equation, arrhenius theory, collision theory ,transition state theory, kinetics of non-elementary reactions, integral and differential methods for finding order of reaction, half life period, constant volume and variable volume reaction. reversible reactions ,autocatalytic reaction.

UNIT 2 DESIGN OF SINGLE IDEAL REACTORS 12 Hrs. Material balance , Energy balance , batch operation, continuous operation , semi-batch operation, ideal conditions, design of ideal batch reactor, ideal plug flow reactor, ideal mixed flow reactor, semi-batch reactor ,recycle reactor.

UNIT 3 DESIGN OF MULTIPLE REACTOR SYSTEMS 12 Hrs. Mixed flow reactors in series and parallel connection , Plug flow reactors in series and parallel connection , reactors of different types in series ,size comparison of reactors using performance charts

UNIT 4 MULTIPLE REACTIONS 12 Hrs. Series reactions , parallel reactions , series-parallel reactions , qualitative discussion about product distribution in mixed flow reactor and plug flow reactor, quantitative treatment of product distribution in mixed flow reactor and plug flow reactor, overall fractional yield ,instantaneous fractional yield, selectivity.

UNIT 5 NON-ISOTHERMAL REACTIONS 12 Hrs. Heat of reaction, equilibrium constants from thermodynamics, equilibrium conversion ,temperature effects on chemical reaction rates, optimum temperature progression , size of reactor. design procedures for adiabatic and non-isothermal operation of batch and flow reactors, reactor stability, exothermic reactions in mixed flow reactors.

Max.60 Hours

TEXT / REFERENCE BOOKS 1. Levenspiel, O., Chemical Reaction Engineering, 3rd Edition, John Wiley & Sons, New York,1995. 2. Fogler, H.S., Elements of Chemical Reaction Engineering, 4th Edition, Prentice-Hall of India Pvt. Ltd,1995. 3. Smith, J.M. Chemical Engineering Kinetics, 2nd Edition, McGraw-Hill Book Company, New York,1981.


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SCH1209 BIOCHEMICAL ENGINEERING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To introduce the key aspects of biochemical processes and to enable the implementation of these principles in

related industries UNIT 1 BATCH AND CONTINUOUS CULTURES 9 Hrs.

Batch and Continuous Cultures,Growth Rate: Kinetics of Cell Growth,Measurement of Cell Growth,Effects of Environment on Cell Growth,Temperature,pH,Oxygen, Oxygen Uptake Rate (OUR), Medium requirements for fermentation processes- Carbon, nitrogen, minerals, vitamins and other complex nutrients; Medium formulation for optimal growth and product formation- examples of simple and complex media; Design of commercial media for industrial fermentations, medium optimization methods.

UNIT 2 MICROBIAL GROWTH 9 Hrs. Microbial Growth, Phases of cell growth in batch cultures, Microbial Growth Kinetics, The Stoichiometry of Microbial Reactions,Medium Formulation and Yield Factors,Material Balance of Cell Growth,Degree of Reduction, Fed Batch Culture,Fed-Batch Model Formulation, Comparison Between Fed-Batch and Continuous Bioreactors, Advantages of Fed-Batch System, Application of Fed-Batch System

UNIT 3 MIXING AND MASS TRANSFER 9 Hrs. Mixing and Mass Transfer, Macro-mixing, Micro-mixing, Methods for Characterizing Mixing, Oxygen Transfer,Gas-Liquid Mass Transfer,Oxygen Transfer Rate,Oxygen Consumption in Cell Growth, Factors Affecting Cellular Oxygen Demand, Measurement of kla in Continuous-Stirred-Tank Bioreactor and Airlift Bioreactor, Continuous-Stirred-Tank Bioreactor, Airlift Bioreactor, Liquid Mixing, Types of Mixing and Stirrers Types of Flows in Agitated Tanks, The Mechanism of Mixing Power Requirement for Mixing, Un-gassed Newtonian Fluids, Un-gassed non-Newtonian Fluids, Gassed Fluids.

UNIT 4 BIOCHEMICAL KINETICS 9 Hrs. Kinetics of Substrate Utilisation, Product Formation and Biomass Production in Cell Cultures, The kinetics of substrate consumption in cellular growth and enzyme-catalysed reaction and their relationship with bioreactor modelling,Unstructured Batch Growth Models,Structured Kinetic Models,Compartmental models,Metabolic models,Product Formation Kinetics, Unstructured model ,structured product formation,kinetic modelling, Microbial and enzyme kinetic models and their applications in bioreactor design, Sterilization, Introduction, Applications, Heat Sterilization.

UNIT 5 BIOREACTOR DESIGN 9 Hrs. Bioreactor Design,Downstream Processing in Biochemical Engineering, Introduction to downstream processing, Cell disruption methods for intracellular products, removal of insolubles, biomass separation techniques; flocculation and sedimentation, centrifugation and filtration methods, Solid-Liquid Separation, Filtration/Ultrafiltration, Centrifugation, Liquid-liquid Extraction, Cell Rupture/Disruption, Product Recovery,Purification, Solvent recovery, Drying, Crystallisation

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Pauline Doran, Bioprocess engineering principles, 1st Edition, Academic Press, 1995. 2. Michael Shuler and FikretKargi, Bioprocess Engineering: Basic Concepts, 2nd Edition, Prentice Hall, Englewood Cliffs, NJ,

2002. 3. Bailey J.E and Ollis D.F, Biochemical Engineering Fundamentals, 2nd Edition, Mc-Graw Hill, Inc., 1986. 4. Stanbury P.E., Whitaker A., Hall S.J, Principles of Fermentation Technology, 2nd Edition, Pergamon Press, 1995. 5. Harvey W. Blanch, Douglas S. Clark, Biochemical Engineering, 2nd Edition, Marcel Dekker, Inc, 1997.


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SCH1210 HEAT TRANSFER L T P Credits Total Marks 3 0 0 3 100

COURSE.OBJECTIVE To provide an adequate knowledge on different modes of heat transfer and their applications in process

industries UNIT 1 INTRODUCTION TO MODES OF HEAT TRANSFER 9 Hrs Basic Considerations: Importance of heat transfer in Chemical Engineering operations. Modes of heat transfer. Mean temperature difference. Conduction: Concept of heat conduction. Fourier’s law of heat conduction. One-dimensional steady state heat conduction equation for flat plate, hollow cylinder and hollow sphere. Heat conduction through a series of resistances. Critical thickness of insulation, Analogy between flow of heat and flow of electricity. Thermal conductivity,Conduction through liquids. Conduction through extended surfaces.

UNIT 2 CONVECTIVE HEAT TRANSFER PROCESSES 9 Hrs. Film Coefficients and their applications: Individual and overall heat transfer coefficients and relationship between them. Transient heat conduction. Convection: Concept of heat transfer by convection. Natural and forced convection. Applications of dimensional analysis for convection. Derivation of equations for forced convection under laminar, transition and turbulent conditions. Equations for natural convections. Heat transfer from condensing vapors. Heat transfer to boiling liquids. Influence of boundary layer on heat transfer. Heat transfer to molten metals. Heat transfer in packed and fluidized beds.

UNIT 3 HEAT EXCHANGERS 9 Hrs. Parallel and counter flow heat exchangers. Log mean temperature difference. Single pass and multi pass heat exchangers. Plate heat exchangers. Use of correction factor charts. Heat exchanger effectiveness and its use. Number of transfer units charts for different configurations. Fouling factor and Wilson’s plot. Various types of heat exchangers. Heat exchanger design. Design of condensers. Effect of non-condensable.

UNIT 4 RADIATION 9 Hrs. Concept of thermal radiation. Concept of black and gray bodies. Stefan-Boltzmann law. Kirchoff’s law. Radiation between surfaces. Radiation from gases. Clouds of particles and luminous flames. Radiation error in temperature measurement. Radiation from shields. Radiation shape factor and relations between shape factor. Radiation network for absorbing and transmitting medium.

UNIT 5 EVAPORATION 9 Hrs. Introduction. Types of evaporators. Single and multiple effect evaporation. Capacity and economy of multi effect evaporators. Thermo re-compression evaporators Vapour re-compression and thermal re-compression evaporators, Effect of liquid head and boiling point elevation. Duhring’s rule. Liquid characteristics. Material and energy balance in evaporators. Illustrated examples.

Max.45 Hours.

TEXT / REFERENCE BOOKS 1. McCabe M.L. and Smith J.C., Unit Operations in Chemical Engineering, 7th Edition, McGraw Hill, 2009. 2. Donald Q. Kern, Processes Heat Transfer, 4th Edition, Tata McGraw Hill, 1997. 3. McAdams W.H., Heat Transmission, 2nd Edition, McGraw Hill, 1954. 4. Holman J.P., Heat Transfer, 6th Edition, McGraw Hill and Kogakusha, 1997. 5. Necati Ozisik M., Basic Heat Transfer, 2th Edition, McGraw Hill and Kogakusha, 1977.


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SCH4053 FLUID MECHANICS LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Flow through Venturimeter 2. Flow through Orifice meter 3. Flow through Pitot tube 4. Characteristics of a Reciprocating pump 5. Characteristics of a Centrifugal pump 6. Characteristics of a Gear pump 7. Flow through packed bed 8. Flow through Fluidization 9. Flow through helical coil 10. Flow through V- Notches 11. Flow through annular pipe/ non circular conduits

SCH4054 MECHANICAL OPERATIONS LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Particle size distribution - differential and cumulative analysis by manual method using standard screens 2. Determination of Screen Effectiveness by Mechanical Method using Standard screens 3. Energy requirement and crushing constants determination using:

i. Ball mill ii. Drop weight crusher

4. Determination of filtration constants at constant pressure conditions using: i. Plate and Frame Press ii. Vacuum Leaf Filter

5. Minimum thickener area calculations performing Batch Sedimentation test 6. Calculation of Angle of nip – Roll Crusher

SCH4055 PROCESS DYNAMICS AND CONTROL LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Simulation of proportional controller using Matlab 2. Step Response of first order system with and without delay using Matlab 3. Step Response of second order system with and without Delay using Matlab 4. Simulation of Ziegler Nicholas Method of controller tuning using Matlab. 5. Simulation of Cascade control loop Using Matlab 6. Step response of interacting level system 7. Step response of Non-interacting level system 8. Characteristics of ON-OFF Controller in Thermal Process 9. Characteristics of control valve ( Actuated and Flow Lift characteristics) 10. Characteristics of I/P Converter 11. Characteristics of P/I Converter 12. Study and control of a Level process using ON-Off, P, PI, PD and PID controllers 13. Study and control of a Pressure process using ON-Off, P, PI, PD and PID controllers 14. Study and control of a Flow process using ON-Off, P, PI, PD and PID controllers

SCH4056 HEAT TRANSFER LAB L T P Credits Total Marks

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SCH1301 COMPUTATIONAL METHODS IN CHEMICAL ENGINEERING


COURSE OBJECTIVE To impart computational techniques for chemical engineering calculations

UNIT 1 BASICS OF MATLAB 12 Hrs. Starting MATLAB,Help, Simple, Functions, Output, Algebra Vectors, Graphs, Interrupting, Syntax, Suppressing Output, Defining Matrices, Size of Matrix, The Identity Matrix, Specialized Matrices ,Diagonal Matrices, The ,Manipulating Matrices, Matrices, matrix Multiplication, String Arrays, Printing Output,MATLAB Scripting Language: M-File MATLAB Search Path, Path Management, and Startup ,File, Function, Errors.

UNIT 2 FORMULATION OF PHYSICAL PROBLEMS 12 Hrs. Mathematical statement of the problem, Representation of problems, Formulation on extraction in single & multiple stages, Radial heat transfer through a cylindrical conductor, salt accumulation in stirred tank.

UNIT 3 INITIAL VALUE PROBLEMS 12 Hrs. Initial value problems for ordinary differential equations-Euler’s method, Trapeziodal method, Runge Kutta methods for second and fourth order , interpolation, Newton-cotes integration, Gaussian quadrature.

UNIT 4 NUMERICAL OPTIMIZATION AND PARAMETER ESTIMATION TECHNIQUES 12 Hrs. Methods for constrained and unconstrained optimization- Lagrangian methods, Simplex, Newton line search method, Trust region Newton method, Single response linear regression, least square regression, Applications- Fitting a kinetic rate law to time dependent data.

UNIT 5 BOUNDARY VALUE PROBLEMS 12 Hrs. Introduction to boundary value problems, shooting method, finite difference method, finite volume method, finite element method. Applications of BVP-Chemical reaction and diffusion in a spherical catalyst, finite differences for a convection, diffusion equation.

Max.60 Hours

TEXT / REFERENCE BOOKS 1. Beers K.J., Numerical Methods for Chemical Engineering: Appplications in MATLAB, 1st Edition, Cambridge University Press

,2007. 2. Jain M.K., Iyengar S.R.K., Jain R.K.,Numerical methods: Problems and solutions, 4th Edition, New age international

publishers, 2003. 3. Davis. M.E.,Numerical Methods and Modeling for Chemical Engineers, 1st Edition, John Wiley &Sons, 1984. 4. Loney N.W.,Applied mathematical models for chemical Engineers, 2nd Edition, CRC press, 2006. 5. Mickley, Reid and Sherwood, Applied Mathematics in Chemical Engineering, 2nd Edition, Tata-McGraw-Hill, New Delhi,1978


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http://accessengineeringlibrary.com/browse/matlab-numerical-methods-with-chemical-engineering-applications/c9780071831284ch01









SCH1302 MASS TRANSFER - II L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To study LLE, principles of adsorption and concept of separation.

UNIT 1 HUMIDIFICATION 9 Hrs. Humidification Theory, Basic concepts, Dry bulb temperature, Relative saturation,Percentage saturation, Dew point, Humid volume, Humid heat, Enthalpy, Adiabatic saturation curves, wet bulb temperature, Psychometric Chart, Adiabatic Saturator, Wet Bulb Theory, Methods of Humidification and dehumidification, Cooling tower theory, Design of cooling towers, Industrial cooling towers, Cooling towers principle and operation, equipments.

UNIT 2 DRYING 9 Hrs. Drying Theory and Mechanism, Drying Characteristics, Estimation of Drying time, Equilibrium moisture content of materials. Bound and unbound moisture. Free and equilibrium moisture., Rate of Drying curves, Calculation methods for constant rate drying period and falling rate drying period, Classification of Driers, Through circulation driers design, Design of driers, Design and performance of Batch and Continuous Dryers,Application of Driers, Equipments for drying,Tray dryer, Vacuum-shelf indirect dryers, continuous tunnel dryers, rotary dryers, drum and spray dryers.

UNIT 3 CRYSTALLIZATION 9 Hrs. Crystallization Theory, Solubility curve, Types of crystals, Principles of Crystallization, Supersaturation Theory, Factors governing nucleation and crystal growth. Theory of crystallization, Classification of crystallizers and their applications.Industrial crystallizers, Crystallizer Design.

UNIT 4 ADSORPTION 9 Hrs. Introduction to adsorption, adsorbents and adsorption processes, Types of adsorption, Nature of adsorbents, Theories of adsorption- Freundlich, Langmuir, BET theories, Adsorption isotherms, Operation of adsorption columns, Break through curve, Batch and continuous operations, Multistage cross and counter current operations, Equipments - fixed-bed adsorbers, moving bed adsorbers, pressure swing adsorber and thermal swing adsorbers.

UNIT 5 EXTRACTION LEACHING 9 Hrs. Equilibrium in ternary systems, Stage wise contact equipments, Calculations for batch and continuous extractors, Multistage Cross current extraction, Multistage counter current extraction, Calculation of number of stages, Equipments - Mixer settlers, Plate column, Packed column, Pulse column & RDC General principles of leaching, Constant and variable underflow, Multistage crosscurrent and counter current leaching, working principle of leaching equipments: Bollman extractor, Rotocel extractor, Thickeners, Continuous counter current decantation (CCD), Industrial application of Leaching process.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Treybal, R.E, Mass Transfer Operations, 3rd Edition, McGraw Hill, 2004. 2. McCabe and Smith, Unit Operations of Chemical Engineering, 7th Edition, McGraw Hill, 2009. 3. Coulson J.M. and Richardson J.F., Chemical Engineering, Vol. II, Pergamon Press. 2002. 4. Gavhane K. V., Mass Transfer II, 11th Edition, Nirali Prakashan, 2011. 5. Anantharaman N., Meera Sheriffa Begum K. M., Mass Transfer Theory and Practice, 1st Edition, PHI, 2011.


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http://www.amazon.in/s/280-2942473-3501445?_encoding=UTF8&field-author=Anantharaman%20N.&search-alias=stripbooks

http://www.amazon.in/s/280-2942473-3501445?_encoding=UTF8&field-author=Begum%20K.%20M.%20Meera%20Sheriffa&search-alias=stripbooks



SCH1303 CHEMICAL REACTION ENGINEERING - II L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE To familiarize the methods of accounting non-ideal behavior of ideal reactors, design of heterogeneous reactors

for solid catalyzed reactions and non-catalytic fluid-particle reactions.

UNIT 1 NON - IDEAL REACTOR 12 Hrs. Non-ideal reactors, Reasons for non-ideal flow behaviors, Concept of mixing: micro and macro mixing, Residence Time Distribution (RTD) functions, C, E and F curves, calculation of mean residence time from E and F curves, Tanks in series models, Axial dispersion model, segregated flow model, Conversion in non-ideal reactors.

UNIT 2 NON-CATALYTIC REACTIONS 12 Hrs. Fluid-solid noncatalytic reactions: Progressive Conversion Model, Unreacted or Shrinking Core Model, Determination of the rate controlling step, Conversion in reactors with constant fluid composition, Conversion in reactors with variable fluid composition.

UNIT 3 CATALYST AND CATALYTIC REACTIONS 12 Hrs. Introduction to catalysis, Physical properties of catalyst: Surface area (BET isotherm), Void volume and solid density, Pore volume distribution; Catalyst preparation, Promoters, Inhibitors and Poisons, Steps in a catalytic reaction, rate of catalytic reaction (adsorption, surface reaction and desorption as rate limiting steps).

UNIT 4 CATALYTIC REACTORS 12 Hrs. The rate equation for Surface Kinetics, Pore diffusion resistance combined with Surface Kinetics, Effectiveness factor, Thiele modulus, Heat effects during reaction, Performance equations for Reactors containing porous catalyst particles, Experimental methods for finding rates.

UNIT 5 INDUSTRIAL REACTORS & CATALYST DEACTIVATION 12 Hrs. Heterogeneous catalytic reactors: Fixed bed reactors, Fluidized bed reactors, Slurry reactors, Trickle bed reactors: Design aspects with some simple examples. Deactivation of catalyst, Mechanism of deactivation of catalyst, Rate and performance study of deactivation.

Max.60 Hours

TEXT / REFERENCE BOOKS 1. Octave Levenspiel, Chemical Reaction Engineering, 3rd Edition, Wiley Publications Ltd., 2007. 2. Smith. J.M., Chemical Engineering Kinetics, 3rd Edition, McGraw Hill, 1981. 3. Gavhane. K. A,. Chemical Reaction Engineering - II, 2nd Edition, Nirali Prakashan, 2013. 4. Fogler.H.S., Elements of Chemical Reaction Engineering, 3rd Edition, Prentice Hall of India Ltd., 2001. 5. Froment. G.F and Bischoff.K.B.,Chemical Reactor Analysis and Design, 2nd Edition, John Wiley and Sons, 1979.


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SCH1304 CHEMICAL PROCESS TECHNOLOGY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To improve knowledge on the chemical processes along with emphasis on technological development

UNIT 1 INTRODUCTION - CHLORO ALKALI INDUSTRIES 9 Hrs. Introduction - Basic principles of unit operations and unit process to common devices used in manufacturing processes like Reactors, Steam jet ejectors, Pumps, Thickeners, Dryers, Electrostatic precipitators, Condenser, Vacuum evaporator in block diagram - Standard symbols used for such devices, Process flow sheet. Manufacturing of soda ash, caustic soda and chlorine - manufacture of bleaching powder.

UNIT 2 SULPHUR, SULPHURIC ACID AND SILICATE INDUSTRIES 9 Hrs. Mining and manufacture of sulphur, recovery of sulphur from polluting gases, sulphur trioxide and sulphuric acid, hydrochloric acid, sodium sulphate, sodium thiosulphate. Manufacture of Portland cement, Manufacture of Glasses and Special glasses.

UNIT 3 INDUSTRIAL GASES AND PAINTS 9Hrs. Manufacture of Carbon dioxide ,Hydrogen , Oxygen, Nitrogen, Acetylene , Water Gas, Producer Gas,Production of Natural Gas. Introduction of Paints, Pigments, Emulsions and Varnishes ,Manufacture of Paints ,Manufacture of White and Coloured Pigments.

UNIT 4 NATURAL PRODUCTS 9 Hrs. Edible and essential oils, soaps and detergents, glycerin, pulp and paper, starch and its derivatives, Manufacturing of sugar.

UNIT 5 SYNTHETIC ORGANIC CHEMICALS 9 Hrs. Methane and synthesis gas, ethylene, acetylene and propylene. Aromatic chemicals - Benzene, toluene, and xylene. Production of thermo- plastic and thermo-setting resins: polyethylene, polypropylene, and Polyvinylchloride, Polymers and their engineering applications. Polyamides and polyesters and processes for the production of natural and synthetic rubber.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Gopala Rao M. and Marshall Sittig., Dryden’s Outlines of Chemical Technology, 3rd Edition., East-West Press, New Delhi,

1997. 2. Shreve. N., Chemical Process Industries, 8th Edition, McGraw Hill, 2004. 3. Mark. W.V, S.C. Bhatia.,Chemical Process Industries volume I and II, 2nd Edition, East-West Press, 2007. 4. Badger and Banchero., Introduction to Chemical Engineering, 2nd Edition , McGraw Hill, 2001, 5. Jacob A. Moulijn, Michiel Makkee, Annelies E.Van Diepen, Chemical process technology,2nd Edition, Wiley India, 2013.


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SCH1305 INSTRUMENTATION AND PROCESS CONTROL


COURSE OBJECTIVE This course enables the students to know about control methods and make the students knowledgeable in

various types of measuring instruments used in chemical process industries.

UNIT 1 INSTRUMENTATION 9 Hrs. Temperature measurement: Thermocouples, Resistance thermometers, Optical and Radiation pyrometers. Pressure measurement: Use of manometers, Bourdon gauge, Bellows type gauge. Flow measurement: Variable area meters. Positive displacement type meters. Liquid level measurement: Direct and differential method, measurement in open and pressure vessels. Measurement of Viscosity, Conductivity, Humidity of gases and pH.

UNIT 2 BASIC CONCEPTS OF PROCESS CONTROL 9 Hrs. Laplace transformation and its application in process control. Response of first order systems Examples of first order systems Process Dynamics of linear open systems. Second order and first order systems in series higher order systems Transfer Function Step, Ramp, Pulse and Sinusoidal inputs and Linearization

UNIT 3 LINEAR CLOSED LOOP SYSTEMS 9 Hrs. Development of a block diagram, Controllers and Final control element Closed loop control systems. Block Diagram for feedback control systems, Servo and Regulator problems. Principles of Pneumatic and Electronic controllers. Transportation Lag Transient response of closed loop control systems, Control valve PI, P, PID control.

UNIT 4 STABILITY ANALYSIS 9 Hrs. Stability, Stability criterion Routh test for stability ; Routh-Hurwitz criterion, Root-Locus analysis. Introduction to frequency response of closed-loop systems, Frequency response Substitution rule Bode diagrams Bode stability criterion. Gain and Phase margins Ziegler Nichols control settings and Transient response Nyquist diagram.

UNIT 5 CONTROL VALVES & ADVANCED CONTROL SYSTEMS 9 Hrs. Control valves, Valve sizing Characteristics Control valve construction, Valve positioning Power unit Transducers Electric to Pneumatic and pneumatic to electric types Transfer function matrix Dead time compensation. Introduction to advanced control systems, Cascade control, Feed forward control and Feedback control.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Coughanowr D.R and Koppel L.M.,Process Systems Analysis and Control, 3rd Edition,McGraw Hill,NewYork,1991. 2. Harriot P., Process Control, 3rd Edition, Tata McGraw Hill, New Delhi, 2008. 3. Eckman D.P., Industrial Instrumentation, 2nd Edition, Wiley Eastern Ltd, 1996. 4. George stephanopolus., Chemical Process Control, 2nd Edition, Prentice Hall of india Pvt. Ltd 1910. 5. Vyas.R.P., Process control and instrumentation, 2nd Edition, Central Techno Publications, Nagpur 2005.


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SCH1306 PROCESS ENGINEERING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide an adequate knowledge on process engineering and their applications in process industries

UNIT 1 INTRODUCTION 9 Hrs. Scales of Production, Selection of Plant Capacity, Plant Location. Availability of Raw Materials, Energy Gestation Period. Expansion, Diversification and Obsolescence. Scope for Standardization in Design and Production. Economics of Research and Development. Indian Chemical Industry, Current Status and Trends.

UNIT 2 PROCESS CREATION 9 Hrs. Preliminary database creation, Preliminary process synthesis, Development of base case design, Generalization of the Resolution Based Synthesis procedure for development of flow sheet for a chemical plant. Principles of steady state flow sheet, simulation, Principles of batch process simulation

UNIT 3 HEURISTICS FOR PROCESS SYNTHESIS 9 Hrs. Raw materials and Chemical reactions, Distribution of chemicals, Separations, Heat removal from and addition to reactors, Heat exchangers and furnaces, Pumping, Compression, Pressure reduction, Vacuum, and Conveying of solids

UNIT 4 SYNTHESIS OF SEPARATION TRAINS 9 Hrs. Feed separation systems, Phase separation of reactor effluent, Industrial separation operations, Criteria for selection of separation methods, Selection of equipment, Sequencing of ordinary distillation columns for the separation of nearly ideal fluid mixtures, Sequencing of operations for the separation of nonideal fluid mixtures, Separation systems for gas mixtures, Separation sequencing for solid-fluid systems.

UNIT 5 SCALING UP PROCESS 9 Hrs. Scaling up of process from laboratory to pilot plant and to industrial scale. Process Evaluation: Batch Versus Continuous, Equilibrium Limitations, Process alternatives, Preparation of study report.

Max.45 Hours.

TEXT / REFERENCE BOOKS 1. Vogel.G.H .,Process Development - From the Initial Ideal to the Chemical Production Plant, 2nd Edition,Wiley- VCH Verlag

GmbH, 2005. 2. Douglas. J. M., Conceptual Design of Chemical Process,3rd Edition Mc Graw Hill Book Company. 1998. 3. Jordan ,Chemical Process Development,2nd Edition, Mc-Graw Hill,1996 4. Seider W.D, Seader J.D, and Lewin D.R., Product and Process Design Principles-Synthesis, Analysis and Evaluation, 2nd

Edition, John Wiley and Sons. 2004. 5. Turton. R , Bailie R.C, Whiting W. B, Shaeiwitz J.A.,Analysis, Synthesi and Design of Chemical Processes,3rd

Edition,Prentice Hall, New Jursey. 1998.


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SCH4053 FLUID MECHANICS LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Flow through Venturimeter 2. Flow through Orifice meter 3. Flow through Pitot tube 4. Characteristics of a Reciprocating pump 5. Characteristics of a Centrifugal pump 6. Characteristics of a Gear pump 7. Flow through packed bed 8. Flow through Fluidization 9. Flow through helical coil 10. Flow through V- Notches 11. Flow through annular pipe/ non circular conduits

SCH4054 MECHANICAL OPERATIONS LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Particle size distribution - differential and cumulative analysis by manual method using standard screens 2. Determination of Screen Effectiveness by Mechanical Method using Standard screens 3. Energy requirement and crushing constants determination using:

i. Ball mill ii. Drop weight crusher

4. Determination of filtration constants at constant pressure conditions using: i. Plate and Frame Press ii. Vacuum Leaf Filter

5. Minimum thickener area calculations performing Batch Sedimentation test 6. Calculation of Angle of nip – Roll Crusher

SCH4055 PROCESS DYNAMICS AND CONTROL LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Simulation of proportional controller using Matlab 2. Step Response of first order system with and without delay using Matlab 3. Step Response of second order system with and without Delay using Matlab 4. Simulation of Ziegler Nicholas Method of controller tuning using Matlab. 5. Simulation of Cascade control loop Using Matlab 6. Step response of interacting level system 7. Step response of Non-interacting level system 8. Characteristics of ON-OFF Controller in Thermal Process 9. Characteristics of control valve ( Actuated and Flow Lift characteristics) 10. Characteristics of I/P Converter 11. Characteristics of P/I Converter 12. Study and control of a Level process using ON-Off, P, PI, PD and PID controllers 13. Study and control of a Pressure process using ON-Off, P, PI, PD and PID controllers 14. Study and control of a Flow process using ON-Off, P, PI, PD and PID controllers

SCH4056 HEAT TRANSFER LAB L T P Credits Total Marks

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SCH1307 PROCESS EQUIPMENT DESIGN L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE To Enable the students to learn the methods and practices followed in the design of process equipments

UNIT 1 DESIGN BASICS 12 Hrs. Design of Plant Layout, Schematics and Presentation, Standards, Materials of Construction and Selection of process equipment. Supports for vessels-Bracket support, Leg Support, Skirt support, Saddle support.

UNIT 2 DESIGN OF HEAT TRANSFER EQUIPMENTS 12 Hrs. Heat Exchangers-Shell and Tube heat exchangers, Condensers, Reboilers-Kettle type, Evaporators-Single effect evaporator-Area calculation.

UNIT 3 DESIGN OF MASS TRANSFER EQUIPMENT 12 Hrs. Distillation Column- Plate type distillation column, Calculation of number of trays and diameter of column, Absorption column- Calculation of NTU and HTU for height determination.

UNIT 4 DESIGN OF PRESSURE VESSELS AND STORAGE TANKS 12 Hrs. Pressure vessels-High pressure vessel-Stress in high pressure vessels-Vessel closures- Design of Storage vessels-Types-Design of spherical and Rectangular tanks.

UNIT 5 DESIGN OF SEPARATION EQUIPMENT AND SAFTEY 12 Hrs. Filters-Rotary Vacuum filter design, Sedimentation-Thickeners, Cyclone Separators-High through put and High efficiency -Safety measures in Equipment design.

Max. 60 Hours.

TEXT / REFERENCE BOOKS 1. Sinnott, R. K.,Coulson & Richardson’s Chemical Engineering, Vol. 6, Butterworth Heinermann, Oxford, 1996. 2. Dawande, S. D., Process Design of Equiments,4th Edition, Central Techno Publications, Nagpur, 2005. 3. Mahajani, V.V. Umarji S.B.,Joshi’s Process equipment Design,4th Edition, Mac Millan,1988. 4. Perry, R. H.,Chemical EngineersHandbook, 6th Edition,McGraw Hill , New York, 1998. 5. Baranan, C.R., Rules of Thumb for Chemical Engineers, 4th Edition, Gulf Publishing Co, Texas,1996.


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SCH1308 PETROLEUM AND PETRO CHEMICAL TECHNOLOGY


COURSE OBJECTIVE The subject deals with the characterization, distillation, refining of petroleum crude and the petrochemicals

obtained by processing petroleum products.

UNIT 1 CLASSIFICATION OF CRUDE AND REFINING 9 Hrs. Theories on origin of petroleum, composition of crude oil, classification and evaluationn of crude oil, laboratory testing techniques of crude quality like flash point ,fire point etc., Refining of petroleum - atmospheric and vacuum distillation.

UNIT 2 THERMAL AND CATALYTIC PROCESSES 9 Hrs. Thermal cracking, catalytic cracking, catalytic reforming, Naphtha cracking, coking, Hydrogenation processes, Alkylation processes, Polymerization and Isomerization process.

UNIT 3 TREATMENT TECHNIQUES 9 Hrs. Treatment techniques for removal of objectionable gases and to improve performance, treatment of gasoline, treatment of kerosene, treatment of lubes. Extraction of aromatics and olefins,Recovery operations from petroleum products.

UNIT 4 CHEMICALS FROM METHANE AND ETHANE 9 Hrs. Production of Methanol, Formaldehyde, Ethylene glycol, PTFE, ammonia , Ethylene, Manufacture of Vinyl Chloride monomer, vinyl Acetate manufacture, Ethanol from Ethylene, Acetylene manufacture

UNIT 5 CHEMICALS FROM HIGHER ALKANES 9 Hrs. Cracking of naphtha and gas for the production of ethylene, propylene, isobutylene and butadiene., synthetic fibers .

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Nelson, W.L., Petroleum Refinery Engineering, 4th Edition., McGraw Hill, New York,1985 2. Bhaskara Rao B. K., Modern Petroleum Refining Processes, 2nd Edition., Oxford and IBH Publishing Company, New

Delhi,1989. 3. Hobson G. D and Pohl. W., Modern Petroleum Technology, 2nd Edition, Gulf Publishers,1986.


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SCH1309 TRANSPORT PHENOMENA L T P Credits Total Marks 3 1 0 4 100

COURSE.OBJECTIVE To provide the fundamentals for the application of basic laws of mass, momentum, and energy transport in

engineering analysis

UNIT 1 FUNDAMENTALS OF TRANSPORT PHENOMENA 12 Hrs. Introduction to transport phenomena - scope and importance, Newton’s law, Non-Newtonian fluids, models for Non Newtonian fluids, pressure and temperature dependence of viscosity, Shell Momentum balances, flow of falling film, flow through a circular tube, flow through an annulus, adjacent flow of two immiscible fluids, The equation of Continuity, The equation of Motion , use of the Equations of Change to set up steady flow problems

UNIT 2 TEMPERATURE DISTRIBUTION 12 Hrs. Fourier’s Law of Heat Conduction, Temperature Distribution in Solids and in Laminar Flow, Shell Energy Balances, Heat Conduction with an electrical heat source, heat conduction with a viscous heat source, heat conduction with a chemical heat source, heat conduction through composite walls, heat conduction in a cooling fin, forced and free convection.

UNIT 3 CONCENTRATION DISTRIBUTION 12 Hrs. Definitions of concentrations, velocities and mass fluxes, relationns among the molar fluxes, Fick’s law of Diffusion, Temperature and Pressure Dependence of Mass Diffusivity, Theory of ordinary diffusion in gases, theories of ordinary diffusion in liquids, Psuedo steady state diffusion, Shell mass balances, Diffusion through a stagnant gas film, Diffusion with heterogeneous chemical reaction, Diffusion with homogeneous chemical reaction, Diffusion and Chemical reaction inside a porous catalyst.

UNIT 4 FRICTION FACTORS AND MACROSCOPIC MOMENTUM BALANCE 12 Hrs. Definition of Friction factors, friction factors for flow through tubes and for flow around spheres, Determination of diameter of a falling sphere, Friction factors for packed columns, the macroscopic Mass, Momentum and Mechanical energy balances, use of Macroscopic balances to set up steady flow problems, Pressure rise and friction loss in a sudden expansion, performance of a liquid- liquid ejector, Isothermal flow of a liquid through an orifice.

UNIT 5 TRANSPORT IN TURBULENT AND ANALOGIES BETWEEN TRANSPORT PROCESSES 12 Hrs. Turbulence, Reynolds equation for incompressible turbulent flow, Reynolds stresses Prandtl’s mixing length theory, Eddy viscosity, the statistical theory of turbulence, Correlation coefficients, intensity and scale of turbulence. Turbulence measurement, Hot - wire anemometer. Turbulence flow in a closed conduit, Prandtl’s Power law of Velocity distribution in smooth and rough pipes. Analogy between Momentum, Heat and Mass transfer. The Reynolds’Analogy for turbulent flow over a flat plate, The Prandtl’s Analogy, The Von karmon Analogy, Coulburn analogy

Max.60 Hours

TEXT / REFERENCE BOOKS 1. Bird R.B., Stewart W.E. and Lightfoot E.N., Transport Phenomena, 2nd Edition, Wiley, New York, 2006, 2. Knudson J.G. and Katz D.L., Fluid Dynamics and Heat Transfer, 2nd Edition, McGraw Hill, New York, 2000. 3. Roy .S.C and C.Guha., Introduction to Transport Phenomena, 1st Edition, Dhanpat Rai & Co, 2008.


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SCH1310 ENVIRONMENTAL POLLUTION AND CONTROL L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the principles of various processes involved in the treatment of Industrial Pollutants such

as Air, Water and Solid

UNIT 1 INTRODUCTION 9 Hrs. Environment definition -The biosphere - Hydrologic cycle -Nutrient cycles, pollutionn of air, water and soil. Air pollution laws and air quality standard. Water pollution quality standards and law. MINAS. Air pollution effect on human, plant and animal. Acid rain.

UNIT 2 AIR POLLUTION AND ITS CONTROL 9 Hrs. Introduction-Sources of air pollution, Air pollution control methods-Source correction method, Cleaning of gaseous effluent, Particulate Emission control and equipments used in particulate emission control.

UNIT 3 WATER POLLUTION AND ANALYSIS 9 Hrs. Origin of waste water, Types of waste pollutants and their effects, Waste water sampling and analysis, Determination of organic and inorganic matters, Physical characteristics, Bacteriological measurements.

UNIT 4 NOISE POLLUTION 9 Hrs. Introduction, sources of noise pollution, Characteristics of sound, noise units, types of noise, effects and control of noise pollution. Radioactive pollution (RAP), Sources of RAP-Classification of its radiation effects on humans, plants and animals.

UNIT 5 SOLID WASTE AND ITS MANAGEMENT 9 Hrs. Sources and Classification of solid waste, Public health aspects, Methods of collection, Disposal Methods, Potential methods of disposal of solid waste.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Kapoor B.S., Environmental Engineering, 3rd Edition, Khanna Publishers, 1997. 2. Mahajan S.P., Pollution Control in Process Industries, 1st Edition, Tata McGraw Hill, 1995. 3. Rao C.S., Environmental Pollution Control Engineering, 2nd Edition, New Age International Publications,2000. 4. Jain P.C, & Monica Jain., Engineering Chemistry. 5th Edition, Dhanpat Rai Publications, 2002. 5. Dara S.S., A Text Book of Engineering Chemistry, 3rd Edition, S.Chan & Co Ltd, 2006.


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SCH1311 INDUSTRIAL SAFETY AND HAZARD ANALYSIS


COURSE OBJECTIVE To emphasize the importance of safety and to gain knowledge on the hazards and their analysis in industries

UNIT 1 INDUSTRIAL SAFETY 9 Hrs. Industrial safety principles, accidents, site selection and plant layout, design for ventilation, emergency response systems for hazardous goods, basic rules and requirements which govern the chemical industries. Emergency response systems for hazardous goods, Emergency planning and preparedness, Major Industrial accidents, causes, methods of prevention, Case Study.

UNIT 2 HAZARDS 9 Hrs. Chemical hazards classification, hazards due to fire, explosion and radiation, various explosions: VCE, UVCE and BLEVE. Potential hazards, Chemical and Physical job-safety analysis, Safety in High-pressure and high temperature operations, toxic effects, highly radioactive materials, Safe handling and operation of materials and machineries.

UNIT 3 HAZARD ANALYSIS 9 Hrs. Types of hazard analysis ,hazard identification ,Material safety data sheet ,specifications, Safety Audit, Hazard and Operability studies Steps involved and significance, Fault tree analysis, Event tree analysis., Failure Mode Effect Analysis procedure and Illustrated examples.

UNIT 4 SAFETY APPRAISAL 9 Hrs. Safety audit ,Effective steps to implement safety procedures, periodic training and regular maintenance, personal protective equipments, types, Safety Program, Elements of safety Program , Fire Formation, Fire Triangle, Fire prevention and fire fighting equipments

UNIT 5 HEALTH HAZARDS AND LEGAL ASPECTS 9 Hrs. OSHA Regulations and Significance, Health hazards -occupational, Industrial health hazards. Health standards and rules, Safe working environment, Factories act, Labor welfare act, ESI act, Workmen compensation act, Provisions and features.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Fawcett H.H. and Wood W.S., Safety and Accedent Prevention in Chemical Operation, 2nd Edition, Inter Science, 1982. 2. Blake R.P., Industrial Safety, 2nd Edition, Prentice Hall Inc., New Jersey, 2006. 3. Deshmukh. L.M., Industrial Safety Management, 3rd Edition, Tata McGraw Hill, New Delhi, 2008. 4. Jain.R.K and Sunil Rao., Industrial Safety, Health and Environmental Management Systems, 1st Edition, Khanna Delhi 2006. 5. Shrikant Dawande., Chemical Hazards and Safety, 2nd Edition, Khanna publishers,2007. 6. Daniel A.Crowl, Joseph F. Louvar., Chemical Process Safety : Fundamentals with applications, 3rd Edition, Prentice Hall Inc.,

New Jersey, 2011.


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0 0 4 2 100 SUGGESTED LIST OF EXPERIMENTS

1. Measure the emissivity of the test plate and plot a graph between emissivity and temperature. 2. Determine the thermal conductivity of metal rod. (Brass rod) 3. Determine the thermal conductivity of hylem, wood, and asbestos. 4. Find the thermal conductivity of the given insulated material by using lagged pipe. 5. Determine the temperature distribution for a cylinder due to heat transfer by natural convection. 6. Study and compare temperature distribution heat transfer rate, overall heat transfer co-efficient in

parallel flow heat exchanger. 7. Study and compare temperature distribution, heat transfer rate, overall heat transfer co-efficient in

counter flow heat exchanger

SCH4057 MASS TRANSFER LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Study the drying characteristics of calcium carbonate and find the critical moisture content and

equilibrium moisture content of the sample. 2. Determine the diffusivity coefficient for the acetone - air system. 3. Determine the diffusivity coefficient for oxalic acid in water at different temperatures. 4. Verify Rayleigh’s equation for the given acetone - water system by simple distillation. 5. Conduct a batch leaching test to leach out sodium carbonate from the mixture given and hence find out

the percentage of sodium carbonate leached out. 6. Verify Freundlich equation for the adsorption of oxalic acid onto activated carbon. 7. Determine the liquid - liquid equilibrium of the system (Benzene - Acetic acid - Water) and hence draw

the ternary graph for the system. 8. Determine the mass transfer coefficient for the given system using Wetted wall column. 9. Determine the HETP of the packed column by Fenske’s method. 10. Studies on the Vapor Liquid Equilibrium (VLE) for the given system 11. Studies on the Absorption of Carbon dioxide in NaOH

SCH4058 CHEMICAL REACTION ENGINEERING LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Interpretation of Batch Reactor Data 2. RTD Studies in Plug Flow Reactor using step input 3. RTD Studies in Mixed Flow Reactor using step input 4. Performance study on Combined Reactors (PFR Followed by MFR) 5. Performance study on Combined Reactors (MFR Followed by PFR) 6. Performance Study on Semi Batch Reactor 7. Kinetic Studies in a Mixed Flow Reactor 8. Kinetic Studies in a Plug Flow Reactor 9. Determination of Rate of Dissociation using Solid – Liquid Non Catalytic Reactor 10. Study on Packed Bed Catalytic Reactor 11. Adiabatic Reactor

SCH4059 MATLAB L T P Credits Total Marks

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SCH1401 PROCESS MODELING AND SIMULATION L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE The objective of this course is to give a broad coverage of the field of mathematical modeling and simulation in

chemical engineering. Both steady-state and dynamic models will be examined and discussed.

UNIT 1 BASICS OF MODELLING 9 Hrs. Introduction to Modeling, need of models and their classification, Uses of Mathematical Models, Scope of Coverage, Principles of Formulation. Fundamental laws-Continuity Equation, Energy Equation, Equations of Motion. Regression and Correlation Analysis

UNIT 2 MODELING OF HEAT TRANSFER AND OTHER EQUIPMENTS 9 Hrs. Two Heated Tanks, Double Pipe Heat Exchanger, Shell and Tube Heat Exchanger, Evaporators,. Mixing process, interacting and non interacting system and Gravity flow tank

UNIT 3 MODELING OF REACTORS 9 Hrs. Batch Reactor, Series of Isothermal Constant-Holdup CSTR,CSTR with Variable Holdup, Non Isothermal CSTR , Semi batch Reactor, Plug Flow Reactor, Packed Bed Reactor and bioreactor models

UNIT 4 MODELING OF MASS TRANSFER OPERATIONS 9 Hrs. Absorption Columns, Ideal Binary Distillation column , Multicomponent Non-Ideal Distillation Column, Batch Distillation with Holdup, Single Component vaporizer multicomponent flash drum and extraction models,

UNIT 5 DYNAMIC SIMULATION 9 Hrs. Dynamic Simulation of Batch Reactor, Non Isothermal CSTR, Three CSTR in Series,PFR, Binary Distillation Column, Evaporator, Absorption column and Gravity Flow Tank

Max.45 Hours.

TEXT / REFERENCE BOOKS 1. William L.Luyben, Process Modelling, Simulation and Control For Chemical Engineers, 2nd Edition, McGraw Hill International

Editions,New York ,1980. 2. Davis M.E., Numerical methods and Modelling for Chemical Engineers, 1st Edition, Wiley, New York, 1984. 3. Denn M.M., Process Modelling, 2nd Edition, Wiley, New York, 1986. 4. Ramirez W., Computational Methods in Process Simulation, 1st Edition, Butterworth’s Publishers, New York, 1989. 5. Mickley. H.S.Sherwood.T.S. and Reed C.E., Applied Mathematics for Chemical Engineers, 1st Edition, Tata McGraw Hill

Publishing Co. Ltd, New Delhi, 1989.


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SCH1402 OPTIMIZATION OF CHEMICAL PROCESSES L T P Credits Total Marks 3 1 0 4 100

COURSE OBJECTIVE To exhibit and develop the decision making skills for achieving conceptual knowledge in the curriculum of operations research.

UNIT 1 OBJECTIVE AND FORMULATION OF OPTIMIZATION 12 Hrs. Objective and Introduction, Objective Function and Decision variables, Inequality and Equality Constrains in Models Formulation of the Objective Function, Lower and Upper Bounds, Selecting Functions to Fit Empirical Data, Factorial Experimental Designs, Degrees of Freedom, Economic Objective Functions, Measures of Profitability.

UNIT 2 BASIC CONCEPTS OF OPTIMIZATION 12 Hrs. Continuity of Function, NLP Problem Statement, Convexity and Its Applications, Convex and concave functions, Interpretation of the Objective Function in terms of its Quadratic Approximation, Necessary and Sufficient Conditions for an Extremum of an Unconstrained Function.

UNIT 3 OPTIMIZATION OF UNCONSTRAINED FUNCTIONS 12 Hrs. One-Dimensional Search Numerical Methods for Optimizing a Function of One Variable, Scanning and Bracketing Procedures, Newton’s, Divided difference and Quasi-Newton Methods of Unidimensional Search.

UNIT 4 CONSTRAINED MULTIVARIABLE OPTIMIZATION 12 Hrs. Linear Programming (LP) and Applications Geometry of Linear Programs, Basic Linear Programming Definitions and Results, Simplex Algorithm, Barrier Methods, Sensitivity Analysis, Linear Mixed Integer Programs, Application of the EXCEL Solver Spreadsheet for Optimization, Formulation. Introduction to Non linear Programming with Constraints and Mixed-Integer Programming.

UNIT 5 APPLICATION OF OPTIMIZATION IN CHEMICAL ENGINEERING 12 Hrs. Examples of Optimization in Chemical Processes like optimizing recovery of waste heat, Optimal Shell and Tube Heat Exchanger Design, Optimal Design and Operation of binary Distillation Column, Optimal pipe diameter etc. Flow sheet Optimization - Case studies.

Max.60 Hours

TEXT / REFERENCE BOOKS 1. Edger T.F., Himmelblau D.M. and Lasdon L.S., Optimization of Chemical Processes, 2nd Edition, McGraw- Hill, 2001. 2. Seider W.D., Seader J.D. and Lewin D.R., Product and Process Design Principles-Synthesis, Analysis, and Evaluation”, 2nd

Edition, John Wiley and Sons Inc., 2008. 3. Kalyan Moy Deb.,Optimization for Engineering Design, 2nd Edition, Prentice Hall of India, 2009. 4. Singiresu S. Rao.,Engineering Optimization Theory and Practice ,3rd Edition, John Wiley and Sons Inc., 1995.


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0 0 4 2 100 SUGGESTED LIST OF EXPERIMENTS

1. Measure the emissivity of the test plate and plot a graph between emissivity and temperature. 2. Determine the thermal conductivity of metal rod. (Brass rod) 3. Determine the thermal conductivity of hylem, wood, and asbestos. 4. Find the thermal conductivity of the given insulated material by using lagged pipe. 5. Determine the temperature distribution for a cylinder due to heat transfer by natural convection. 6. Study and compare temperature distribution heat transfer rate, overall heat transfer co-efficient in

parallel flow heat exchanger. 7. Study and compare temperature distribution, heat transfer rate, overall heat transfer co-efficient in

counter flow heat exchanger

SCH4057 MASS TRANSFER LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Study the drying characteristics of calcium carbonate and find the critical moisture content and

equilibrium moisture content of the sample. 2. Determine the diffusivity coefficient for the acetone - air system. 3. Determine the diffusivity coefficient for oxalic acid in water at different temperatures. 4. Verify Rayleigh’s equation for the given acetone - water system by simple distillation. 5. Conduct a batch leaching test to leach out sodium carbonate from the mixture given and hence find out

the percentage of sodium carbonate leached out. 6. Verify Freundlich equation for the adsorption of oxalic acid onto activated carbon. 7. Determine the liquid - liquid equilibrium of the system (Benzene - Acetic acid - Water) and hence draw

the ternary graph for the system. 8. Determine the mass transfer coefficient for the given system using Wetted wall column. 9. Determine the HETP of the packed column by Fenske’s method. 10. Studies on the Vapor Liquid Equilibrium (VLE) for the given system 11. Studies on the Absorption of Carbon dioxide in NaOH

SCH4058 CHEMICAL REACTION ENGINEERING LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Interpretation of Batch Reactor Data 2. RTD Studies in Plug Flow Reactor using step input 3. RTD Studies in Mixed Flow Reactor using step input 4. Performance study on Combined Reactors (PFR Followed by MFR) 5. Performance study on Combined Reactors (MFR Followed by PFR) 6. Performance Study on Semi Batch Reactor 7. Kinetic Studies in a Mixed Flow Reactor 8. Kinetic Studies in a Plug Flow Reactor 9. Determination of Rate of Dissociation using Solid – Liquid Non Catalytic Reactor 10. Study on Packed Bed Catalytic Reactor 11. Adiabatic Reactor

SCH4059 MATLAB L T P Credits Total Marks

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0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Practicing MATLAB environment with simple exercises to familiarize Command Window, History,

Workspace, Current Directory, Figure window, Edit window, Shortcuts, Help files. 2. Data types, Constants and Variables, Character constants, operators, Assignment statements. 3. Control Structures: For loops, While, If control structures, Switch, Break, Continue statements. 4. Program to calculate the vapor pressure of water by using Antoine equation 5. Program to find the Bottoms and distillate composition in distillation column 6. Program to find out the feed and product composition in mixer 7. Estimation of average boiling point of a water /ethanol system at different water composition 8. Estimation of composition in sequence of distillation column 9. Calculation of vapor pressure vapour using pressure vs. temperature data in fourth order polynomial

equation 10. Calculation of average density, conductivity and specific heat for water in various rage of temperature

SCH4060 PROCESS SIMULATION LAB L T P Credits Total Marks 0 0 4 2 100

SUGGESTED LIST OF EXPERIMENTS 1. Introduction to software (flow sheeting) 2. Simulation of flash drum 3. Simulation of distillation columns 4. Simulation of absorption columns 5. Simulation of Reactors 6. Simulation of Heat Exchangers. 7. Simulation of pumps and compressors. 8. Simulation of mixing 9. Simulation of compressors.

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SCH1403 PROCESS ENGINEERING ECONOMICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE The course deals with the thought processes, concepts, methods, and knowledge bases used by engineeers to

cost engineering projects and to evaluate the merit of making a particular investment, and to choose the best of a series of alternative investments to achieve a desired objective

UNIT 1 PROCESS DESIGN DEVELOPMENT 9 Hrs. Types of Designs, Material and Energy Balance, Equipment Sizing and Selection, Process Flow Sheet and P&I Diagrams, Plant Location and Layout, Factors affecting Plant Design.

UNIT 2 ENGINEERING ECONOMICS FOR PROCESS ENGINEERS, INTEREST & INVESTMENT COSTS 9 Hrs. Time Value of Money, Equations for Economic Studies, Equivalence, Amortization, Capital Recovery, Depreciation- Nature of Depreciation, Methods of determining depreciation, Depletion.

UNIT 3 COST ESTIMATION AND ANNUAL REPORTS 9 Hrs. Capital Requirements for Process Plants, Cost Indices. Equipment Costs, The William six-tenth’s Factor, Service Facilities, Capital requirements for Complete Plant, The Balance Sheet, Sources of Capital, Variable Costs, Fixed Costs, Income Statement, Income Statement Ratios.

UNIT 4 ECONOMICS OF INVESTMENT ALTERNATIVE 9 Hrs. Economics of Selecting alternates, Annual Cost methods, Present worth method, Equivalent Alternate, Rate of Return and payout-time, Economic Production Charts, Capacity Factors, Break Even Chart for Production Schedule and its Significance for Optimum Analysis.

UNIT 5 ECONOMIC BALANCE 9 Hrs. General Procedure, Practical Considerations, General Procedure for finding optimum Conditions, Procedure for Solving Single- Variable Balances, Procedure With More than One Controllable Variable, Interactive Systems.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Max. S,Peters and Klaus. D Timmerhaus., Plant Design and Economics for Chemical Engineers, 5th Edition, Mc Graw Hill

International Editions, New York, 2004. 2. Schweyer. H.E.,Process Engineering Economics, 1st Edition, Mc Graw Hill, 1955. 3. Jelen F.C and Black J.H.,Cost and Optimization Engineering,3rd Edition, McGraw Hill, 1992. 4. James.R.Couper.,Process Engineering Economics, 1st Edition ,Marcel Dekker Inc, New York,2003.


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COURSE OBJECTIVE To familiarize engineering students with the concepts of Management useful for Managing their own enterprise or to work in a professional organization in Managerial capacity and to provide them an ethical outlook.

UNIT 1 MANAGEMENT FUNCTIONS & STRUCTURE 9 Hrs. Management - Definition -Role of managers- Levels of management-Basic Function - Contribution of Taylor & Fayol. Types of structures - Line, staff, Functional, Committee and Project & Matrix - Structures. Departmentalization - Centralization - Decentralization - Span of control. Management by COURSE OBJECTIVES (MBO)- Management by Exception (MBE).

UNIT 2 MANAGEMENT OF ORGINASATION 9 Hrs. Forms of Business / Industrial Ownership - Sole Trader, Partnership, Joint stock Company, Performance Appraisal - Basic Principles - Pitfalls - Methods to Overcome. Industrial Safety - Causes of Accidents - Cost of Accidents - Measures to avoid Accidents. Plant Layout & Maintenance - Need, Types & Managerial Aspects.

UNIT 3 ORGANISATIONAL BEHAVIOUR 9 Hrs. Organisational Behaviour - Definition - Nature & Scope - Contributing Disciplines - Importance of OB to Managers. Personality - Definition - Theories - Factors Influencing Personality. Motivation - Definition - Theories. Transactional Analysis. Morale & Job Satisfaction - Factors Influencing Job Satisfaction.

UNIT 4 GROUP DYNAMICS 9 Hrs. Group - Definition - Types - Determinants of Group Cohesiveness. Communication - Process - Barriers - Effective Communication. Leadership-Definition- leadership styles- Theories of leadership - Factors Contributing to Effective Leadership. Trade Unions- Role of Trade Union in Organizations - Types and Functions of Trade Unions.

UNIT 5 PROFESSIONAL ETHICS 9 Hrs. Ethics in Workplace - Formulation of Ethics - Managerial Ethics - Managing Ethical Behaviour - Codes of Ethics - Encouraging Ethical Behaviour - Ethical Leadership - Ethical Decision making. Corporate Social Responsibility (CSR) - Intellectual Property Rights (IPR)- Meaning- Laws relating to Intellectual Property Rights (IPRs)

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Gupta C.B., Management Theory and Practice, 14th Edition, Sultan Chand & Sons, 2009. 2. Dr. Prasad L.M., Principle & Practice of Management, 7th Edition, Sultan Chand & Sons, 2008. 3. Aswathappa, Organisational Behaviour, 8th Edition, Himalaya Publishing House, 2010. 4. Dr. Prasad L.M., Organisational Behaviour, 4th Edition, Sultan Chand & Sons, 2008. 5. Harold Koontz, Principles of Management, 1st Edition, Tata McGraw Hill, 2004.


SBA1101 PRINCIPLES OF MANAGEMENT AND PROFESSIONAL ETHICS


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SCH1601 COMPUTER APPLICATIONS IN CHEMICAL ENGINEERING


COURSE OBJECTIVE To impart the students the knowledge of computer and its application in chemical engineering.

UNIT 1 INTRODUCTION TO COMPUTER APPLUCATIONS 9 Hrs. Introduction, Algebraic Equations, Process Simulation, Differential Equations, Equations of State, mathematical formulation, Solving equations of state Using Excel (Single equation in one unknown), Solution using ‘Goal seek’, Solution using ‘Solver’ ,Example of a chemical engineering problem solved using ‘Goal Seek’ , Solving equations of state using MATLAB® (Single equation in one unknown), Example of a chemical engineering problem solved using MATLAB, Specific volume of a mixture.

UNIT 2 CALCULATION IN PHASE SEPARATION 9 Hrs. Vapor-liquid Equilibria, Flash and phase separation, Isothermal flash – development of equations, Example using Excel, Thermodynamic parameters, Example using MATLAB, Example using Aspen Plus, Non-ideal liquids – test of thermodynamic model. Transport Process in 1D, Applications in chemical engineering – mathematical foundation, Heat transfer, Diffusion and reaction, Fluid flow, Unsteady heat transfer, Examples: Heat transfer in a slab, Reaction and diffusion, Parametric solution, Flow of a Newtonion fluid in a pipe, Flow of a Non-Newtonion in a pipe, Transient Heat Transfer.

UNIT 3 SOLUTION USING EXCEL AND MATLAB 9 Hrs. Chemical Reaction Equilibria, Chemical equilibrium expression, Example of hydrogen for fuel cells , Solution with Excel , Solution using MATLAB, Chemical equilibria with two or more equations, Multiple equations, few unknowns with MATLAB, Method 1 using the ‘fsolve’ command, Method 2 using the ‘fminsearch’ function, Variations in MATLAB.

UNIT 4 SEQUENTIAL AND SIMULTANEOUS SOLUTIONS 9 Hrs. Mass Balances with Recycle Streams, Mathematical formulation, Example without recycle, Example with recycle; comparison of sequential and simultaneous solution methods, Example of process simulation using Excel for simple mass balances, Example of process simulation using Excel including chemical reaction equilibrium, Example of process simulation using Excel including phase equilibrium.

UNIT 5 CHEMICAL PROCESS SIMULATION 9 Hrs. Simulation of Mass Transfer Equipment, Thermodynamics, Example: multi component distillation with shortcut method, Mathematical development, Example: multi component distillation with rigorous plate-to-plate methods, Example: packed bed absorption, Example: gas plant product separation.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Finlayson, B.A.,Introduction to Chemical Engineering Computing, 1st Edition, University of Washington, 2005. 2. Bird, R. B., Stewart, W. E., Lightfoot, E. N., Transport Phenomena, 2nd Edition., Wiley, New York, 2002. 3. Plawsky J.L., Transport Phenomena Fundamentals, 1st Edition, Marcel-Dekker, New York, 2001.


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SCH1602 COMPUTATIONAL FLUID DYNAMICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To study the flow of dynamic fluids using computational methods

UNIT 1 OVERVIEW OF CFD AND CONSERVATION LAWS 9 Hrs. Role of CFD, Problem solving in CFD, Components of CFD Software, Governing Equations of Fluid flow and Heat Transfer, Mass conservation, Momentum and Energy equation, Differential and Integral forms, Conservation and non-conservation form.

UNIT 2 TURBULENCE AND ITS MODELLING 9 Hrs. Transition from Laminar to Turbulent flow, Effect of turbulence on time-averaged Navier-Stokes equations, Characteristics of simple turbulent flows, Free turbulent flows, Flat plate boundary layer and pipe flow, Turbulence models, Mixing length model, The k- model, Reynolds stress equation models.

UNIT 3 FINITE VOLUME METHOD 9 Hrs. Introduction, One dimensional steady state diffusion, Two-dimensional diffusion problems, Discretised equations for diffusion problems, One-dimensional unsteady state heat conduction, Discretisation of transient convection-diffusion equation, Solution procedures for unsteady flow calculations, Implementation of Inlet, outlet and wall boundary conditions, Constant pressure boundary condition.

UNIT 4 CFD METHODS 9 Hrs. CFD Methods for the Eular Equation- Linearization and Jacobian Matrix ,Eigen values and Eigenvectors, Flux Splitting Methods. CFD Methods For Navier-Stokes Equations-Beam Warming Algorithm, Mac Cormack’s scheme, Upwind Techniques.

UNIT 5 GRID GENERATION 9 Hrs. Structured Grid generation, Unstructured Grid generation, Adaptive Grid generation, Physical aspects, simple and multiple connected regions, grid generation by PDE solution.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Anderson, J. D.,Computational Fluid Dynamics: The Basics with Applications, 2nd Edition, McGraw Hill International

Editions,1995. 2. Fletcher, C. A. J., Computational Techniques for Fluid Dynamics,3rd Edition Springer Verlag, 1997. 3. Versteeg, H.K. and Malalasekera, W., An Introduction to Computational Fluid Dynamics: The Finite Volume Method,

2nd Edition ,Pearson Education Ltd., 2007. 4. Chung T. J., Computational Fluid Dynamics,2nd Edition, Cambridge University Press,1997.


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SCH1603 INSTRUMENTAL METHODS OF ANALYSIS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the principle involved in the operation of various instruments and their application in

industry and research

UNIT 1 FUNDAMENTALS OF SPECTROSCOPY 9 Hrs. Electromagnetic Radiation: Properties, Various energy levels, Interaction of photons with matter, absorbance, transmittance and their relationship, Permitted energy levels for the electrons of an atom and simple molecules. Beer-Lambert’s law, Limitations, Deviations .Nephelometry and turbiditymetry , Duboscq colorimetry, Estimation of inorganic ions such as Fe, Ni using Beer-Lambert’s Law. Selection of instrumental methods, Instrumental errors, calibration, precision and accuracy.

UNIT 2 MOLECULAR SPECTROSCOPY 9 Hrs. Various electronic transitions in organic and inorganic compounds effected by UV, Visible and infra red radiations, Various energy level diagrams of saturated, unsaturated and carbonyl compounds, excitation by UV and Visible radiations, Woodward-Fischer rules, Effects of auxochromes and effects of conjugation on the absorption maxima, Instrumentation and applications of UV, Visible and IR spectrophotometer, Multi component analysis, Probe type photometer, Photometric titration

UNIT 3 ADVANCED SPECTROSCOPIC METHODS OF ANALYSIS 9 Hrs. Atomic Absorption Spectroscopy (AAS): Principle, Instrumentation and Applications, Various interferences observed in AAS. Principle,instrumentation and Applications of polarimetry and refractometry. Principle of flame photometry and Inductively coupled plasma atomic emission spectroscopy, Nuclear magnetic resonance spectroscopy.

UNIT 4 ELECTROMETRIC METHODS OF ANALYSIS 9 Hrs. Introduction of electrometric methods, difference between redox and acid- base reactions, types of cells, schematic representation of cell, single electrode potential, laboratory reference electrodes (Standard hydrogen, saturated calomel, Ag -AgCl and inert electrodes), ion-selective electrodes. Potentiometry: Nernst equation, experimental set-up and measurement of pH; Conductometry- Measurement of conductance, experimental set-up and various conductometric titrations.

UNIT 5 CHROMATOGRAPHIC METHODS 9 Hrs. Basic principles of chromatography, Classification of chromatographic methods, types of chromatography- Column, Thin layer, Paper, Gas, High Performance Liquid Chromatography (Principle involved , instrumentation and applications).

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Willard H.H., Merritt I.I., Dean J.A., and Settle, F.A., Instrumental Methods of Analysis, 6th Edition, CBS Publishers,

1986. 2. Skoog D.A and Weswt D.M.M., Fundamentals of Analytical Chemistry, 8th Edition Saunders-College Publishing, 2004. 3. Gurdeep R. Chatwal and Sham K. Anand., Instrumental Methods of Chemical Analysis, 5th Edition., Himalaya

Publishing House,Mumbai, 2002. 4. Sharma B.L., Instrumental methods of chemical analysis, 24th Edition, Goel publishing house, 2005.


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SCH1604 FERTILIZER TECHNOLOGY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To make the student’s understand and improve the Technological advancements in agriculture and fertilizer industry

UNIT 1 INTRODUCTION TO FERTILIZERS & NITROGENOUS FERTILIZERS 9 Hrs. Plant nutrients and its types, Fertilizer and its types, Production of Ammonia and Nitric acid, Methods of production, Specification, storage and handling of nitrogenous fertilizers, Ammonium sulphate, Ammonium nitrate, Urea, Calcium ammonium nitrate, Ammonium chloride.

UNIT 2 POTASSIUM FERTILIZERS 9 Hrs. Sources of potassium, Location, Methods of production, Specification, storage and handling of potassic fertilizers, potassium chloride, Potassium choenites. Function of potassium in plants.

UNIT 3 PHOSPHATIC FERTILIZERS 9 Hrs. Raw materials, Phosphoric acid, Sulphuric acid, Phosphate rock, Sulfur, pyrite. Methods of production, Specification, storage and handling of Phosphatic fertilizers, ground rock phosphate, Bone meal, Single super phosphate, Triple super phosphate, Thermal phosphate.

UNIT 4 COMPLEX AND MISCELLANEOUS FERTILIZERS 9 Hrs. Types of complex fertilizers, composition ,Production of ammonium phosphate fertilizers, Ammonium sulfate, Diammonium phosphate, Nitro phosphate , Mono Ammonium Phosphate and various grade of NPK fertilizers Produced in industries. Mixed fertilizers and granulated mixtures, Biofertilizers and nutrients. Secondary nutrients and Micronutrients, Fluid fertilizers.

UNIT 5 ENVIRONMENTAL PROTECTION & POLLUTION PREVENTION 9 Hrs. Environmental issues related to the use of fertilizers, Environmental impact of the fertilizer industry, Phosphogypsum, Environmental Impact Assessment, and Role of international organizations.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Handbook of Fertilizer Technology, Fertilizer Association of India, New Delhi, 1998. 2. George T. Austin, Shreve’s Chemical Process Industries, 5th Edition, McGraw-Hill International Editions, Singapore,

1984. 3. Gopala Rao M. and Marshall Sittig, Dryden’s Outlines of Chemical Technology, 3rd Edition., East-West Press, New

Delhi, 1997. 4. Slack. A.V., Chemistry and Technology of Fertilizers, 2nd Edition, Interscience, Newyork, 1967. 5. Fertilizer Manual, Kluwer Academic Publishers, Netherlands, 1998.


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SCH1605 NOVEL SEPARATION PROCESSES L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To indentify about the kind of separation processes in general and novel separations are integral part of any

process chemical industries.

UNIT 1 THERMAL SEPARATION 9 Hrs. Thermal Diffusion: Basic Rate Law, Theory of Thermal Diffusion Phenomena for gas and liquid mixtures, Equipments design and Applications. Zone Melting: Equilibrium diagrams, Controlling factors, Apparatus and Applications, Zone Refining and Zone leveling.

UNIT 2 SORPTION TECHNIQUES 9 Hrs. Types and choice of adsorbents, Normal Adsorption techniques, Chromatographic techniques, Equipment and Commercial processes, Recent advances and Economics, Molecular Sieves. Latest developments in separation techniques: Cryogenic, Supercritical fluid extraction, Bio-separation, and Azeotropic separation.

UNIT 3 MEMBRANE SEPARATION PROCESSES 9 Hrs. Principle of membrane separations process; Classification: Reverse osmosis, Ultrafiltration, Micro-filtration, Nano-filtration and Dialysis; Analysis and modeling of membrane separation processes; Membrane modules and application; Ion selective membranes and their application in electro-dialysis; Pervaporation and gas separation using membranes; Electrophorosis; Liquid membranes and its industrial applications.

UNIT 4 IONIC SEPARATION 9 Hrs. Controlling factors, Applications, Equipments for Electrophoresis, Dielectrophoresis, Electro Dialysis and Ion - Exchange, Commercial processes. Other Techniques: Adductive Crystallization: Molecular addition compounds, Clathrate compounds and Adducts, Equipments, Applications, Economics and Commercial processes.

UNIT 5 FOAM SEPARATION 9 Hrs. Foam and bubble separation: Principle; Classification; Separation techniques; Column operations. Surface Adsorption, Nature of foams, Apparatus, Applications, and controlling factor.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Schoen H. M., New Chemical Engineering Separation Techniques, 2nd Edition, Inter Science Publications, NewYork,

1972. 2. Seader, J.D, and Henley E.J.,Separation Process Principles, John Wiley & Sons, Inc.,1984. 3. Perry R.H. and. Green D.W.,Perry’s Chemical Engineers Hand book, 6th Edition. McGraw Hill, New York, 1990. 4. Coulson J. M. and Richardson J. F., Chemical Engineering, Vol. II, 4th Edition, Butterworth, Heinemann, London,

1991. 5. King C.J.,separation Processes, 4th Edition, Tata McGraw Hill, New Delhi, 1978.


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SCH1606 INDUSTRIAL CATALYSIS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the catalysts and their role in chemical engineering

UNIT1 INTRODUCTION TO CATALYSIS 9 Hrs. General properties of homogenous and heterogeneous catalysis, Life cycle of catalyst, Steps in a catalytic reaction, Physisorption and Chemisorptions, active site, catalyst characterization, catalyst activity and selectivity.

UNIT 2 GEOMETRIC AND ELECTRONIC FACTORS IN CATALYSIS 9 Hrs. Adsorption and reaction kinetics in catalytic (heterogeneous) system, Electron band theory, Valence Bond theory, Dowden’s rule for bond formation, Semiconductor theory, Charge transfer theory

UNIT 3 CATALYST PREPARATION 9 Hrs. Preparation and evaluation of industrial catalysts, catalyst formation, wet methods, precipitation and precipitation deposition, unsupported and supported metal catalyst, sintering, reverse micro emulsion method, industrial catalyst examples and applications.

UNIT 4 KINETICS OF HETEROGENEOUS REACTIONS 9 Hrs. Reaction engineering applied to catalytic homogeneous and heterogeneous chemical reactions, Kinetics of adsorption and surface reaction, evaluation of kinetic parameters.

UNIT 5 CATALYST POISONING 9 Hrs. Catalyst poisoning and deterioration, (sintering) origination of catalyst, types of poison, catalyst deactivation, pour mouth poisoning, poisoning by chemical binding, Catalytic – cracking and regeneration, reversible and irreversible poisoning.

Max.45 Hours

TEXT / REFERENCE BOOKS 1. Smith J. M., Chemical Engineering Kinetics, 3rd Edition, McGraw Hill, 1983. 2. Bond G., Heterogeneous Catalysis -Principles and Applications,2nd Edition, Oxford Univ. Press, 1986. 3. Mukhlyonov I., Catalyst Technology,2nd Edition, Mir Publishers, 1976. 4. Thomas C.C., Catalytic Processes with Proven Catalysts, 2nd Edition, Academic Press1970.


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SCH1607 FLUIDIZATION ENGINEERING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To understand fluid flow behavior and its application in Chemical process industries

UNIT 1 INTRODUCTION AND APPLICATIONS 9 Hrs. Introduction to Fluidized bed systems. Fundamentals of fluidization. Industrial applications of fluidized beds -Physical operations. Synthesis reactions, cracking and reforming of hydrocarbons, Gasification, Carbonization, Gas-solid reactions, Calcining and clinkering.

UNIT 2 GROSS BEHAVIOR OF FLUDIZED BEDS 9 Hrs. Gross behavior of fluidized beds. Minimum and terminal velocities in fluidized beds. Types of fluidization. Design of distributors. Voidage in fluidized beds. TDH, Variation in size distribution with height, Viscosity and fluidity of fluidized beds, Power consumption.

UNIT 3 ANALYSIS OF BUBBLE AND EMULSION PHAS 9 Hrs. Davidson’s model, Frequency measurements, bubbles in ordinary bubbling bed model for bubble phase. Emulsion phase: Experimental findings. Turnover rate of solids. Bubbling bed model for emulsion phase Interchange coefficients.

UNIT 4 FLOW PATTERN OF GAS AND HEAT & MASS TRANSFER IN FLUIDIZED BEDS 9 Hrs. Flow pattern of gas through fluidized beds. Experimental findings. Bubbling bed model for Gas interchange Interpretation of Gas mixing data. Heat and Mass Transfer between fluid and solid- Experiment findings on Heat and Mass Transfer. Heat and Mass Transfer rates from bubbling bed model.

UNIT 5 HEAT TRANSFER BETWEEN FLUIDIZED BEDS AND SURFACES 9 Hrs. Heat transfer between fluidized beds and surfaces: Experiment finding theories of bed heat transfer comparison of theories. Model for entrainment and application of the entrainment model to elutriation.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Kunii D. and Levenspiel O., Fluidization Engineering, 2nd Edition, John Wiley & sons, 1992. 2. Gidaspow D.,Multiphase flow and fluidization continuum and kinetic theory description, Elsevier Science and

Technology Books, 1985.


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SCH1608 MULTICOMPONENT SEPARATION SYSTEM L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVE To understand the governing mechanisms and driving forces of various separation processes and design the

equipment involved.

UNIT 1 INTRODUCTION 9 Hrs. Importance of a variety of separation processes, Characteristics of Separation process, Introduction to multi component separation system –Technological schemes of complex oil, gas condensate processing plant, application of multi component separation system in petrochemical system-Low temperature absorption system-gas, oil and water separation system by using three phase separator.

UNIT 2 MULTI COMPONENT DISTILLATION 9 Hrs. Introduction to Multi component distillation-Key components, Estimation of minimum theoretical stages using Fenske’s equation, determination of minimum reflux ratio using Under wood’s method, approximate calculation for multi component-multistage distillation, estimation of actual reflux ratio and theoretical stages (Kirks-Bridge equation) distribution of no, key components at actual refuse.

UNIT 3 ABSORPTION 9 Hrs. Absorption of multi component–calculation of number of trays by Kremser’s equation, Working and construction of Horizontal multistage plate absorber, vertical plate and packed bed absorber, direct flow multi stage absorption and step direct flow, counter flow absorption.

UNIT 4 EXTRACTION 9 Hrs. Extraction of multi component system-Choice of solvent, single stage extraction, Multistage extraction-cocurrent and counter current-batch, simulation of continuous counter current cascade extraction, Stage Efficiency, Types of extractors.

UNIT 5 CONSTRUCTION OF SEPARATORS 9 Hrs. Construction of Separators, Dividers, and Settlers-vertical, horizontal separators, gill and grid orifice, centrifugal -one socket and multi socket separators, separators with grid and glass fiber coagulator, gravitation oil gas separator, Electro dehydrator, and cooling devices.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Sinaiski E.G. and Lapiga E.J., Separation of Multiphase, Multicomponent Systems, 1st Edition, Wiley-VCH Verlag

GmbH & Co , 2003. 2. Treybal R.E., Mass Transfer operation, 3rd Edition, McGraw Hill, 1980. 3. Sinnott R.K., Chemical Engineering Design, 3rd Edition, Asian Book Printers Ltd., 2007. 4. Seader J.D., Ernest J. Henley and Roper D.K., Separation Process Principles, 3rd Edition, Wiley Publications, 2009.


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SCH1609 FOOD TECHNOLOGY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart knowledge to the students about advanced technology in food science and recent trends adapted in

food industry.

UNIT I FOOD PROCESSING ENGINEERING–FUNDAMENTALS 9 Hrs. Fundamentals of Food Process Engineering, Application of Quantitative methods of Material & Energy Balances in Food Engineering Practices. Constituents of Food, Quality and Nutritive aspects, Food Adulterations, Deteriorative factors and Control

UNIT 2 UNIT OPERATIONS IN FOOD INDUSTRIES 9 Hrs. Fluid Flow, Thermal Process Calculations, Refrigeration, Evaporation and Dehydration operations in Food Processing

UNIT 3 FOOD CANNING TECHNOLOGY 9 Hrs. Fundamentals of Food Canning Technology, Heat Sterilization of Canned food, Containers – metal, Glass and Flexible packaging. Canning Procedures for Fruits, Vegetables, Meat, Poultry and Marine Products

UNIT 4 FOOD PRESERVATION METHODS 9 Hrs. Preservation by Heat and Cold, Dehydration, Concentration, Drying, Irradiation, Microwave heating, Sterilization and Pasteurization, Fermentation and Pickling, Packaging Methods

UNIT 5 PRODUCTION AND UTILIZATION OF FOOD PRODUCTS 9 Hrs. Cereal, Grains, Pulses, Vegetables, Fruits, Spices, Fats and Oils, Bakery, Confectionary and Chocolate Products. Soft and Alcoholic Beverages, Dairy Products, Meat, Poultry and Fish Products

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Heid J.L. Joslyn M.A.,Fundamentals of Food Processing Operation, 5th Edition,The AVI publishing Co., West port

1967 2. Potter N.N., Food Science, 6th Edition, The AVI publishing Co., Westport, 2003 3. Heldman D.R., Food Process Engineering, 4th Edition ,The AVI publishing.2005 4. Owen .R.Fennema.,Principles of Food Science Part I & II, 4th Edition, Marcel Dekker Inc New York, 1976.


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SCH1610 POLYMER TECHNOLOGY L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVE To provide a broad and fundamental knowledge of the polymers and their chemical, physical and mechanical

behavior.

UNIT 1 INTRODUCTION TO POLYMERS 9 Hrs. Classification of polymers, polymerization process, chemistry and Kinetics of step growth and chain growth polymerization, polymerization techniques: Bulk, solution, suspension emulsion, mold, polycondensation, interfacial condensations, solid and gas phase polymerization.

UNIT 2 MOLECULAR WEIGHT & SIZE OF POLYMERS 9 Hrs. Number average and weight average molecular weight, significance of molecular weight, determination of molecular weight and group analysis, solution viscosity method, osmotic pressure, light scattering method, gel permeation chromatography method etc.

UNIT 3 POLYMER PROPERTIES & THEIR TESTING 9 Hrs. Glass transition temperature and associated properties, thermosetting polymers. Tensile strength & impact strength and their determination, softening point, heat distortion dielectric and power factor etc. Rheology of polymeric materials.

UNIT 4 SYNTHESIS & PROPERTIES OF COMMERCIAL POLYMERS 9 Hrs. Plastic, rubber and fibers of commercial importance, polymer auxiliaries; plasticizers, stabilizers, fillers, lubricant etc. Manufacture, processing and properties of resins such as phenol formaldehyde, urea formaldehyde, epoxy resins, urethane foam and silicon polymers; LDPE, HDPE, polypropylene, polyvinyl chloride, polystyrene, polybutadiene, polyacrylonitrile, polyamide, etc. fiber reinforced plastics.

UNIT 5 ENGINEERING APPLICATIONS OF POLYMERS 9 Hrs. Elastomeric composites in tyre technology, polymers in fiber, manmade fibers, acetate fiber, acrylic, nylon, olefin, polyester, rayon, synthetic adhesives, Bio-polymers and their applications, plastics and polymers in agriculture industry, Plastics in consumer goods, polymer powders, coating and medical applications of polymers. Polymer degradation: Thermal, Mechanical and by ultrasonic waves, photo degradation, heat energy radiation, oxidation and hydrolysis.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Billmeyer F.W. ,Text Book of Polymer Science,3rd Edition, Wiley, Singapore, 1984. 2. Anilkumar and Gupta R.K., Fundamental of Polymers, 2nd Edition, McGraw Hill, 1996 3. Rodrigue F.Z., Principals of Polymer Systems, 4th Edition, Taylor and Francis, Washington, 1996. 4. Fried, J.R.,Polymer Science and Technology, 4th Edition, Prentice Hall, 2000.


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SCH1611 OIL AND FAT TECHNOLOGY L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVE The objective of the study was to evaluate the fatty acids composition and interrelations between various fats and oils.

UNIT 1 INTRODUCTION 9 Hrs. Importance of fats and oils in foods; Sources of fats and oils; Extraction of fats and oils – rendering, pressing, solvent extraction; Processing of oils – Degumming, Refining, Bleaching, Deodorization, Fractionation; Reversion and rancidity of fats and oils.

UNIT 2 OILS AND FATS CONSTITUENTS 9 Hrs. Natural vegetable oil and animal fat: Source, Composition, Properties and industrial applications; Plastic fat in bakery and confectionary; Preparation of shortenings and margarine.

UNIT 3 GENERAL ENGINEERING ASPECTS AND PROCESSING METHODS 9 Hrs. Manufacture of different types of fat/oil derived products: Winterization, Esterification, Inter-Esterification & Emulsification

UNIT 4 OIL REFINING 9 Hrs. Production technology of oil seed protein isolates; Standard and quality control of fats and fatty foods; By-products of fat and oil processing industries.

UNIT 5 HYDROGENATION 9 Hrs. Hydrogenation of oils Description of equipments related to the process; Catalysts; Dry & Wet reduction. The Hardening operation and Hydrogenation products.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. George T. Austin, Shreve’s Chemical Process Industries, 5th Edition., McGraw-Hill , 1984. 2. Gopala Rao M. and Marshall Sittig, Dryden’s Outlines of Chemical Technology, 3rd Edition, East-West Press, 1997. 3. Kent J.A., Riegel’s, Handbook of Industrial Chemistry, 2nd Edition, Van Nostrand Reinhold, 1974. 4. Daniel Swern, Baileys, industrial oil and fat products,1st Edition , Wiley Interscience publication ,1979. 5. Patterson H, Hydrogenation of fats and oils, 1st Edition , Applied Science publishers ,1983.


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SCH1612 DRUGS AND PHARMACEUTICALS TECHNOLOGY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the various processes involved in a Pharmaceutical industry along with formulation and

quality control

UNIT 1 INTRODUCTION 9 Hrs. Pharmaceutical Industry, Drug discovery and Development of Drugs, Organic Therapeutic agents uses and Economics, Physio chemical principles, Drug Metabolism and pharmacokinetics, Kinetic Studies and Action of drugs on Human Bodies

UNIT 2 UNIT PROCESSES AND THEIR APPLICATIONS 9 Hrs. Chemical Conversion Processes - Alkylation, Carboxylation, Condensation, Cyclisation, Dehydration, Esterification, Halogenation Oxidation , Sulfonation , Complex Chemical Conversions and Fermentation

UNIT 3 ANUFACTURING PRINCIPLES 9 Hrs. Compressed Tablets, Wet Granulation, Dry Granulation or Slugging, Direct Compression, Tablet Presses, Formulation, Coating Pills, Parental Solutions, Oral Liquid, Injections , Ointments, Role of Regulatory Authorities (FDA), Standard of Hygiene and Manufacturing Practice (GMP)

UNIT 4 PRODUCT FORMULATION 9 Hrs. Vitamins and other nutrients, Cold Remedies, Laxatives, Analgesics, External Antiseptics, CNS Stimulants, sedatives, Antacids, Antibiotics, Biologicals, Hormones

UNIT 5 ANALYSIS & QUALITY CONTROL 9 Hrs. Pharmaceutical Analysis Packaging and Control , Analytical Methods and Tests for various Drugs & Pharmaceuticals- principle, instrumentation and applications of UV/VIS and IR spectroscopy, chromatography principle and its types, Packaging Techniques and Quality Control

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Rawlnes, E.A., Bentley’s Text Book of Pharmaceuticals, 7th Edition, Bailliere Tindalls, London, 2009. 2. Remingston, Pharmaceutical Sciences, 18th Edition, Mach Publishing Co., 1990. 3. Nita pandit K ,Introduction to pharmaceutical sciences, 1st Edition, lipincott Williams & wilkins, 2007. 4. James swarbrick, Encyclopedia of pharmaceutical technology, 3rd Edition, informa healthcare distribution, 2006. 5. Mark Saltzman.W., Drug delivery, engineering principles for drug therapy, 1st Edition, oxford university press, 2001.


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SCH1613 NANO SCIENCE AND TECHNOLOGY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To understand the manipulation of matter on an atomic and molecular scale.

UNIT 1 SUPRAMOLECULAR CHEMISTRY 9 Hrs. Supramolecular Chemistry. Definition and examples of the main intermolecular forces used in supramolecular chemistry. Self assembly processes in organic systems. Main supramolecular structures. Dendrimers, synthesis, properties & structure Fullerenes, synthesis, properties & structure Carbon Nanotube, synthesis, properties & structure. Core Shell nano particles.

UNIT 2 SYNTHESIS OF NANOMATERIALS 9 Hrs. Methods of Synthesis of Nanometerials. Equipment and processes needed to fabricate nanodevices and structures such as bio-chips, power devices, and optoelectronic structures. Bottom-up (building from molecular level) and top-down (breakdown of microcrystalline materials) approaches.

UNIT 3 FABRICATION 9 Hrs. Micro-nano fabrication: photolithography; Fabrication and characterization in mesoscale employing lithography, microscopy, chromatography and spectroscopy. MEMS and NEMS fabrication.

UNIT 4 NANO-BIOTECHNOLOGY 9 Hrs. Biologically Inspired Nanotechnology Basic biological concepts and principles that may lead to the development of technologies for nanoengineering systems. Molecular nanoscale engineered devices, nanoscale biotechnologies, nano products.

UNIT 5 CHARACTERIZATION OF NANOMATERIALS 9 Hrs. Atomic size, crystallography, Particle size determination, Surface structure, Microscopy, Transmission Electron Microscopy, Field Ion Microscopy, Spectroscopy,Infrared and Raman Spectroscopy, Photoemission and X ray Spectroscopy, Magnetic resonance. Atomic Force Microscope (AFM), Scanning Electron Microscopy (SEM), Principles of Noncontact Atomic Force Microscope (NCAFM).

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Jean-Marie Lehn., Supramolecular Chemistry, 1st Edition, Wiley Publications, 1995. 2. Novailhat, Alain., Introduction to Nano technology, 2nd Edition, Wiley Publications, 2007. 3. Hovnyax G., Moore J., Tibbals J., Fundamental of Nanotechnology, 1st Edition, CRC Press, 1997 4. Madou.M.J., Fundamentals of Microfabriation. The Science of Miniaturization, 2nd Edition, Taylor and Francis, 2002. 5. Pradeep.T., Nano the essentials Kindle, 3rd Edition,The McGraw-Hill Companies,2007.


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SCH1614 CORROSION ENGINEERING L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVE To provide fundamental understanding of aspects of electrochemistry and material science relevant to corrosion

phenomena, prevention and remediation of corrosion

UNIT 1 INTRODUCTION 9 Hrs. Definition of Corrosion, corrosion damage, effect of material safety and reliability, classification of corrosion, expression of corrosion rate, electrochemical corrosion reaction, redox reaction, effect of oxygen, oxidizers. Effect of temperatures, concentration of chemicals on corrosion rate, Corrosion: direct & two stage attack, electrochemical attack, environment conditioning.

UNIT 2 TYPES OF CORROSION 9 Hrs. Effect of galvanic coupling, metallurgical aspects, metallic properties, ringworm corrosion, Principle of modern corrosion theory, Forms of corrosion, Uniform attack, galvanic corrosion, crevice corrosion, pitting intergranular corrosion and hydrogen damage, higher corrosion resistance through proper selection of material, isolation of corrosion prone materials from destructive environment.

UNIT 3 CORROSION PROTECTTIVE MEASURES 9 Hrs. Technologies of anodisation, enameling, rubber lining, glass lining, refractory lining, painting and other surface protective measures.

UNIT 4 APPLICATION OF CORROSION ENGINEERING 9 Hrs. Corrosion engineering in special applications such as material transport, pumping, filtration, condensation, boiling, riveting, welding, and high temperature environments.

UNIT 5 CORROSION TESTING AND MEASUREMENTS 9 Hrs. Corrosion testing, monitoring and inspection, laboratory corrosion test, accelerated chemical tests for studying different forms of corrosion, electrochemical methods of corrosion rate measurements by DC and AC methods, corrosion monitoring methods, chemical and electrochemical removal of corrosion products, cost factor in competitive corrosion prevention and inhibition techniques.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Unling, H.H., Corrosion Control, 2nd Edition, John Wiley & Sons, 1971 2. Butler, G. & Ison, H.C.K., Corrosion & its Prevention in Waters, 2nd Edition, Leonard Hill, London, 1966. 3. Maslow, P., Chemical Materials for Construction, 1st Edition, Structures Publishing Co., 1974. 4. Fontance, M.G. & Gtretrnee, N.D., Corrosion Engineering, 2nd Edition, McGraw Hill, 1967. 5. Rajagopalan, K.S. Corrosion and its Prevention, Chemical Engineering Education Development Centre, IIT Madras,

1975.


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SCH1615 ELECTROCHEMICAL ENGINEERING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide adequate knowledge in the principles involved in the electrochemical process and its applications.

UNIT 1 INTRODUCTION 9 Hrs. Electrode potential, Phase equilibrium, chemical and electrochemical potential. Faraday’s law, Nernst potential, Galvanic cells, Polarography The electrical double layer: its role in electrochemical processes, Electro capillary curve, Helmholtz layer, Guoy Chapman, Steven’s model of the double layer, fields at the interface.

UNIT 2 BATTERIES 9 Hrs. Batteries, Primary Batteries and Secondary Batteries, Lechlanche dry cell, Alkaline Manganese cell, Mercury cell Reverse electrolytic cells like Mg–CuCl2, Mg-PbO, Zn-PbO, Secondary cells like lead acid, Ni-Cd, Ni-Fe, AgO-Zn, AgO-Cd, Sodium-Sulfur, Li-S, Fuel Cells.

UNIT 3 ELECTRODES 9 Hrs. Electrodes: Metals Graphite, Lead Oxide, Titanium Substrate insoluble electrodes, Iron Oxide, Semiconductor type electrodes. Metal finishing, Electro Deposition, Electro refining, Electro reforming, Electro polishing, Anodizing, Selective Solar Coatings.

UNIT 4 CORROSION 9 Hrs. Introduction, Metallic surface preparation, Phosphating, Inhibitors in acid media, in engine cooling systems. Control measures, industrial boiler water corrosion control, protective coatings, vapor phase inhibitors, cathodic protection, sacrificial anodes, Paint removers.

UNIT 5 ELECTROCATALYSIS AND ELECTRODIALYSIS 9 Hrs. Chemical catalysis and electro catalysis, comparison of electro catalysts, electro catalysis in Simple redox reactions involving adsorbed species, electronic and geometric factors in electro catalysts, Discussion on the mechanisms of hydrogen evolution and oxygen reduction reactions.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Picket.,Electrochemical Engineering, 2nd Edition Prentice Hall, 1977. 2. Bard.A.J & Faulkner.L.R, Electrochemical Methods Fundamentals and Applications, 2nd Edition,John Wiley & Sons,

2001. 3. Newman.J.S., Electrochemical systems, 3rd Edition, Prentice Hall, 1973. 4. Mantell.C., Electrochemical engineering”, 2nd Edition, McGraw Hill, 1972. 5. Paul Delahay., Double Layer Structure and Electrode Kinetics, 2nd Edition,interscience publishers, 1965.


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SHS1601 LIFE AND EMPLOYABILITY SKILLS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES The course aims at equipping students to be competent in facing the challenges in today's globalized context, by providing an insight to soft skills for success and life skills for survival at the workplace.

UNIT 1 ACHIEVEMENT MOTIVATION 9 Hrs. Time Management - Positive and negative aspects of time log - Formula for successful time management.

UNIT 2 SELF-AWARENESS AND EMPATHY 9 Hrs. Work-Life Balance – Project completion Techniques – Effective Planning and Organisation - Strategies to improve team communication.

UNIT 3 DECISION MAKING 9 Hrs. Decision making techniques- types of decisions- Setting Goals and Plans - Problem Solving Techniques.

UNIT 4 EFFECTIVE COMMNICATION 9 Hrs. Non-verbal communication - means of communication – Personality development – Language and body language for interviews- Self Empowerment.

UNIT 5 NEGOTIATION SKILLS 9 Hrs. Negotiation skills – skill acquisition strategies – effective persuading skills.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Gravells, Ann. “Delivering Employability Skills in the Lifelong Learning Sector Further Education and Skills”, United

Kingdom: SAGE Publications Ltd, 2010. 2. Hind, David W.G., Stuart Moss, “Employability Skills,” Business Education Publishers Ltd., United Kingdom :Tyne & Wear,

2005. 3. Rao M.S., “Enhancing Employability: Connecting Campus with Corporate”, New Delhi: I K International Publishing House

Pvt. Ltd, 2010

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each – No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SHS1602 TECHNICAL WRITING FOR SCIENTISTS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide with an introduction to professional writing as a disciplinary field.

UNIT 1 INTRODUCTION TO TECHNICAL WRITING 9 Hrs. Technical Writing – Principles and procedure of technical writing; Role of a Technical writer, Various forms of Technical Writing

UNIT 2 ONLINE TOOLS 9 Hrs. Printed documentation and Online Help Systems, Working with images and illustrations, designing graphic aids.

UNIT 3 PROCESS OF WRITING 9 Hrs. Collecting and Organizing information, Drafting information verbally and visually, Producing Information, Documentation Process.

UNIT 4 REACHING THE AUDIENCE 9 Hrs. Technical Writing Process Templates and Page design, Audience Profiling.

UNIT 5 PRESENTATION 9 Hrs. Writing specialized forms as abstracts, instructions, proposals and project and lab reports

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Mike Markel's “Technical Communication”, New York: Bedford/St. Martin's, 2009 2. Joseph M. Williams book Style: “Toward Clarity and Grace”, Chicago, University of Chicago Press, 1995

END SEMESTER EXAM QUESTION PAPER PATTERN: Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each – No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SHS1603 PROFESSIONAL WRITING AND ADVANCED RHETORIC


COURSE OBJECTIVE To educate the learners on written communication and provide exposure to practical aspects of writing for wider audience and for scientific community.

UNIT 1 BASICS OF PROFESSIONAL COMMUNICATION 9 Hrs. Technical Writing and Business communication (process, networks, importance, cultural variations, today’s globalized workplaces), Practical aspects of communication, Principles and procedure of technical writing, Role of a Technical writer , attention to analyzing audience and purpose, Understanding and Inventing Pedagogies for Professional Writing.

UNIT 2 PROCESS OF PROFESSIONAL COMMUNICATION 9 Hrs. Technical Writing Process Today, Genres of Technical Communication, Writing Proposals, Formats for Letters, Memos, abstracts, instructions, and proposals, and Email Messages.

UNIT 3 PRACTICAL ASPECTS OFPROFESSIONAL COMMUNICATION 9 Hrs. Drafting and Documentation, Collecting and Organizing information , Drafting information verbally and visually, Producing Information, Documentation Process, Argument, Persuasion, Propaganda, Audience and Style, Readers and Context of Use, The participatory model of writing.

UNIT 4 PROFESSIONAL ETHICS & STRATEGIES IN CHANGING SCENARIO 9 Hrs. Ethics in Professional Communication, Applying theory to practice- analysis of papers and speeches, Writing on line-Principles while designing web sites, Creating effective presentation slides, Speech writing- basics, scrutiny and observation, Speech writing techniques and application.

UNIT 5 PROFESSIONAL COMMUNICATION & FUTURE 9 Hrs. Future of Technical Communication, multimedia genre, Identity, Authority, and Learning to Write in New Workplaces, Writing work, technology, and pedagogy in the present era

Max. 45 Hours TEXT / REFERENCE BOOKS 3. Dubinsky, James, ed., “Teaching Technical Communication: Critical Issues for the Classroom”. Bedford, 2004 4. Hawk, Byron. "Toward a Post-Techne: or, Inventing Pedagogies for Professional Writing." (TCQ) 5. Mara, Andrew and Byron Hawk. "Posthuman Rhetorics and Technical Communication." 6. Henry, Jim. “Writing Workplace Cultures: An Archaeology of Professional Writing”. SIUP, 2000. 7. Johnson-Sheehan, Richard. “Technical Communication Today” 3rd ed. NY: Longman, 2010. 8. Locker, Kitty O. and Donna S. Kienzler., “Business and Administrative Communication”. 9th ed. McGraw Hill, 2010. 9. Mike Markel's Technical Communication, New York: Bedford/St. Martin's, 2009 10. Spilka, Rachel, ed. “Digital Literacy in/for Technical Communications”. Routledge, 2009. 11. Spinuzzi, Clay. “Tracing Genres through Organizations: A Sociocultural Approach to Information Design (Acting with

Technology)”. MIT, 2003


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SCI1619 DISASTER MANAGEMENT L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To create an awareness towards natural and man-made disasters, disaster preparedness and disaster management

UNIT 1 INTRODUCTION TO DISASTERS 12 Hrs. Natural resources and its importance - understanding on fragile eco-system - characteristics and types of Disasters, Geological and Mountain Area Disasters: Earthquakes, Volcanic eruption, landslides - Wind and Water Related Natural Disaster: Floods, Droughts, Cyclones, Tsunamis - Man Made Disasters: Forest fires, Nuclear, Biological and Chemical disaster - Causes and effects - Disaster Profile of India - Disaster Management cycle.

UNIT 2 DISASTER PREPAREDNESS 8 Hrs. Disaster management, mitigation and preparedness: Disaster Preparedness for People and Infrastructure, CommUNITy based Disaster Preparedness Plan - Roles & Responsibilities of Different Agencies and Government: Education, Communication & Training, Central, State, District and local administration, Armed Forces, Police, Para Military Forces, International Agencies, and NGO’s - Disaster Mitigation: Strategies, Emerging Trends, Mitigation management and Role of Team and Coordination.

UNIT 3 REHABILITATION, RECONSTRUCTION & RECOVERY 10 Hrs. Damage assessment – Development of Physical and Economic Infrastructure - Nature of Damage to Houses and Infrastructure due to Disasters - Funding Arrangements for Reconstruction - Monitoring and Evaluation of Rehabilitation Work: Training, Rescue and planning the rescue activities and rehabilitations - Role of Government and NGO’s - Participative Rehabilitation Process: Case Studies

UNIT 4 DISASTER RESPONSE AND DISASTER MANAGEMENT 8 Hrs. Disaster Response Plan: Communication, Participation and Activation of Emergency Preparedness Plans, Search, Rescue, Evacuation and other logistic management - Human Behaviour and Response Management: Psychological Response and Psychological Rehabilitation, Trauma and Stress Management, rumour and Panic Management, Medical and Health Response to Different Disasters - Relief Measures: Minimum Standard of Relief, essential components of Relief Management, and funding.

UNIT 5 RISK ASSESSMENT AND VULNERABILITY ANALYSIS 7 Hrs. Hazard, Risk and Vulnerability: Concept and Relationship: Disaster Risk Reduction, People Participation in Risk Assessment - Vulnerability Analysis, Vulnerability Identification - Vulnerability profile of India - Strategies for Survival - Social Infrastructure for Vulnerability Reduction.

Max. 45 Hours TEXT / REFERENCE BOOKS

1. Bryant Edwards, “Natural Hazards”, Cambridge University Press, U.K, 2005 2. Carter, W. Nick, “Disaster Management, Asian Development Bank”, Manila, 1991. 3. Government of India, “Vulnerability Atlas of India”, New Delhi, 1997. 4. Sahni, Pardeep et.al. (eds.), “Disaster Mitigation Experiences and Reflections”, Prentice Hall of India, New Delhi, 2002 5. Sahni, Pardeep and Ariyabandu, Madhavi Malalgoda, 2012: “Disaster risk reduction in South Asia”, Phi learning pvt. Ltd.- publisher, New Delhi, 2012. 6. Sharma, R.K. & Sharma, G.,(ed), “Natural Disaster”, APH Publishing Corporation, New Delhi, 2005. 7. Taori, K, “Disaster Management through Panchayati Raj”, Concept Publishing Company, New Delhi, 2005. Websites: 8. NOAA Coastal Services Center, “Linking People Information and Technology”, 9. “Risk and Vulnerability Assessment Tool”, at, http://www.csc.noaa.gov/rvat/criticalEdd.html


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SBI1101 INTRODUCTION TO BIOINFORMATICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To enable the students to understand the tools used in Bioinformatics & how to use them. This will facilitate the

students to undertake projects in modern biology.

UNIT 1 INTRODUCTION 9 Hrs. Introduction to bioinformatics, biological information, the Central Dogma, Bioinformatics: Definition and overview Bioinformatics, Branches of Bioinformatics, Aim, Scope and Research areas of Bioinformatics. Genome projects, human genome project- Databases and human chromosomes, role of Bioinformatics in biological sequences. Biological data- DNA sequence protein sequence, macromolecular structure.Challenges in bioinformatics.

UNIT 2 COMPUTING IN BIOINFORMATICS 9 Hrs. Introduction to internet-facilities used on the internet-www- web browsers, introduction to network basics- LAN, wan, network topology, protocol. Basic principles of computing in bioinformatics - database system, programming languages for bioinformatics- Perl, python. Introduction to computational biology.

UNIT 3 BIOLOGICAL DATABASES 9 Hrs. Databases and programs, Information retrieval from databases of nucleic acid and proteins. Pair wise alignment and database searching, Multiple Sequence Alignment database searching, DNA analysis, protein analysis, Data information and Knowledge Management, Concepts in Bioinformatics, Databases and Data Warehouses in Bioinformatics. Challenges, combining multiple types of data, Information Retrieval system in bioinformatics.

UNIT 4 TOOLS APPLICATIONS IN BIOINFORMATICS 9 Hrs. Bio-algorithms and Tools- Identifying genes, Overview of sequence annotation. Gene prediction methods- Human variation and disease identification, Visualizing and comparing nucleic acids and Protein Introduction to Phylogenetic analysis definition, concepts of tree, steps in constructing Phylogenetic analysis. Introduction to microarray.

UNIT 5 SOFTWARES IN BIOINFORMATICS 9 Hrs. Basic software tools used in bioinformatics - Sequence analysis- GCG, Emboss - Cn3D viewer- Rasmol, Swiss pdb viewer, Pymol, Jmol. Modeling- Discovery studio 2.0, Docking -Auto dock,HEX.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Des Higgins and Willie Taylor, Bioinformatics sequence structures and databases, by Oxford University press, 1st ed., 2000. 2. Atwood, Paey Smith, Introduction to bioinformatics, Woodhead Publisher Ltd., 2001. 3. Arthur M.Lesk, Introduction to bioinformatics, Oxford University Press, 2002. 4. David W. Mount, Bioinformatics: Sequences and genome analyses, Cold Spring Harbor Laboratory press, 2000. 5. Westhead, Parish and Twyman, Instant notes: Bioinformatics, 2003.

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks : 80 Exam duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks 60 Marks

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SBI1207 PERL PROGRAMMING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To understand the basics of PERL programming and its role and applications in Bioinformatics discipline.

UNIT 1 INTRODUCTION TO PERL PROGRAMMING 9 Hrs. Introduction to Perl for Bioinformatics- Comprehensive PERL Archive Network-Variables in Perl: Scalars, Arrays and Hashes. Basic structure of Perl language- a functional approach - constructing atgc.pl. tr/// function -text formatting - formatting numerical output with printf - trapping errors at run time - the s/// operator - the chop and chomp operators.

UNIT 2 INTRODUCTION TO ARRAYS AND HASHES 9 Hrs. Introduction to arrays and Hashes Variables - Printing hash data, accessing and removing elements. Special variable $[ Accessing elements in an array. Function list - reverse- sort- join- split- pop- push- shift- unshift-split function-advanced array operation - copying and creating arrays - populating arrays with sequential data - qw function - determination of the size of an array -counting arrays - accessing first element in an array, accessing last element in an array, accessing other elements in an array - adding elements to the end of an array - adding elements- removing elements - appending elements ,altering elements - array slices - splicing array - sorting arrays - reversing arrays - arrays from strings. Merging arrays, Transforming strings to arrays, transforming arrays to strings (Split and join functions).

UNIT 3 PERL REGULAR EXPRESSIONS AND CONTROL STRUCTURES. 9 Hrs. Perl regular expressions - special characters (+, *,?, [ ]) - regex operator - pattern modifier operator - conditional matching operator - range operator - match quantifiers - matching boundaries, grouping matching. Perl control statements - control structures - if statements - if-else - if-elsif - if-elsif-else - while loop - until loop -unless for loop - foreach loop -scoping of variables.

UNIT 4 FILES AND DIRECTORY MANIPULATIONS 9 Hrs. Files- Operating modes: read, write, append function- File variable, Die function- terminating a program, Reading complete file, Reading a file line by line, Closing a file. File test operators (d, e, l, r, s, w, x, B, T)-Manipulation Functions -link, unlink, rename, truncate, removing files. Directory Manipulation functions - mkdir, chdir, opendir, readdir, closedir, rmdir, chmod.

UNIT 5 INTRODUCTION TO PERL MODULES 9 Hrs. Introduction to modules and Subroutines- BioPerl module, Getopt: Long module and LWP: Simple Module- Cwd module - creating perl module tree, system function -Perl subroutines and functions. Introduction and applications of Common Gateway Interfaces (CGI).

Max. 45 Hours.

TEXT / REFERENCE BOOKS 1. Harshawardhan P Bal, Perl Programming for Bioinformatics, Tata McGraw Hill Publishing Company Limited, 2003. 2. Tim Bunce and Alligator Descartes, Programming the Perl DBI, O'Reilly Media, USA, 2000. 3. Michael Moorhouse and Paul Berry, Bioinformatics, Biocomputing and PERL, John Wiley and Sons Ltd., UK, 2004. 4. James Tisdall, Beginning Perl for Bioinformatics, O’Reilly & Associates, USA, 2001. 5. Steven Holzner, PERL, Black Book, Dreamtech Publications, 2nd Edition, 2001.

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks 60 Marks

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SBI1605 PYTHON L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To learn to appreciate the programming language that can be used for a wide variety of programming tasks and

to expose the student to the standard scripting language. At the end of the course, the student will be developing adequate skills in programming and will be known to understand the implementation of various applications using powerful assortment of built-in types in python.

UNIT 1 INTRODUCTION TO PYTHON 9 Hrs. Introduction to PYTHON- History -Features –installation - Setting up path -Working with Python -Basic Syntax -–Operator

UNIT 2 VARIABLE AND DATA TYPES 9 Hrs. Native datatypes – Booleans –Numbers – Strings - Bytes and byte arrays-Lists- Tuples – Sets - Dictionaries

UNIT 3 REGULAR EXPRESSIONS 9 Hrs. Python regular expressions – Match function -Search function -Matching Vs Searching -Modifiers -Patterns.

UNIT 4 CONTROL STATEMENTS 9 Hrs. Conditional Statements -If , If- else , Nested if-else , - Looping- For , While , Nested loops,- Control Statements- Break , Continue , Pass

UNIT 5 FUNCTIONS AND MODULES 9 Hrs. Functions - Defining a function -Calling a function -Types of functions -Function Arguments -Anonymous functions -Global and local variables, Modules- Importing module -Math module -Random module -Packages –Composition

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Hetland., Beginning Python , Apress, 2008 2. Mark Pilgrim, Dive Into Python, Apress, 2004 3. Martin C. Brown, Python: The Complete Reference (English) ,McGraw-Hill/Osborne Media, 2001. 4. Mark Summerfield, Programming in Python 3 2nd ed (PIP3) - Addison Wesley ISBN: 0-321-68056-1,2009


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SBM1304 BIOMATERIALS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE The course provides an intriguing insight in chemistry, engineering, biology and medicine that has a significant

impact on biomaterials. It highlights the way in which modern biology and medicine is inextricably linked to scientific discipline and

helping us to understand the complex world of biomaterials.

UNIT 1 INTRODUCTION AND METALS 9 Hrs Biomaterials - Overview, Classification of biomaterials, Interfacial Phenomena and tissue response to biomaterials, Metals and alloys for orthopedic implants-Stainless steel, Cobalt chromium alloy, Titanium and its alloys, Precious metal alloys, Other metal alloys. Dental implants - materials, types and designs

UNIT 2 REPLACEMENT AND FIXATION DEVICES 9 Hrs Bioelectric effect, Wolff’s Law, Types of orthopedic fixation devices-pins, screws and plates, Intra Medullary and spinal nails. Interface Problems with artificial joints and various fixation methods, Hard tissue replacements - total hip and knee joint replacements. Soft Tissue replacements- Sutures -Tapes, Staples, Adhesives. Maxillofacial Implants

UNIT 3 POLYMERS AND APPLICATIONS 9 Hrs. Polymers in biomedical use, Hydrogels, silicone rubber, biodegradable polymers, Polymer Sterilization, Deterioration of polymers

UNIT 4 BIOCERAMICS AND COMPOSITES 9 Hrs Bioceramics, types and - bioactive resorbable, non - resorbable, bioceramic coatings on metallic and implants and bone bonding reactions on implantation. Hydroxyapatite - properties and applications. Composites - Types and Applications, Bioglass

UNIT 5 OPTHALMOLOGY, CORROSION AND TESTS 9 Hrs Ophthalmology- Introduction, Contact lenses, Eye shields, Viscoelastic solutions, Vitreous implants, Acrylate adhesives, Scleral buclikng materials for retinal detachment, artificial tears. Corrosion, Biocompatibility and Hemocompatibility, Biological Tests. Material surface characterization

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Sujata V Bhat, Biomaterials, Narosa Publishing House, New Delhi, 2002. 2. Rolando Barbucci, Integrated Biomaterials Science, Plenum Publishers, New York, 2002. 3. A.F. Von Recum, Handbook of Biomaterials Evaluation - Scientific, Technical and Clinical Testing of Implant Materials, 1998. 4. 2nd Edition, Taylor & Francis, Philadelphia,1999. 5. 4. J.B Park and R.S Lakes, Biomaterials: An Introduction, Second Edition, Plenum press, New York, 1992. 6. 5. Joseph D Bronzino, The Biomedical Engineering Hand Book, Vol - 11, CRC press, 2000.


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SBM1404 HOSPITAL MANAGEMENT L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES The paper provides opportunities for training and research in all aspects of hospital / health administration. It

helps to promotesscientific management of hospital and advancement of health care systems so as to make it rational, responsive and cost efficient.

The student is thus educated in the development of high quality of hospital care in the community and the country so as to provide a satisfactory environment to the patient and clinical research

UNIT 1 STANDARD OF HOSPITAL 9 Hrs Concept of Hospital Management - Role of Administrator - Responsibilities of Administrator - Hospital Design - Outlines for establishing Departmental Zones - Hospital Engineering

UNIT 2 HOSPITAL ORGANIZATION 9-Hrs. Organization of Out-Patient Services - Problems encountered in functioning of O.P Department - Organization of In- Patient Services - Casualty & Emergency Services - Organization and management of Operation theatres

UNIT 3 SERVICES IN HOSPITAL 9 Hrs Organization of Ancillary Services: Lab Services - Department of Physiotherapy & Occupational Therapy - Organization of Blood Transfusion Services - Department of Radio - diagnosis - Hospital Pharmacy

UNIT 4 STERILIZATION AND HOSPITAL SAFETY 9 Hrs Disease transmission, Sterilization and disinfection methods, Hospital safety - Radiation Safety, hazardous safety, safety disposal of biological waste - Maintenance of Equipments & Instruments.

UNIT 5 SUPPORTIVE SERVICES IN HOSPITAL 9 Hrs Organization and management of Nursing services and Dietary Services in hospital - House-keeping and maintenance -Medical Records -Staffing the hospital - Human resources management in hospital - Management Assisted by Computers: Reservation, Admission, Registration & Discharge Module

Max.45 Hours.

TEXT / REFERENCE BOOKS 1. Dr. L.L. Rao, Hospital Management.Annamalai University Press 2. R. D. Lele, Computers in Medicine, Tata McGraw Hill, 2008 3. Mohan Bansal, Medical informatics, Tata McGraw Hill, 2005


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SBM1606 BIOMEMS AND NANOTECHNOLOGY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To enable the student to acquire adequate knowledge on micro mechanical devices and their applications in

drug delivery and nanotechnology.

UNIT 1 INTRODUCTION 9 Hrs. MEMS – definition. Origin of MEMS – Types – Materials used and their properties. MEMS Technology. Applications in health care. Integrated MEMS and microsystem.

UNIT 2 PROCESSING: MICRO MACHINING TECHNOLOGY 9 Hrs. Lithography- etching- Ion implantation- wafer bonding- Integrated processing- Bulk micro machining- surface micro machining- coating technology and CVD-LIGA process.

UNIT 3 MICROSYSTEMS AND MICROFLUIDS 9 Hrs. General principles- Microsensors – Actuators- Electrostatic forces- Piezoelectric crystals – Intelligent materials and structures. Fundamentals of micro fluids, lab – on – a chip devices - Silicon and glass micromachining for micro total analysis systems.Surface chemistry in polymer microfluidic systems.

UNIT 4 APPLICATION IN MEDICINE 9 Hrs. Trends in MEMS for health care. Drug delivery systems - Biochip – Micro needles- Microelectrodes- Neural prosthesis – shape memory implants.

UNIT 5 BIOMEDICAL NANOTECHNOLOGY 9 Hrs. Nanotechnology- Medical applications of Nanotechnology- Drug synthesis and delivery- Nanofabrication methods – Nanomaterials in human body- Toxicity in nanomaterials. Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Tai-Ran Hsu, MEMS & Microsystem, Design and manufacture, Mc. Graw Hill 2002. 2. Malsch, NeelinaH., ed., Biomedical Nanotechnology, Washington, DC: CRC Press, 2005 3. Marc J. Madou, Fundamentals of Microfabrication and Nanotechnology, 3rd Edition, Three-Volume Set,CRC Press

2011. 4. Mohamed Gad-el-Hak, The MEMS Handbook, CRC Press, 2005 5. HocineYahia, Shape Memory Implants Springer Verlag 2000.


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SBT 1610 GMP AND QUALITY CONCEPTS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To introduce students about Good manufacturing practices quality concepts which would expose them to

industrial scenario.

UNIT 1 INTRODUCTION 9 Hrs. Basic Concepts: Quality concepts, Quality Control, Quality Assurance, Good Manufacturing Practices, Good Laboratory Practices, Responsibilities. Quality Control: Quality control laboratory: Responsibilities, good laboratory practices, routine controls, instruments, protocols.

UNIT 2 GMP 9 Hrs. Good Manufacturing Practice. Legal requirements pertaining to GMP: GMP Guidelines, Standards, Regulatory agencies. Basic Components of GMP: Organization & Personnel, Premises, Equipments, Raw Materials, Complaints and recalls, Specifications, Self inspection.

UNIT 3 GLP 9 Hrs. Good Laboratory Practice (GLP) – an overview and basic information, Scope. Principles of GLP: Test Facility Organization and Personnel, Quality Assurance Programme, Facilities, Test Systems, Test and Reference Items, Standard Operating Procedures, Performance of the Study, Reporting of Study Result, Storage and Retention of Records and Materials.

UNIT 4 INSPECTION 9 Hrs. Inspections, Quality Audit and Quality System Reviews: Inspections, role of quality audit, role of inspectors, methods of inspection- routine, concise, follow-up and special inspections, frequency and duration of inspections, preparations for inspections, conduct, report and regulatory actions.

UNIT 5 REGULATION 9 Hrs. Regulatory bodies – Need and role of regulatory bodies. Different regulatory bodies – FDA, HACCP and their scope. Importance of regulatory approval. ISO 9000 – regulations.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Sidney H. Willig, Good manufacturing Practices for Pharmaceuticals, 5th Edition, Revised and Expanded, Marcel

Dekker, Inc. New York, 2005. 2. Jose Rodriguez-Perez, The FDA and Worldwide Current Good Manufacturing Practices and Quality System

requirements guidebook for finished pharmaceuticals, American Society for Quality, ASQ Quality Press, Milwaukee, Wisconsin, 2014.


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SBT 1611 BIOLOGY FOR ENGINEERS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To understand the essentials of basic biological principles

UNIT 1 INTRODUCTION TO CELLS 9 Hrs. Cell: Functional unit of living organisms - Cell theory - Prokaryotic and eukaryotic cell – bacterial, plant, animal cells - cell components - functions- cell organization – tissues - basic types -cell division: Mitosis, meiosis, cell cycle regulation

UNIT 2 SOCIAL IMPORTANCE 9 Hrs. Application of biological sciences and biotechnology to the society - human health care and medicines - pharmaceuticals and nutraceuticals -food and agriculture- pollution management and environment - Biofuels

UNIT 3 INTRODUCTION TO BIOMOLECULES 9 Hrs. Biomolecules - classification, salient features - biological significance - carbohydrates, proteins and amino acids - lipids and fats - nucleic acids - vitamins-Enzymes

UNIT 4 HUMAN PHYSIOLOGY 9 Hrs. Human Physiology - Different systems associated with humans- Tissues, organ and physiology of the various systems: Digestive, respiratory, circulatory, skeletal, nervous, excretory and reproductive system - Artificial memory and neural network

UNIT 5 MEDICAL IMPORTANCE 9 Hrs. Infectious and non infectious diseases- causative agents, epidemiology, pathogenicity, control and prevention, treatment of AIDS, tuberculosis, Pathology of non infectious and genetic diseases and disorders - cancer, diabetes mellitus, cardiac diseases- neurological disorders-Parkinson’s disease

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Satyanarayana, U. Biotechnology, 4th Edition, Books and Allied Pvt. Ltd. Kolkata, 2007. 2. Lehninger A.L, Nelson D.L, Cox .M.M, Principles of Biochemistry. CBS Publications 1993

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks 60 Marks \

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SCY1601 SPECTROSCOPY L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To make the students to understand the basic concepts about the analytical techniques

UNIT 1 UV-VIS SPECTROSCOPY 9 Hrs. Principles of radiation – Frank condon principle – Various electronic transitions (185-800 nm) – Beer-Lambert law – Instrumentation of single beam and double beam spectrophotometer – Woodward and Fieser rule – Applications of UV-Visible spectroscopy.

UNIT 2 IR AND RAMAN SPECTROSCOPY 9 Hrs. Principles of IR spectra – Instrumentation of IR spectroscopy – Force constant – Effect of hydrogen bonding – Applications of IR spectroscopy – Raman spectroscopy: Principle – Strokes line and antistrokes line – Instrumentation – Applications of Raman spectroscopy.

UNIT 3 1H NMR AND 13C SPECTROSCOPY 9 Hrs. General introduction and definition: Chemical shift – Spin-spin interaction – Shielding mechanism – Coupling constants. Nuclear overhauser effect (NOE). Instrumentation of 1H NMR and 13C spectroscopy.

UNIT 4 MASS SPECTROMETRY 9 Hrs. Principle of Mass spectra – Instrumentation – Principle of fragmentation – Nitrogen rule – McLafferty rearrangement – Representation of Mass spectrum – Applications of mass spectra.

UNIT 5 IMAGING TECHNIQUES 9 Hrs. Scanning electron microscopy – Energy dispesrve X-ray spectroscopy – Transmission electron microscopy – Atomic force microscopy – Scanning tunneling microscopy – X-ray photoelectron spectroscopy.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Banwell C.N., and McCash E. M., “Fundamentals of Molecular Spectroscopy”, 4th Edition, Tata McGraw Hill, 2000. 2. Silverstein R. M., and Webster F. X., “Spectroscopic Identification of Organic Compounds”, 6th Edition, John Wiley & Sons,

2003. 3. Levine I. N., “Molecular Spectroscopy”, John Wiley & Sons, 1974. 4. Williams D. H., and Fleming I., “Spectroscopic Methods in Organic Chemistry”, 4th Edition, Tata McGraw-Hill Publishing

Company, 1988. 5. Kemp W., “Applications of Spectroscopy”, English Language Book Society, 1987.

END SEMESTER EXAM QUESTION PAPER PATTERN: Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each – No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks (10% problems may be asked)

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SCY1602 ENERGY SOURCES L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVE To know the various sources of energy available and to face the future challenges arising due to energy crisis.

UNIT 1 GLOBAL AND INDIAN ENERGY SCENARIO 9 Hrs. Bio-fuels − Nuclear energy − Their utilization pattern in the past, present and future projections of consumption pattern. Power sector reforms − Restructuring of energy supply sector − Energy strategy for future.

UNIT 2 HYDROGEN ENERGY 9 Hrs. Hydrogen as a renewable energy source: Sources of Hydrogen – Fuel for Vehicles. Hydrogen Production: Direct electrolysis of water – Thermal decomposition of water – Biochemical methods of hydrogen production. Storage of Hydrogen: Gaseous, Cryogenic and Metal hydride.

UNIT 3 ELECROCHEMICAL ENERGY 9 Hrs. Fuel cells: Principle of working, construction and applications of phosphoric acid fuel cell – Solid oxide fuel cell – Molten carbonate fuel cell – Polymer electrolyte membrane fuel cell. Batteries: Lead-acid battery – Nickel-cadmium battery – Lithium batteries – Nickel hydride batteries.

UNIT 4 BIOENERGY 9 Hrs. Thermo-chemical Conversion: Pyrolysis – Combustion – Gasification – Liquification. Bio-Chemical Conversion: Aerobic and Anaerobic conversion – Fermentation. Ethanol as a fuel for I.C. engines. Isolation of methane from Biogas and packing and its utilization.

UNIT 5 NUCLEAR ENERGY 9 Hrs. Nuclear Energy – Nuclear Chain reaction – Fuel enrichment – Different Types of Nuclear Reactors: Pressurised water reactor – Boiling water reactor – Fast Breeder reactor. Nuclear waste disposal – Nuclear Fusion.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Culp A. W., “Principles of Energy Conversion”, 2nd Edition, McGraw-Hill, 1991. 2. Maths D. A., “Hydrogen Technology for Energy”, Noyes Data Corp., 1976. 3. Linden D., Handbook: “Batteries and Fuel cell”, Mc.Graw Hill, 1984. 4. Bansal N. K., and Kleeman M. K., “Renewable Sources of Energy and Conversion Systems”, Tata McGraw Hill, 1990. 5. White L. P., “Biomass as Fuel”, Academic Press, 1981. 6. Raymond Murray, Keith Holbert, “Nuclear Energy: An Introduction to the Concepts, Systems, and Applications of Nuclear

Processes”, 7th Edition, Elsevier Science & Technology, 2014. 7. Arniker H. J., “Essentials of Nuclear Chemistry”, New Age Publications, 1996.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each – No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks (10% problems may be asked)

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SPH1601 ENERGY PHYSICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To expose the students to the basic principles of energy conversions, materials for energy conversion and energy storage devices.

UNIT 1 ENERGY AND THERMODYNAMICS 9 Hrs. Forms of Energy, Conservation of Energy, Entropy, Heat capacity, Thermodynamic cycles: Brayton, Carnot Diesel, Otto and Rankin cycle; Fossil fuels, time scale of fossil fuels and solar energy as an option,.

UNIT 2 ENERGY CONVERSION MATERIALS 9 Hrs. Single, poly – and amorphous silicon, GaAs, CdS, Cu2S, CuInSe2, CdTe etc. technologies for fabrication of single and polycrystalline silicon solar cells, amorphous silicon solar cells and tandem cells, solar cell modules, photovoltaic systems, space quality solar cells

UNIT 3 PHOTOVOLTAIC CONVERTORS 9 Hrs. Introduction- Photovoltaic effect-conversion of solar energy into electrical energy- behaviour of solar cells- basic structure and characteristics of solar cells-single, multi and thin film silicon solar cells-solar cell arrays- PV modules, generators-interfacing PV modules to loads, direct connection of load to PV modules and connection of PV modules to a battery and load together-energy storage alternatives to PV systems..

UNIT 4 THERMOELECTRIC CONVERTERS 9 Hrs. Thermoelectric effects, solid state description of thermoelectric effect, Kelvin’s thermodynamic relations, analysis of thermoelectric generators, basic assumptions, temperature distribution and thermal energy transfer for generator, co-efficient of performance for thermoelectric cooling,.

UNIT 5 ENERGY STORAGE DEVICES 9 Hrs. Cuprates and MgB2 superconductors and their properties, superconducting wires, Role of superconductor in Electric generator, Magnetic energy storage devices and power transmission. Energy storage systems, Faradaic and non-Faradaic processes, Types of capacitors and batteries, Comparison of capacitor and battery, Charge-discharge cycles, experimental evaluation using Cyclic voltammetry, and other techniques.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Richard C. Neville, “Solar energy conversion: The solar cell”, Elsevier Science; 2 edition, 1995 2. Peter Aue, “Advances in Energy systems and technology”, Academic Press, 1978. 3. Frank Kreith and Jang Kreider, “Principles of solar engineering”, CRC Press; 2 edition, 2000. 4. A. E. Dixon & J. D. Leslie, “Solar energy conversion”, Science Direct, 1999. 5. A.Goetzberger, V.U.Hoffmann, “Photovoltaic solar energy generation”, Springer-Verlag, 2005. 6. Castaner, S.Silvestre, “Modelling Photovoltaic systems”, Pspice John Wiley & Sons, 2002. 7. R.J.Komp, Practical Photovoltaics, “Electricity from solar cells”, 3rd edition, Aatec Publ., 2001. 8. R.Messeiger, J.Ventre, “Photovoltaic systems Engg”, 2nd edition, CRC Press, 2004. 9. Stanley W Angrist, “Direct energy conversion” (4th edition) –Allyn and Bacon, Inc., 1982 10. B. E. Conway, “Electrochemical supercapacitors”, Kluwer Academic Press. Springer US, Apr 30, 1999 11. David Linden, “Handbook of Batteries and Fuel Cells”, McGraw-Hill, 1984 12. A.G. Milnes and D. L. Feucht, “Heterojunction and metal – semiconductor junctions“, Academic Press, 1972. 13. B.G. Streetman, “Solid state electronic devices”, 5th Edition, Prentice Hall, 2000.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each – No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks - 60 Marks (10% problems may be asked)

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SPH1602 GEOPHYSICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide a qualitative idea on the fundamentals of seismology and theoretical understanding of various physical properties of earth.

UNIT 1 SEISMOLOGY 9 Hrs. Introduction-Seismology-P-waves-S waves, their velocities-the location of epicenters-Effect of Boundaries-Major discontinuities-.Seismic energy sources-Detectors-Interpretation of time and distance curves.-Derivation of properties from the velocities.

UNIT 2 INTERNAL STRUCTURE OF EARTH 9 Hrs. Introduction-Seismic waves-Rayleigh waves and love waves-Study of earth by seismic waves-Earthquake seismology-Horizontal and vertical seismograph-Seismograph equation-Internal structure of earth..

UNIT 3 EARTHQUAKES AND GRAVITY 9 Hrs. Earthquakes: Focus, Magnitude, Frequency–Detection and prediction–Gravity–Absolute and relative measurements of gravity-Worden gravimeter-Application of gravity methods.

UNIT 4 GEOMAGNETISM 9 Hrs. Geomagnetism-Definitions, magnetic field,-Measurements Proton precession magnetometer, Alkali vapour magnetometer–Theory of Earth magnetism-Dynamo theory of earth magnetism-Magnetic surveying-application.

UNIT 5 GEOCHRONOLOGY AND GEOTHERMAL PHYSICS 9 Hrs. Geochronology-Radioactivity of the earth-Radioactive dating of rocks and minerals-Geological time scale Geothermal Physics: Flow of heat to the surface of earth–Sources of heat within earth--Process of heat transport-Internal temperature of earth..

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Cook,A.H., “Physics of the Earth and Planets”, I Ed, McMillan Press, London ,1973 2. William Lourie, “Fundamentals of Geophysics”, II Ed, Cambrige University Press, 1982 3. Garland .G.D., “Introduction to Geophysics”, 11 Ed, WB Saunder Company, London.1979 4. Ramachandra Rao M.B., “Out lines of Geophysical prospecting-A manual for Geologists”, Prasaranga University of

Mysore, Mysore, 1975 5. Telford, W.M. Geldart, L. P. Sheriff R.E. and Keys .D.A., “Applied Geophysics:, Oxford–IBH Publishing Co.Pvt.Ltd. New

Delhi. 1976 6. Rama Rao.B.S., Murthy I.V.R., “Gravity and magnetic methods of prospecting”, Arnold Heinemann Publishers, New Delhi,

1978

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each – No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks - 60 Marks

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SPH1603 SPACE PHYSICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide the Windows to the Universe, Solar System, and Planetary Atmospheres and also to expose the students to the instruments related with space physics.

UNIT 1 ASTRONOMY FUNDAMENTALS, TELESCOPES FOR ASTRONOMY 9 Hrs. Radiation from space, radiation laws, Basic terminology used in astronomy, Introduction to the various types of astronomy: optical, radio, IR, UV, X-ray, γ ray, Gravitational etc. Introduction to Optical, IR, X ray, γ ray telescopes, brief description of the various instruments.

UNIT 2 RADIO TELESCOPES AND RECEIVERS 9 Hrs. Antennas, Types of interferometers, array, Radio telescopes of the world including GMRT, OOTY, PRL, Radio telescope receivers, total power receiver, Dicke receiver, correlation receiver, noise temperature. Noise sources.

UNIT 3 SOLAR SYSTEM, TERRESTRIAL AND JOVIAN PLANETS 9 Hrs. Origin of solar system, occurrence of planetary systems, celestial mechanics, properties of the sun. Orbital and physical characteristics, atmosphere, Studies of Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune and their moons. Recent explorations of various planets..

UNIT 4 SCINTILLATION, PLASMA, IONIZATION 9 Hrs. Interplanetary scintillation, interstellar scintillation, methods for probing solar wind, use of IPS in measurement of solar wind, study of irregularities in the interplanetary medium, properties of plasma at different distances from earth, photoionisation, cosmic ray ionization, meteoric ionization, various resonances in plasma, various waves in plasma, measurement procedures.

UNIT 5 DIAGNOSTIC TECHNIQUES FOR PROBING IONOSPHERE 9 Hrs. Radio wave propagation in absence and presence of magnetic field, Formation of Chapman layer, Appleton Hartree equation and its explanation, propogation of radio waves at different frequencies. Ground based, balloon based, space based techniques, Ionosonde, air glow, P.R.Radar, radio scintillation, magnetometer, Langmuir probe, electrostatic analyzer, mass spectrometer, radiosonde.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Glasstone. Van Nostrand, “Sourcebook on the Space Sciences”, Princeton, N.J., 1965 2. John Daniel Kraus Cygnus, “Radio Astronomy: Quasar Books”; 2nd edition, 1986 3. W.N.Christiansen & J.A.Hogbom, “ Radiotelescopes, Radio Telescopes”, 1st edition, Cambridge University Press 1969 4. H.Karttunem, P.Kroger, H.Oja, M.Poutanen, K.J.Donner, “Fundamental Astronomy”, Springer-Verlag; 2nd edition, 1994 5. N.Henbest, M.Marten, “The new Astronomy”, Cambridge University Press, 1996 6. S.K.Alurkar, ”Solar and Interplanetary Disturbances”, World Scientific Publishing Company, 1997. 7. J.A.Ratcliffe, “An introduction to ionosphere and magnetosphere”, Cambridge : Cambridge University Press, 1972 8. A.Giraud, M.Petit, “Ionosphere techniques and phenomena”, First Edition, D. Reidel Pub Co, 1978.


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SPH1604 ASTROPHYSICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To provide qualitative description of interesting astronomical aspect and evolution of structures in the Universe.

UNIT 1 GRAVITY 9 Hrs. Newtonian gravity and basic potential theory, Simple orbits – Kepler’s laws and precession, flat rotation curve of galaxies and implications for dark matter, virial theorem and simple applications, role of gravity in different astrophysical systems,.

UNIT 2 RADIATIVE PROCESSES 9 Hrs. Overview of radiation theory and Larmor formula, Different radiative processes : Thomson and Compton scattering, Bremsstrahlung, Synchrotron [detailed derivations are not expected] Radiative equilibrium, Planck spectrum and properties; line widths and transition rates in QT of radiation, qualitative description of which radiative processes contribute in which waveband/ astrophysical system, distribution function for photons and its moments, elementary notion of radiation transport through a slab, concept of opacities.

UNIT 3 GAS DYNAMICS 9 Hrs. Equations of fluid dynamics; equation of state in different regimes [including degenerate systems]; Models for different systems in equilibrium, Application to White dwarfs/Neutron stars, Simple fluid flows including supersonic flow, example of SN explosions and its different phases.

UNIT 4 STELLAR SYSTEM 9 Hrs. Basic equations of stellar structure, Stellar energy sources; qualitative description of numerical solutions for stars of different mass, homologous stellar models, Stellar evolution, Evolution in the HR-Diagram.

UNIT 5 GALACTIC DYNAMICS 9 Hrs. Milky Way Galaxy, Spiral and Elliptical galaxies, Galaxies as self gravitating systems; spiral structure, Supermassive black holes, Active galactic nuclei.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Bradley W. Carroll, D.A.Ostlie, “Modern Astrophysics”, Addison-Weseley, 1996. 2. Frank H. Shu,”The physical universe: An Introduction to Astronomy”, University Science books, 1982. 3. Frank H. Shu, “The Physics of Astrophysics”, Volume I and II, University Science books, 2010. 4. T. Padmanabhan, “Theoretical Astophysics”, Volumes I, II and III, Cambridge University Press; First edition,

2001. 5. Arnab Rai Choudhuri, “The Physics of fluids and plasmas”, Cambridge University Press, 1998. 6. Martin. Harwitt, “Astrophysical concepts”, 3rd edition, Springer Science & Business Media, 1998. 7. James Binney & Michael Merrifield, “Galactic Astronomy”, Princeton University Press, 1998. 8. James Binney & Scott Tremaine, “Galactic dynamics”, 2nd edition, Princeton University Press, 2008. 9. A. K. Kembhavi and J. V. Narlikar, “Quasars and Active Galactic Nuclei”, Cambridge University Press, 1999. 10. Bradley M. Peterson, “An Introduction to Active Galactic Nuclei”, Cambridge University Press, 1997.


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SPH1605 ATOMIC AND NUCLEAR PHYSICS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVE To enable the students understand the laws that govern the structure and properties of the atom, molecules and the nucleus. Also to provide an introduction to the elementary particles.

UNIT 1 IONS, ELECTRONS AND ATOMIC STRUCTURE 9 Hrs. Detection of charged particles in electric and magnetic fields-Dunnigton's method for e/m-positive ray analysis: Thomson's parabola method-Bohr's atom model-Sommerfeld's relativistic atom model-the Vector atom model and the quantum numbers-comparison with quantum model. Coupling schemes: L-S coupling and j-j coupling–Pauli’s exclusion principle-Magnetic moment due to (i) orbital motion of the electron (ii) due to spin-Stern and Gerlach experiment

UNIT 2 ATOMIC AND MOLECULAR SPECTRA 9 Hrs. Spin-orbit interaction in atomic spectra-fine structure and sodium doublet-Zeeman effect: experiment-classical result-Quantum mechanical explanation-anomalous Zeeman effect-Paschen Back effect-Stark effect (qualitative) Origin of a pure rotational spectra of a rigid linear molecule-vibrating diatomic molecule as a quantum harmonic oscillator-pure vibrational spectra-Spectroscopy (Schematic): Ultraviolet-Infrared-absorption-Raman.

UNIT 3 PROPERTIES OF NUCLEI AND RADIOACTIVITY 9 Hrs. Isobars, isotopes, mirror nuclei-Nuclear mass and binding energy-Parity-Nuclear spin–Mass defect and packing fraction-Stable nuclei–Nuclear size, nuclear magnetic moment-Electric quadrapole moment-Nuclear energy levels. Radioactivity: Range and stopping power of alpha particles.-Geiger-Nuttal law-Feature of alpha decay Tunnelling–Beta ray spectrum-Energetic of beta decay-Detection of neutrino-Gamma ray absorption in matter.

UNIT 4 NUCLEAR MODELS, FISSION AND FUSION 9 Hrs. Neutron: Discovery, Mass, Half life, Magnetic Moment, sources and detection–Shell model, Liquid drop theory-Nuclear fission–Spontaneous fission and potential barrier-Self sustaining Chain Reaction–Neutron balance in Nuclear Reactor-Uncontrolled chain reaction-Nuclear Fusion–radiation hazards and safety measures-Controlled fusion-Fusion in stars..

UNIT 5 ELEMENTARY PARTICLE PHYSICS 9 Hrs. Discovery of cosmic rays-primary and secondary rays-cosmic ray showers-discovery of positron–the mesons–origin of cosmic rays-the Big-Bang theory-thermal history of the Universe-Hubble’s law–the future of the universe-dark matter. Particles and anti-particles-antimatter-the fundamental interactions–elementary–particle quantum numbers–conservation laws and symmetry–the Quark model–quantum chromodynamics-the standard model–unification of interactions–Grand unified theories. (Qualitative).

Max. 45 Hours TEXT / REFERENCE BOOKS 1. R.Murugeshan and Kiruthiga Sivaprasath, “Modern Physics” 14thEd, S.Chand and Company Ltd, 2009 2. A.B. Gupta and Dipak Ghosh, “Atomic and Nuclear Physics”, Books and Allied(P)Ltd, Calcutta, 1997 3. Ronald Gautreau and William Savin, “Modern Physics, Schaum’s outline series, 2nd Ed., Tata McGraw Hill P.Ltd, 2004 4. K.Gopla Krishnan, Atomic and Nuclear Physics”, 3rd Ed. ,MacMillan India Ltd. 1994 5. H.S.Mani and Mehta ( G.K) , “Introduction to Modern Physics”, Affiliated EWast-West Press, 1989 6. R.P.Feynmann, R.B. Leighton and M.Sands , “The Feynmann Lectures on Physics”, Vol III, 7th Indian reprint, Narosa Pub.

Ltd, 1992


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SIT1402 MOBILE APPLICATION DEVELOPMENT L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To develop applications for current and emerging mobile computing devices, performing tasks at all stages of the

software development life-cycle. To learn how to utilize rapid prototyping techniques to design and develop sophisticated mobile interfaces. To design, implement and deploy mobile applications using an appropriate software development environment.

UNIT 1 INTRODUCTION AND UI INTERFACE 9 Hrs. Introduction to mobile technologies, mobile operation systems, Mobile devices-pros and cons, Introduction to Android, Versions, Features, Architecture, UI Widgets and Events handling, Layouts, Required tools-Eclipse, ADT, AVD, Application structure, AndroidManifest file, Android design philosophy, Creating Android applications.

UNIT 2 BUILDING BLOCKS AND DATABASES 9 Hrs. Introduction to Activities and Intents-Understanding Activity life cycle, Linking Activities, Passing Data, Toast, Displaying a Dialog Window and Notifications. Content Provider, Services, Broadcast receivers, accessing databases, sample applications, debugging and deploying app, publish in Playstore.

UNIT 3 C PROGRAMMING 9 Hrs. C- Data Types and Expressions, Decision Making and Looping, Objects and Classes, Property, Messaging, Categories and Extensions, Fast Enumeration – NSArray, NSDictionary, Methods and Selectors, Static & Dynamic objects, Exception handling, Memory management, Required Tools- Xcode, iOS Simulator, Instruments, ARC, frameworks.

UNIT 4 INTRODUCTION TO IOS 9 Hrs. Introduction to iPhone, History, Versions, Features, MVC Architecture, View Controller - Building the UI and Event handling, Application life cycle, Tab Bars, Story Boards and Navigation Controllers, Table View, Push Notification, Database handling, Debugging and Deployment, Publishing app in Appstore, sample applications.

UNIT 5 WINDOWS MOBILE APP DEVELOPMENT 9 Hrs. Introduction to Windows Phone 8, Application Life cycle, UI Designing and events, Building, Files and Storage, Network Communication, Push Notification, Background Agents, Maps and Locations, Data Access and storage,Introduction to silvelight and XAML, Running and Debugging the App, Deploying and Publishing.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Reto Meier, “Professional Android Application Development”, Wrox Edition. 2. http://www.tutorialspoint.com/android/index.htm 3. http://developer.android.com/training/index.html 4. Stephen G. Kochan, “Programming in COURSE OBJECTIVE C”, Addition Wesley, 4th Edition. 5. David Mark, Jack Nutting and Jeff LaMarche, “Beginning iOS 5 Development”, Apress Edition. 6. Baijian Yang, Pei Zheng, Lionel M. Ni, “Professional Microsoft Smartphone Programming”, Wrox Edition.

END SEMESTER QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No Choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SIT1606 BIG DATA L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To understand the dominant software systems and algorithms for coping with Big Data. Apply appropriate analytic techniques and tools to analyze big data, create statistical models, and identify

insights that can lead to actionable results To explore the ethical implications of big data research, and particularly as they relate to the web

UNIT 1 INTRODUCTION 9 Hrs. Introduction to Big Data – Challenges of Conventional Systems - Nature of Data - Small data-Medium data – Big Data – Small data vs Big data - Sources of Big Data- Big Data Characteristics – Big Data Analytics – Importance of Big Data, Big Data in the Enterprise – Big Data Enterprise Model – Building a Big Data Platform -Big data in Social and Behavioral sciences.

UNIT 2 HDFS, HADOOP AND HADOOP INFRASTRUCTURE 9 Hrs. Hadoop and Databases - Typical Datacenter Architecture - Adding Hadoop to the Mix - Key Benefit -· Flexibility: Complex Data Processing - HDFS - Hadoop Infrastructure -Architecture – Different in Data Model and Computing Model – HDFS Files and Blocks , Components of HDFS - Hadoop framework - HDFS-Map Reduce Framework-Data Loading techniques-Hadoop Cluster Architecture-Hadoop Configuration files-Hadoop Cluster modes-Single Node-Multi Node-Fully distributed node.

UNIT 3 HADOOP MAP REDUCE FRAMEWORK 9 Hrs. Relationship between MapReduce and HDFS- Relationship between MapReduce and HDFS- Clients, Data Nodes, and HDFS Storage - MapReduce workloads. Hadoop framework- Hadoop data types-Hadoop map reduce Paradigm-Map and Reduce Tasks-Map reduce Execution framework-Partitioners and Combiners-Input formats (Input Splits and Records, Text Input, Binary Input, Multiple Inputs)- Output Formats (TextOutput, BinaryOutPut, Multiple Output)- Hadoop Mapreduce programming- Advanced Map reduce concepts- Counters, Custom Writables-Unit testing framework-Error Handling-Tuning-Advanced Map reduce.

UNIT 4 HADOOP IMPLEMENTATION AND HADOOP ECO SYSTEM TOOLS 9 Hrs. Hadoop Implementation - · Job Execution - · Hadoop Data Types - · Job Configurations - · Input and Output Formats ECO system tools- Pig's Data Model, Pig Latin, Developing & Testing Pig Latin Scripts- Writing Evaluation, Filter, Load & Store Functions-Hive- Hive Architecture- Comparison with Traditional Database- HiveQL: Data Types, Operators and Functions- Hive Tables- Querying Data-Advance Hive, NoSQL Databases -HBase-Loading Data in Hbase-Querying Data in Hbase

UNIT 5 HADOOP PROJECT ENVIRONMENT 9 Hrs. HBase: Introduction to HBase, Client API's and their features, Available Client, HBase Architecture, MapReduce Integration. HBase: Advanced Usage, Schema Design, Advance Indexing, Coprocessors, Hadoop 2.0- MRv2 –YARN- NameNode High Availability, HDFS Federation, MRv2, YARN, Running MRv1 in YARN, Upgrade your existing MRv1 code to MRv2, Programming in YARN framework-cover Apache Oozie Workflow Scheduler for Hadoop

Max. 45 Hours TEXT / REFERENCES BOOKS 1. WA Gmob , “Big Data and Hadoop”, Kindle Edition, 2013 2. Eric Miller, “A Overview of Map Reduce and its impact on Distributed Data”, Kindle Edition, 2012. 3. Strata, “ Big Data Now”, O’Reily Media Inc., Kindle Edition, 2012.


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SIT1609 GAME PROGRAMMING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To provide introductions to event driven programming, game engine scripting, game engine class structures. Learning to plan and to report on a significant programming project. Learn to work in programming in teams, and learn to use standard game development environments, in

particular the Unity3d development platform.

UNIT 1 3D GRAPHICS FOR GAME PROGRAMMING 9 Hrs. Coordinate Systems, Ray Tracing, Modelling in Game Production, Vertex Processing, Rasterization, Fragment Processing and Output Merging, Illumination and Shaders, Parametric Curves and Surfaces, Shader Models, Image Texturing, Bump Mapping, Advanced Texturing, Character Animation, Physics-based Simulation

UNIT 2 GAME DESIGN PRINCIPLES 9 Hrs. Character development, Story Telling, Narration, Game Balancing, Core mechanics, Principles of level design, Genres of Games, Collision Detection, Game Logic, Game AI, Path Finding.

UNIT 3 GAMING ENGINE DESIGN 9 Hrs. Renderers, Software Rendering, Hardware Rendering, and Controller based animation, Spatial Sorting, Level of detail, collision detection, standard objects, and physics

UNIT 4 GAMING PLATFORMS AND FRAMEWORKS 9 Hrs. Flash, DirectX, OpenGL, Java, Python, XNA with Visual Studio, Mobile Gaming for the Android, iOS, Game engines - Adventure Game Studio, DXStudio, Unity.

UNIT 5 GAME DEVELOPMENT 9 Hrs. Developing 2D and 3D interactive games using OpenGL, DirectX – Isometric and Tile Based Games, Puzzle games, Single Player games, Multi-Player games.

Max. 45 Hours

TEXT REFERENCE BOOKS 1. David H. Eberly, “3D Game Engine Design, Second Edition: A Practical Approach to Real-Time Computer Graphics”

Morgan Kaufman , 2 Edition, 2006. 2. Jung Hyun Han, “3D Graphics for Game Programming”, Chapman and Hal/CRC,1st edition, 2011 . 3. Mike McShaf rfy, “Game Coding Complete”, Third Edition, Charles River Media, 2009. 4. Jonathan S. Harbour, “Beginning Game Programming”, Course Technology PTR, 3 edition, 2009. 5. Ernest Adams and Andrew Rolings, “Fundamentals of Game Design”, Prentice Hall 1st edition, 2006.


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SIT1608 GREEN COMPUTING L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To study about existing green computing strategies fundamental challenges in achieving green operations of computing units Assess enterprise-wide and personal computing and computing related energy consumption.

UNIT 1 GREEN COMPUTING FUNDAMENTALS 9 Hrs. Green IT fundamentals: Business, IT, and the environment – Green computing: Carbon foot print - scoop on power – Green IT strategies: Drivers, Dimensions, and Goals – Environmentally responsible business: Policies, Practices and Metrics.

UNIT 2 GREEN ASSETS AND MODELING 9 Hrs. Green Assets: Buildings, data centers, networks and devices – Green business process management: Modeling, optimization and collaboration – Green enterprise architecture – Environmental intelligence – Green supply chains – Green information systems: Design and development models.

UNIT 3 GRID FRAMEWORK 9 Hrs. Virtualizing of IT systems – Role of electric utilities, telecommuting, teleconferencing and teleporting – Materials recycling – Best ways for green PC – Green data center – Green grid framework

UNIT 4 GREEN COMPLIANCE 9 Hrs. Socio-cultural aspects of green IT – Green enterprise transformation roadmap – Green Compliance: protocols, standards and audits –Emergent carbon issues: technologies and future.TheWayClimate Savers Computing Initiative Do - The Climate Savers Computing Initiative - What Green Computing Impact Organization Supplies - Green Computers Initiatives - Green Computing Impact Organization Overview - Green Electronics Council - Going Green Can Be Truly Challenging - The Green Grid Framework - The CSCI Top Secrets Revealed - The EPEAT Standards - To Have a Green Computer - Green Computing Means to Save Your Money and Your Business - Finances - Green Computing Initiative Platforms.

UNIT 5 CASE STUDIES 9 Hrs. The Environmentally Responsible Business Strategies (ERBS) – Case study scenarios for trial runs – Case studies – Applying green IT strategies and applications to a home, hospital, packaging industry and telecom sector.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Bhuvan Unhelkar, “Green IT Strategies and Applications- Using Environmental Intelligence”, CRC Press, June 2011. 2. Woody Leonhard, Katherrine Murray, “Green Home computing for dummies”, August 2009. 3. Warland & Pravin Varaiya, “High Performance Communication Networks”, Jean Harcourt Asia Pvt. Ltd., II Edition, 2001. 4. Jason Harris, “Green Computing and Green IT- Best Practices onregulations & industry”, Lulu.com, 2008. 5. Alin Gales, Michael Schaefer, Mike Ebbers, “Green Data Center:steps for the Journey”, Shoff/IBM rebook, 2011. 6. John Lamb, “The Greening of IT”, Pearson Education, 2009.


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SCS1302 COMPUTER GRAPHICS AND MULTIMEDIA SYSTEMS L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To gain knowledge to develop, design and implement two and three dimensional graphical structures To enable students to acquire knowledge of Multimedia compression and animations. To learn creation, Management and Transmission of Multimedia objects.

UNIT 1 BASICS OF COMPUTER GRAPHICS 9 Hrs. Output Primitives: Survey of computer graphics – Overview of graphics systems – Line drawing algorithm – Circle drawing algorithm – Curve drawing algorithm - Attributes of output primitives – Anti-aliasing.

UNIT 2 2D TRANSFORMATIONS AND VIEWING 8 Hrs. Basic two dimensional transformations – Other transformations – 2D and 3D viewing – Line clipping – Polygon clipping – Logical classification – Input functions – Interactive picture construction techniques.

UNIT 3 3D CONCEPTS AND CURVES 10 Hrs. 3D object representation methods - B-REP , sweep representations, Three dimensional transformations. Curve generation - cubic splines, Beziers, blending of curves- other interpolation techniques, Displaying Curves and Surfaces, Shape description requirement, parametric function. Three dimensional concepts.Introduction- Fractals and self similarity- Successive refinement of curves, Koch curve and peano curves.

UNIT 4 METHODS AND MODELS 8 Hrs. Visible surface detection methods – Illumination models – Halftone patterns – Dithering techniques – Polygon rendering methods – Ray tracing methods – Color models and color applications.

UNIT 5 MULTIMEDIA BASICS AND TOOLS 10 Hrs. Introduction to multimedia - Compression & Decompression – Data & File Format standards – Digital voice and audio – Video image and animation. Introduction to Photoshop – Workplace – Tools – Navigating window – Importing and exporting images – Operations on Images – resize, crop, and rotate. Introduction to Flash – Elements of flash document – Drawing tools – Flash animations – Importing and exporting - Adding sounds – Publishing flash movies – Basic action scripts – GoTo, Play, Stop, Tell Target

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Donald Hearn, Pauline Baker M., "Computer Graphics”, 2nd Edition, Prentice Hall, 1994. 2. Tay Vaughan ,”Multimedia”, 5th Edition, Tata McGraw Hill, 2001. 3. Ze-Nian Li, Mark S. Drew ,”Fundamentals of Multimedia”, Prentice Hall of India, 2004. 4. D. McClelland, L.U.Fuller ,”Photoshop CS2 Bible”, Wiley Publishing, 2005. 5. James D. Foley, Andries van Dam, Steven K Feiner, John F. Hughes, “Computer Graphics Principles and Practice, 2nd

Edition in C, Audison Wesley, ISBN – 981-235-974-5 6. William M. Newman, Roberet F. Sproull, “Principles of Interactive Computer Graphics”, Second Edition, Tata McGraw-Hill

Edition.


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PROGRAMME: B.TECH CHEMICAL ENGINEERING CURRICULUM · B.E. / B.Tech REGULAR xxvi REGULATIONS 2015 PROGRAMME: B.TECH CHEMICAL ENGINEERING CURRICULUM SEMESTER 1 Sl. No. SUB.CODE COURSE

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