|
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| Line 466: |
Line 466: |
| Shames. I.H, “Engineering Mechanics-Statics and Dynamics”, Prentice Hall of India | | Shames. I.H, “Engineering Mechanics-Statics and Dynamics”, Prentice Hall of India |
| Reference Books | | Reference Books |
| Beer.F.P and Johnson E.R, “Mechanics for Engineers-Statics and Dynamics”, McGraw Hill Publishers.
| |
| Rajasekharan and Sankarsubrahmanian, “Engineering Mechanics”, VIkas Publishing House
| |
|
| |
| Internal work assessment
| |
| 60% - Test papers (minimum 2)
| |
| 30% - Assignments/Term project/any other mode decided by the teacher. (At least one assignment should be computer based using spreadsheet or suitable tools)
| |
| 10% - Other measures like Regularity and Participation in Class.
| |
| Total Marks = 50
| |
|
| |
| University examination pattern
| |
| QI - 8 short type questions of 5 marks, 2 from each module (in which, at least 5 questions to be numerical)
| |
| QII - 2 questions of 15 marks each from module I with choice to answer anyone
| |
| QIII - 2 questions of 15 marks each from module II with choice to answer anyone
| |
| QIV - 2 questions of 15 marks each from module III with choice to answer anyone
| |
| QV - 2 questions of 15 marks each from module IV with choice to answer anyone
| |
| (QII toV can have subdivisions and at least 80% weightage for numerical problems)
| |
|
| |
| Module I: Differential Calculus (15 hours)
| |
| Indeterminate forms-L' hospital's rule- radius of curvature-centre of curvature - evolute -functions of more than one variable-idea of partial differentiation-Euler's Theorem for homogeneous functions-chain rule of partial differentiation-applications in errors and approximations-change of variables-Jacobians-maxima and minima of functions of two -method of Litgrange multipliers.
| |
|
| |
| Module II: Infinite series (15 hours)
| |
| Notion of convergence and divergence of infinite series-ratio test -comparison test-Raabe's test- root test-series of positive and negative terms-absolute convergence-test for alternating series-power series -interval of convergence-Taylors and Maclaaurins series expansion of functions-Leibnitz formula for the nth derivative of the product of two functions-use of Leibnitz formula in the Taylor and Maclaurin expansions.
| |
|
| |
| Module III: Matrices (21 hours)
| |
| Rank of a matrix- reduction of a matrix to echelon and normal forms- system of linear equations- consistency of linear equations-Gauss elimination- homogeneous linear equations-fundamental system of solutions- solution of a system of equations using matrix inversion -Eigen values and eigen vectors - Cayley-Hamilton theorem- Eigen value of Hermitian, skew-hermitian and unitary matrices- Digitalization of matrix using Eigen values and Eigen vectors-quadratic forms-matrix associated with a quadratic form -definite, semidefinite and indefinite forms.
| |
|
| |
| Module IV: Fourier series and harmonic analysis (15 hours)
| |
| Periodic functions-trigonometric series-Fourier series-Euler formulae-even and odd functions-functions having arbitrary period -half page expansions-approximation by trigonometric polynomials- minimum square error- numerical method for determining Fourier Coefficients- harmonic analysis
| |
|
| |
| Reference Books
| |
| Michael D. Greenberg, Advanced Engineering Mathematics (second edition),Pearson Education Asia.
| |
| Wylie C.R. and L.C. Barrent, Advanced Engineering Matematics, McGraw Hill
| |
| Kreyszig E, Advanced Engineering Mathematics, Wiley Eastern
| |
| Piskunov N, Differential and Integral calculus, MIR Publishers
| |
| Ayres F, Matrices, Schaum's Outline Series, McGraw Hill
| |
| Sastry, S.S, Engineering Mathematics -Vol.1 and 2, Prentice Hall of India
| |
|
| |
| Internal work assessment
| |
| 60% - Test papers (minimum 2)
| |
| 30% - Assignments/Term project/any other mode decided by the teacher.
| |
| 10% - Other measures like Regularity and Participation in Class.
| |
| Total Marks=50
| |
|
| |
| University examination pattern
| |
| QI - 8 short type questions of 5 marks, 2 from each module
| |
| QII - 2 questions of 15 marks each from module I with choice to answer anyone
| |
| QIII - 2 questions of 15 marks each from module II with choice to answer anyone
| |
| QIV - 2 questions of 15 marks each from module III with choice to answer anyone
| |
| QV - 2 questions of 15 marks each from module IV with choice to answer anyone
| |
|
| |
| == EN04-102 : MATHEMATICS II ==
| |
| (Common for all B.Tech. Programmes)
| |
| 3 hours lecture per week
| |
|
| |
| Module I: Ordinary diferential equations (21 hours)
| |
| Equations of first order-seperable, homogeneous and linear types-exact equations -orthogonal trajectories-linear second order equations-homogeneous linear equation of the second order with constant coefficients-fundamental system of solutions-Solutions of the general linear equations of second order with constant coefficients- method of variation of parameters-Cauchy's equation-simple applications of differential equations in engineering problems, including problems in mechanical vibrations, electric circuits and bending of beams
| |
|
| |
| Module II: Laplace transforms (15 hours)
| |
| Gamma and Beta functions- definitions and simple properties-Laplace transform -Inverse transform-Laplace transform-shifting theorems-Transforms of derivatives and Integrals- differentiation and integration of transforms -transforms of unit step function and impulse function-transform of periodic functions -solution of ordinary differential equations using Laplace transforms
| |
|
| |
| Module III: Vector differential calculus (15 hours)
| |
| Vector function of single variable -differentiation of vector functions-scalar and vector fields- gradient of scalar field-divergence and curl of vector fields-their physical meanings-relations between the vector differential operators
| |
|
| |
| Module IV: Vector integral calculus (15 hours)
| |
| Double and triple integrals and their evaluation -line, surface and volume integrals-Green's theorem- Gauss divergence theorem -Stocke's theorem (proofs of these theorems not expected)- line integrals independent of the path.
| |
|
| |
| Reference Books
| |
| Michael D. Greenberg, Advanced Engineering Mathematics (second edition), Pearson Education Asia
| |
| Wylie C.R. and L.C. Barrent, Advanced Engineering Mathematics, McGraw Hill
| |
| Kreyszig E, Advanced Engineering Mathematics,Wiley Eastern
| |
| Piskunov N, Differential and Integral calculus, MIR Publishers
| |
| Ayres F, Matrices, Schaum's Outline series, McGraw Hill
| |
| Sastry, S.S, Engineering Mathematics - Vol 1 and 2, Prentice Hall of India
| |
|
| |
| Internal work assessment
| |
| 60% - Test papers (minimum 2)
| |
| 30% - Assignments/Term project/any other mode decided by the teacher.
| |
| 10% - Other measures like Regularity and Participation in Class.
| |
| Total Marks=50
| |
|
| |
| University examination pattern
| |
| QI - 8 short type questions of 5 marks, 2 from each module
| |
| QII - 2 questions of 15 marks each from module I with choice to answer anyone
| |
| QIII - 2 questions of 15 marks each from module II with choice to answer anyone
| |
| QIV - 2 questions of 15 marks each from module III with choice to answer anyone
| |
| QV - 2 questions of 15 marks each from module IV with choice to answer anyone
| |
|
| |
| == EN04-103A : ENGINEERING PHYSICS(A) ==
| |
| (Common for AI, CS, EE, EC, IT, IC, BM, BT, PT)
| |
| 2 hours lecture per week
| |
|
| |
| Module I: (11 hours)
| |
| Semi conductor Physics- Formation of energy bands in solids -Classification of solids on the basis of energy band gap-Intrinsic and extrinsic semiconductors -Elemental and compound Semiconductors -Fermi level in intrinsic semiconductor-Electron and hole concentrations in intrinsic semiconductor in thermal equilibrium -law of mass action Eectrical conductivity of intrinsic semi conductor-Fermi level in n-type and p-type semiconductors-Electrical conductivity of extrinsic semi conductor-Diffusion and total current. Application of semiconductors-Band model of p-n junction- Junction diode and its characteristics - characteristics of a transistor in common emitter configuration -Input, output resistance and current amplification factor -light emitting diode, photo diode, solar cell, photo resistor (LDR) , photo transistor, liquid crystal display (LCD) and zener diode-Avalanche and zener breakdown-Application of zener diode as a voltage regulator.
| |
| Hall effect in semi conductors - Derivation of Hall coefficient-Detremination of Hall coefficient by measuring Hall voltage-Applications of Hall effect.
| |
| Super conductivity -Properties of super conductors (critical magnetic field, Meisnner effect, critical current, flux quantization)- Types of super conductors-BCS theory of super conductivity of (Qualitative)- Josephon's effect-Theory of d.c. Josephon's effect-SQUID- Applications of super conductivity.
| |
|
| |
| Module II: (11 hours)
| |
| Interference of light- Interference due to division of amplitude - Interference from plane parallel thin films-Colours of thin films in reflected and transmitted light-Newton's rings-measurement of Wavelength and refractive index-Thin wedge shaped film-Air wedge -testing of optical planeness of surfaces.
| |
| Interferometry-Michelson's interferometer-Types of fringes -Visibility of fringes-Application of Michelson's interferometer in determination of wavelength of monochromatic light, resolution of spectral lines and refractive index of gase.
| |
| Diffraction of light-Introduction of Fresnel and Fraunhoffer class of diffraction and their distinction Fresnels diffraction and rectilinear propogation of light - Diffraction pattern due to straight edge and expression for intensity maximum and minimum-Fraunhoffer diffraction- Simple theory of diffraction grating, its construction and working -Rayleigh's criteria. For resolution of spectral lines-resolving power and dispersive power of grating.
| |
|
| |
| Module III: (11 hours)
| |
| Poarisation of light-Double refraction-Huygen's explanation of double refraction in uniaxial crystals-Positive and negative crystals-Nicol prism, construction and working -quarter and half wave plates -Theory of circularly and elliptically polarized light, their production and detection -Rotatory polarization -Laurent's half shade (brief expansion)-laurent's half shade polarimeter-Applications of polarized light. Laser physics-Basic concepts and properties of laser-Spontaneous and stimulated emission - Expression for ratio of their coefficients- Absorption, population inversion and optical pumping -Construction and components of a laser -Ruby, Helium and Neon and semiconductor lasers-Application of lasers.
| |
| Basic principles of holography and its application.
| |
| Fibre optics-Basic principle-fibre dimensios and construction-Step index single mode and multi mode fibre- Graded index fibre-Numerical aperature and acceptance angle- Signal distortion in optical fibres and transmission losses (brief ideas only)-optic fibre communication (block diagram) and it's advantages-Applications of optic fibres.
| |
|
| |
| Module IV: (11 hours)
| |
| Planck's quantum theory -Absorbing power, reflecting power and transmitting power of body or surface- perfect black body-Distribution energy in the spectrum of a black body -Wein's displacement law- Planck's hypotheses-Derivation of Planck's law of radiation.
| |
| Quantum mechanics-Distinction between Newtonian and quantum mechanics-Schroedinger wave equation for free particle-Potential in Schrodinger equation-Time dependent and time independent schroedinger equations and their derivations-Expectation values-Applications-Particles in a box( motion in one dimension)
| |
| Ultrasonics-Piezo electric effect -Piezo electric crystal -Production of ultrasonics by piezo-electric oscillator-detecton of ultrasonics-general properties and applications of Ultrasonics-Ultrasonic diffractometer and determination of velocity of ultrasonic in a liquid.
| |
|
| |
| Text
| |
| Sreenivasan M.R, Physics for Engineers, New Age International
| |
| Vasudeva A.S, modern Engineering Physics, S.Shand
| |
| S.O. Pillai, Solid state Physics, New Age International
| |
| Reference books
| |
| Tyagi, M.S. Introduction to semi conductor materials and devices, John Wiley and sons
| |
| Mayer, Introduction to classical and modern optics, Arendt
| |
| John Senior, Fibre optic communication
| |
| G Aruldhas, Quantum mechanics, Prentice Hall of India
| |
| Murukesan R, Modern Physics- s.Chand and Co
| |
| Brijlal and Subrahmanyam N, Text Book of Optics, S.Chand
| |
| Kale Gokhale; Fundamentalspf Solid State Electronics, Kitab Mahal
| |
| Guptha S.L. and Kumar, V; Solid State Physics, K. Nath
| |
|
| |
| Internal work assessment
| |
| 60% - Test papers (minimum 2)
| |
| 30% - Assignments/Term project/any other mode decided by the teacher.
| |
| 10% - Other measures like Regularity and Participation in Class.
| |
| Total Marks=50
| |
|
| |
| University examination pattern
| |
| QI - 8 short type questions of 5 marks, 2 from each module
| |
| QII - 2 questions of 15 marks each from module I with choice to answer anyone
| |
| QIII - 2 questions of 15 marks each from module II with choice to answer anyone
| |
| QIV - 2 questions of 15 marks each from module III with choice to answer anyone
| |
| QV - 2 questions of 15 marks each from module IV with choice to answer anyone
| |
|
| |
| == EN04-103(P) : PHYSICS LAB(A) ==
| |
| (Common for AI, EE,EC, IC, BM, BT)
| |
| 1 hour lab per week or 2 hours lab per alternate weeks
| |
|
| |
| Band gap energy in a semi conductor using a reverse biased p-n junction.
| |
| Static characteristics of a transistor(p-n-p or n-p-n) in common emitter configuration.
| |
| Characteristic of a Zener diode
| |
| Characteristic of a LED and wave length of emitted radiation
| |
| Characteristic of a Photo diode
| |
| Characteristics of a photo resistor (LDR)
| |
| Voltage regulation using Zener diode
| |
| Wavelength of mercury spectral lines using diffraction grating and spectrometer.
| |
| Refractive indices of ordinary and extra ordinary rays in calcite or in quarts prisms.
| |
| Wave length of sodiumlight by Newton's rings method.
| |
| Diameter of a thin wire or thickness of a thin paper by air wedge method.
| |
| Specific rotatory power of cane sugar solution using polarimeter
| |
| Frequency of an electrically maintained tuning fork (transverse and longitudinal mode)
| |
| Wave length and velocity of ultrasonic waves using ultrasonic difractometer.
| |
| Divergence of laser beams using He-Ne laser or diode laser
| |
| Wave length of laser using transmission grating.
| |
| Resolving and dispersive power of a grating.
| |
| Wave length of monochromatic light by straight edge using laser beam.
| |
| Characteristics of a solar cell.
| |
| Planck's constant using photo-electric cell or solar cell
| |
| Hall coefficient by measuring Hall voltage in a semi conductor
| |
| Measurement of numerical aperature, acceptance angle and attenuation in an optical fibre.
| |
| Measurement of displacements using optic fibre.
| |
| Michelson's interferometer-Determination of wavelength of a monochromatic source, resolution of spectral lines and refractive index of gas.
| |
| (Any 12 experiments should be done)
| |
|
| |
| Reference Books
| |
| “Practical Physics with viva voice”- Dr. S.L. Guptha and Dr. V. Kumar -Publishers- Pragati Prakashan
| |
| “Experiments in Engineering Physics”- M.N. Avadhanulu, A.A. Dani and R.M. Pockley-Publishers-S.chand.
| |
| Internal work assessment
| |
| Lab practicals and record = 15
| |
| Test/s = 10
| |
| Total Marks = 25
| |
|
| |
| == EN04-104A: ENGINEERING CHEMISTRY(A) ==
| |
| (Common for AI, CS, EE, EC, IT, IC, BM, BT, PT)
| |
| 2 hours lecture per week
| |
|
| |
| SECTION -1
| |
| CHEMISTRY OF ENGINEERING MATERIALS
| |
|
| |
| Module 1 (13 hours)
| |
| Solids: Classification of solids with examples-(crystalline-Polycrystalline-Amorphous-Partially melted solids-(KCN)-Super cooled liquids-(Glass) - liquid crystals) (1 hour)
| |
| Crystalline state: Steno's law -Internal structure-Space lattices -Crystallographic axes-law of rational indices -Crystal systems -Elements of symmetry -X-ray study-Bragg's equation (derivation) single crystal and powder method -(Deybe -Scherrer Camera) Cubic systems-Structure elucidation- d100:d110:d111 ratio (problems to be worked out)-crystal imperfections (point-line-surface-volume-burgers vector- dislocations-edge and screw) Physical properties, bonding characteristics and Structure relation of - (covalent solids-Ionic solids-metals)- metallic bonding-stacking of atoms- (ABCABC……….), (ABAB……..)- tetrahedral and octahedral voids -Alloys-Hume Rothery rule -Conductivity-resistivity -(Free electron theory -explanation with Fermi-Dirac statistics ) - Fermi level-Applications of conductors-(transmission lines-OFHS Copper, ACSR, contact materials, Precision resistors- heating elements -Resistance thermometers)- Super Conductors(type I and II examples) (5 hours)
| |
| Semiconductors- Band theory -(MOT) Valence band-Conduction band-intrinsic and extrinsic semiconductors-Fabrication of semiconductor materials - Crystal Growth -ultra pure Silicon production -zone refining -fabricationof Integrated Circuits(IC) (2 hours)
| |
| Dielectric materials -Polarization-Ferro-Electricity -Piezoelectricity-Applications with examples-Introduction to Nano Science -carbon nano tubes and nano wires (1 hour)
| |
| Non-crystalline state -glass- properties- (applications- conducting glasses-solid supported liquids-(stationary phases in reverse phase chromatography)-Optical fibre (1 hour)
| |
| Liquid crystals -characterization-Nematic phase Smectic Phase -Cholestric Phases -Columnar Phases-Chemical Properties-thermotropic-lyotropic-epitaxial-growyh-Freedericksz transition-applications-Liquid crystal thermometers-LCD displays (3 hours)
| |
|
| |
| Reference
| |
| J.D. Lee (1996) “Concise Inorganic Chemistry”, Chapman and Hall Ltd. London, pp-1032
| |
| S. Glasstone (1997) “Textbook of Physical Chemistry” Macmillan, New Delhi, pp-1320
| |
| P.W. Atkins (1987) “Physical Chemistry” Oxford University Press, Oxford, pp-857
| |
| P.W. Atkins and J. Depaula (2001) “Physical Chemistry” W.H. Freeman and Co, pp-1000
| |
| V. Raghavan (2000) “Material Science and Engineering-A first Course” Fourth edition, Prentice Hall of India Pvt. Ltd., New Delhi, pp-485
| |
| L.H. Van Vlack (1998) “Elements of Materials Science and Engineering” Sixth Edition, Addison-Wesley, London pp-598
| |
| J.W. Goodby (1997) “Chemistry of liquid crystals” VCH Publishing, pp-400
| |
| K.W. Kolasinski (2002) “Surface Science: Foundations of Catalysis and Nano science” John-Wiley and Sons, pp-326
| |
| K.J. Klaubunde (2001), “Nano Scale materials in Chemistry” Wiley- interscience, pp-304
| |
| J.I. Gersten and F.W. Smith (2001) “The Physics and Chemistry of Materials” Wiley-Interscience, pp-856
| |
|
| |
| Module 2 (13 hours)
| |
| High Polymers and Lubricants-Classification of Polymers- (Natural and Synthetic, Organic and Inorganic, Thermoplastic and Thermosetting, plastics, Elastomers, Fibres and liquid resins) Polymerization (Chain polymerization Polythene-PVC-Teflon-Polystyrene-Poly-methylmethacrylate) Condensation polymerization (Polyamide and polyesters) Co-polymerization(Buna-S, Buna-N, PVC-Co-polyvinyl acetate, PAN- Co-polyvinyl chloride), Coordination polymerization (Zeigler -Natta Polymerization) - Electro chemical Polymerization-Metathetical polymerization -Group transfer Polymerization (3 hours)
| |
| Mechanism of polymerization (Cationic, anionic and free radical). Polymerization techniques ( Bulk polymerization, Solution polymerization, Suspension polymerization, Emulsion polymerization, Melt poly condensation, solution poly condensation, Interfacial condensation, Solid and Gas Phase Polymerization (2 hours)
| |
| Structure relation to properties (Chemical resistance,Strength,plastic deformation, Extensibility, Crystallinity)- Mol.Wt of polymers-Number average Molecular wt. Weight average Mol. Wt- Gel Permeation Chromatography. (1 hour)
| |
| Thermosetting resins (Bakelite, Urea-Formaldehyde, Silicones), Thermoplastic resins|(Acrylonitrile, PVC, PVA, PS, PMMA,PE)- Fibres (Nylon6, nylon66, 10, Cellulose fibres, dacron, Kevlar) Application of polymers in electronic and electrical industry. Elastomers -Natural rubber-Structure-Vulcanization-Synthetic rubbers (Neoprene, Buna-S, Buna-n, Thiokol, Silicon rubber) (3 hours)
| |
| Compounding of Plastics (Filters, Plasticizers, lubricants, pigments, antioxidants, Stabilizers) and Fabrication (Calendaring, Die casting, film casting, Compression, injection, Extrusion and Blow moulding, Thermoforming, Foaming, Reinforcing) (1 hour)
| |
| Lubricants: Theory of friction-Mechanisms of Lubrication-Fluid film or hydrodynamic, thin film or boundary lubrication, extreme pressure lubrication-Classification of Lubricants-(Liquid (animal and vegetable oils, Petroleum oils), Semi-solid, (Ca-soap grease, Li- soap grease, Al-soap grease, Axle soap grease) Solid lubricants (Di-basic acid esters, Poly glycol ethers, Organo phosphates, Organo silicones). Properties of Lubricants (Viscosity index, Cloud point and pour point, flash point and fire point, Corrosion stability, emulsification, Aniline point). Additives and their functions (Fatty acids, Sulphurised fats, Phenols, Calcium sulphonates, Organo-metallics, Hexanol, Amine phosphates, Tricresyl phosphates, Silicon polymers) (3 hours)
| |
|
| |
| Reference
| |
| B.R. Gowariker et al (2002), “Polymer Science”, New Age International pp-505
| |
| B.W. Gonser et al (1964), “Modern Materials-advances in development and application” Vol 1-7, Academic Press, New York.
| |
|
| |
| Module 3 (9 hours)
| |
| Electrochemistry: Single Electrode potential (theory-Nernst equation, derivation from thermodynamic principles)-types of electrodes (M|M+|, M|MA|A-, M|A+, A+2, Pt|Cl2|Cl-, Pt|O2|OH- -glass electrode) Electrochemical cells -concentration cells- Salt bridge -Liquid junction potential -emf measurements -Poggendorf's compensation method-digital method -electrochemical series -over voltage -theory - application in corrosion control-Polarogarphy-storage cells-lead acid, Ni/Cd- Fuel cells- H2/O2 fuel cells (Bacon cell), Hydrocarbon/air fuel cell -Bio-chemical fuel Cell (5 hours)
| |
| Acid-Bases- (Lowry-Bronsted and Lewis concepts-examples)-concept of pH -pH measurement- (instrumental details recquired)-Dissociation constants -Potentiometric titrations - (Neutralization, Oxidation-reduction and Preciptation) Buffer solutions -Henderson's equation for calculation of pH (4 hours)
| |
| Reference
| |
| S. Glasstone (1997) “Text book of Physical Chemistry” Macmillan, New Delhi, pp-1320
| |
| P.W. Atkins (1987) “Physical Chemistry” Oxford University Press, Oxford, pp-857
| |
| C.A. Hampel (Ed) (1964) ”encyclopedia of the Electro chemistry”, Reinhold Publishing Corportation, Newyork, pp.1206
| |
| A.Standen (Ed) (1964) “Kirk-Othmr Encyclopaedia of Chemical Technology”, Vol. 3, John Wiley and Sons, Inc, New York, pp-925
| |
|
| |
| SECTION-2
| |
| CHEMISTRY OF MATERIAL AND ENVIRONMENTAL DAMAGE
| |
|
| |
| Module -4 (9 hours)
| |
| Material damages and prevention: Corrosion-theoretical aspects- (electrochemical; theory) - galvanic series- Pourbiaxdiagram-assessment of corrosion potential of materials-Types of corrosion-Dry corrosion-direct chemical-Wet Corrosion-Electrochemical-differential aeration-Corrosion of Iron in acidic neutral, basic condition (Corrosion in boilers)-Galvanic corrosion- (corrosion at contact points in computers-Ag/Au)-Inter granular corrosion (18-8 Steel). Microbial corrosion-factors influencing corrosion.
| |
| Corrosion protection-Self protecting corrosion products-Pilling-Bedworth rule-Coatings -organic -(paints and polymesr)-Inorganic Coatings-Galvanizing (dip coating, Sherardizing, Wire-gun method)- Tinning-Electroplating- (Chromium, Nickel), Anodizaion of Aluminium-Passivation of metals by chemical treatment-Protection by Sacrificial Anode-Impressed current. (4 hours)
| |
| Environmental damages and prevention:
| |
| Pollution-Definitions-Classification of pollutants(Global, regional, Local; Persistent and Non persistent; Pollutants-Eg: CO2, CO, SOx, NOx, VOC, SPM, CFC, POP, Dissolved metals)-effects on environments -Air pollution-Fossil fuel burning-Automobile exhausts-Photchemical smog-PAN, PBN formation, chemical equations required)-Stratospheric Ozone depletion-CFCs-Nomenclature CFC's - Chapman cycle of Ozone formation -CFC dissociation and its reaction with Ozone-Alternate refrigerants-Monitoring of pollution -gases (CO, SO2, NOx) and particulate (High volume sampler )- Pollution from thermal power plants-Caol composition- fly ash-Thermal pollution.
| |
| Methods of control of Air pollution-Bag filters, cyclones, Scrubbing, ESP, Catalytic converters-composition and action with CO, NOx. Water pollution-pollutant classification- (Organic, Inorganic, Suspended and dissolved-Toxic metal waste-BOD-COD)-Monitoring (analytical methods- brief discussion) and control-waste water treatment- aerobic, Anaerobic- USAB process-industrial waste water treatment- solid pollution-solid waste- radio nuclides-Toxic metals-Monitoring and control -incineration-Dioxins-hazardous waste-deep-well injection (5 hours)
| |
|
| |
| Reference
| |
| L.L Shreir (Ed) “Corrosion Control” Vol I and II, Newnes-Butterworths, London
| |
| C.A. Hampel (Ed), “Encyclopaedia of Electrochemistry” Reinhold Publishing corporation, pp-1206
| |
| V. raghavan (2000), “Material Science and Engineering- A First Course”, Prentice Hall of India Pvt. Ltd, New Delhi, pp-485
| |
| A.K. De (1996), “Environmental Chemistry”, New Age International Pvt. Ltd, New Delhi, pp-364
| |
| C.N. Sawyer and P.L.McCarty (1989), “Chemistry for Environmental Engineering” McGraw Hill Book company, New Delhi, pp-530
| |
| H.S. Peavi, D.R. Rowe and G.Tchobangoglous (1985), “Environmental Engineering” McGraw hill International, pp-720
| |
| S.P. Mahajan (1985) “Pollution Control in Process Industries” Tata McGraw Hill, New Delhi, pp-273
| |
| S.E. Manahan (1975) “Environmental Chemistry”, Willard Grant Press, Boston, pp-532.
| |
|
| |
| Internal work assessment
| |
| 60% - Test papers (minimum 2)
| |
| 30% - Assignments/Term project/any other mode decided by the teacher.
| |
| 10% - Other measures like Regularity and Participation in Class.
| |
| Total Marks=50
| |
|
| |
| University examination pattern
| |
| QI - 8 short type questions of 5 marks, 2 from each module
| |
| QII - 2 questions of 15 marks each from module I with choice to answer anyone
| |
| QIII - 2 questions of 15 marks each from module II with choice to answer anyone
| |
| QIV - 2 questions of 15 marks each from module III with choice to answer anyone
| |
| QV - 2 questions of 15 marks each from module IV with choice to answer anyone
| |
|
| |
| == EN04-104A (P): CHEMISTRY LAB (A) ==
| |
| (Common for AI, EE, EC, IC, BM, BT)
| |
| 1hour lab per week or 2 hour lab per alternate weeks
| |
|
| |
| List of experiments
| |
| Estimation of purity of Copper (Iodometric method)
| |
| Estimation of purity of Aluminium (EDTA method)
| |
| Crystal growth (melt grouth, solution grouth-CuSO4,KDP,ADP crystals)
| |
| Phenol formaldehyde-preparation and study of properties
| |
| Urea formaldehyde-preparation and study of properties
| |
| Flash and fire point-Martens apparatus
| |
| Measurements of Single Electrode potential-Poggendorf's method (M|M+ M|MA|A-, Salt bridge preparation, calculation of Junction potential)
| |
| Corrosion potential measurement of certain metal and alloys in 3.5% salt solution (steel (18-8), AI, CU, Brass, Bronze, Monel metalor alloys of industrial use)- Potentiodynamics and Potentiostatics methods.
| |
| .pH meter-Caliberation and measurement of pH-preparation of Buffers- Calculation of pH by Henderson's equation and verification.
| |
| Potentiometric titration of acid and base-plots of E/V,∆E/∆V,∆2E/∆V2 plots.
| |
| electrodepostion- plating of Copper-detection of the thickness or the layer deposited. Anodizing of aluminium-characteristics of the coating.
| |
| Estimation of SO2, NO2, H2S. calculation of concentration in ppm and microgram per M3 and comparison of data with permitted levels.
| |
| Estimation of Pb, Cd in water-colourimetric method.
| |
| Estimation of Fluoride(Alizarin dye method),Nitrate in water- colourimetric method
| |
| Estimation of Dissolved oxygen (Winklers method)
| |
| Identification tests for certain common plastics(PE, PVC, Nylon, PET, etc)
| |
| Preparation of some liquid crystals and study of their properties.
| |
| (At least 12 experiments should be done)
| |
|
| |
| Internal work assessment
| |
| Lab practical and record = 10+5
| |
| (Lab performance to be evaluated by the thoroughness of the procedure practices, results of each experiments and punctuality in the submission of rough and fare records)
| |
| Test/s = 10
| |
| Total marks = 25
| |
|
| |
| == EN04-105: HUMANITIES ==
| |
| (Common for all B.Tech Programmes)
| |
| 2 Hours Lecture Per Week
| |
|
| |
| Module I: (10 hours)
| |
| Introduction to english usage and grammar-review of grammar-affixes, prefixes, suffixes, participles and gerunds-transformation of sentences-commonly misspelt words -correction of mistakes-punctuation-idioms-style-vocabulary building
| |
| Reading comprehension -exposure to a variety of reading materials, articles, essays-graphic representation, journalistic articles, etc.
| |
| Writing comprehension-skills to express ideas in sentences, paragraphs and essays.
| |
|
| |
| Module II: (10 hours)
| |
| Technical communication and report writing
| |
| Need, importance and characteristics of technical communication -correspondence on technical mattres-aspects of technical description of machinery, equivalent and processes-giving instructions in an industrial situation-note taking and note making-correspondence on technical topics-different types of technical reports
| |
|
| |
| Module III: (14 hours)
| |
| History of science and technology
| |
| Science and technology in the primitive society-the development of human civilization from primitive to modern society -impact of sciences and technology on societies-cultural and industrial revolutions-the rise and development of early indian science-contribution of indian scientist-j c boss, c v raman, visweswaraya-ramanujan and bhabha-gandhian concepts-recent advances in indian science.
| |
|
| |
| Module IV: (10 hours)
| |
| Humanities in a technological age
| |
| Importance of humanities to technology, education and society-relation of career interests of engineers to humanities-relevance of a scientific temper-science, society and culkture
| |
|
| |
| Reference Books
| |
| Huddleston R, English Grammar-An Outline, Cambridge University Press
| |
| Pennyor, Grammar Practice Activities,Cambridge University Press
| |
| Murphy, Intermediate English Grammar, Cambridge University Press
| |
| Hashemi, Intermediate English Grammar-Supplementary Exercises With Answers, Cambridge University Press
| |
| Vesilind; Engineering, Ethics And The Environment, Cambridge University Press
| |
| Larson E; History Of Inventions, Thompson Press India Ltd.
| |
| Bernal J.D, Science In History, Penguin Books Ltd
| |
| Dampier W.C, History Of Science, Cambridge University Press
| |
| Encyclopaedia Britannica, History Of Science, History Of Technology
| |
| Subrayappa; History Of Science In India, National Academy Of Science, India
| |
| Brownski J, Science And Human Values, Harper And Row
| |
| Schrodinger , Nature And Greeks And Science And Humanism, Cambridge University Press
| |
| Bossel H, Earth At A Crossroads-Paths T A Sustainable Future, Cambridge University Press
| |
| Mccarthy, English Vocabulary In Use, Cambridge University Press
| |
| Anna University, English For Engineers Andtechnologists,. Orient Longman
| |
| Meenakshi Raman Et Al, Technical Communication-Principles And Practice, Oxford University Press
| |
|
| |
| Internal assessment
| |
| One essay relevant topic 10
| |
| One technical report 10
| |
| 2 test 2x15 30
| |
| Total marks = 50
| |
|
| |
| University examination pattern
| |
| QI - 8 short type questions of 5 marks, 2 from each module
| |
| QII - 2 questions of 15 marks each from module i with choice to answer anyone
| |
| QIII - 2 questions of 15 marks each from module ii with choice to answer anyone
| |
| QIV - 2 questions of 15 marks each from module III with choice to answer anyone
| |
| QV - 2 questions of 15 marks each from module iv with choice to answer anyone
| |
|
| |
| == EN04-106A : ENGINEERING GRAPHICS (A) ==
| |
| (Common for AI, CS, EE, EC, IT, PT, BM, PT)
| |
| 1 hour lecture and 3 hours drawing
| |
|
| |
| Module 0: (8 hours- I drawing exercises)
| |
| Drawing instruments and their use-different types of lines-lettering and dimensioning-familiarization with current Indian standard code of practice for general engineering drawing. Construction of ellipse, parabola and hyperbola. Construction of cycloid, involute and helix. Introduction to computer aided drafting. (For practice only, not for university examination)
| |
|
| |
| Module I: (12 hours- 3 drawing exercises)
| |
| A) Introduction to orthographic projections -vertical, horizontal and profile palne-principles of first angle and third angle projections. Projections of points in different quadrants. Orthographic projections of straight lines parallel to one plane and inclined to the other plane-straight lines inclined to both the planes and occupied in one quadrants-traces of lines.
| |
| B) True length and inclination of a line with reference planes. Line occupied in more than one quadrant. Line inclined to the two reference planes but parallel to the profile plane. Line dimensioned in surveyor's unit.
| |
|
| |
| Module II: (16 hours- 3 drawing exercises)
| |
| A) Projections of plane laminae of geometrical shapes parallel to one plane and inclined to other plane- plane laminae inclined to both the planes.auxiliary projections of plane laminae. Projections of laminae inclined to the two reference planes but perpendicular to the profile plane.
| |
| B) Projections of polyhedra and solids of revolution -frustums-projections of solids with axis parallel to one plane and inclined to other plane. Projections of solids with the axis inclined to both the planes. (solids to be drawn: cube, prisms, pyramids, tetrahedron, cone and cylinder). Projections of solids on auxiliary planes. Projection of combinations of solids. (solids to be drawn: prisms, pyramids, tetrahedron, cube, cone, and sphere)
| |
|
| |
| Module III: (12 hours- 3 drawing exercises)
| |
| A) Sections of solids -sections by planes parallel to the horizontal or vertical planes and by planes inclined to the horizontal or vertical planes. True shape of section by projecting on auxiliary plane, (solids to be drawn: cube, prisms, pyramids, tetrahedron, cone and cylinder)
| |
| B) Development of surfaces of solids -method of parallel line, radial line, triangulation and approximate developments. Development of polyhedra, cylinder, cone and sectioned solids. Developments of solids having hole or cut.
| |
|
| |
| Module IV: (12 hours- 3 drawing exercises)
| |
| A) Introduction to isometric projection-isometric scale-isometric projections of prisms, pyramids,cylinder,cone, spheres,sectioned solids and combinations of them. Principle of oblique projection-cavalier, cabinet and general oblique projections of solids and simple objects
| |
| B) Introduction to perspective projections-classification of perspective views-parallel, angular and oblique perspectives-visual ray method and vanishing point method of drawing perspective projection-perspective views of prisms, pyramids and circles
| |
|
| |
| Module V: (12 hours- 6 drawing exercises)
| |
| A) Introduction to multiview projection of objects-the principle of the six orthographic views -conversion of pictorial views of simple engineering objects into orthographic views.
| |
| B) Conventional representation of threaded fasteners. Drawing of nuts, bolts, washers and screws. Locking arrangements of nuts. Bolted and screwed joints. Foundation bolts of eye end type hook end type and split end type.
| |
| Note: All drawing exercises mentioned above are for class work. Additional exercise where ever necessary may be given as home assignments.
| |
|
| |
| Text Books
| |
| John K.C, Engineering Graphics, Jet Publications
| |
| P.I. Varghese, Engineering Graphics, Vip Publications
| |
| Bhatt N.D, Elementary Engineering Drawing, Charotar Publishing House
| |
|
| |
| Reference Books
| |
| Luzadder W.J., Fundamentals Of Engineering Drawing,Prentice Hall Of India
| |
| Narayana K.L and Kannaiah P, Engineering Graphics, Tata Mcgraw Hill
| |
| Gill P.S., Geometrical Drawing, Kataria And Sons
| |
|
| |
| Internal work assessment
| |
| Drawing exercise (best10) 10x3 =30
| |
| 2tests 2x10=20
| |
| Total marks = 50
| |
|
| |
| University examination pattern
| |
| No question from module 0
| |
| QI - 2 questions A and B of 20 marks from module I with choice to answer anyone
| |
| QII - 2 questions A and B of 20 marks from module II with choice to answer anyone
| |
| QIII - 2 questions A and B of 20 marks from module III with choice to answer anyone
| |
| QIV - 2 questions A and B of 20 marks from module IV with choice to answer anyone
| |
| QV - 2 questions A and B of 20 marks from module V with choice to answer anyone
| |
|
| |
| == EN04-107A : ENGINEERING MECHANICS(A) ==
| |
| (Common for AI, CH, CS, EE, EC, IT, IC, BM, BT, PT)
| |
| 2 hour lecture and 1 hour tutorial per week
| |
|
| |
| Objectives
| |
| To acquaint the student with general method of analyzing engineering problems
| |
| To illustrate the application of the method to solve the practical engineering problems.
| |
|
| |
| Module I: (17 hours)
| |
| Principles of static-free body diagrams-Coplanar forces and forces and force system-resultant and equilibrium conditions for concurrent, parallel and general system of forces-solutions of problems by scalar approach. Introduction vector approach (application to simple problems only)- concurrent forces in space - resultant-equilibrium of a practical in space -Non-concurrent forces in space-resultant of force of system
| |
|
| |
| Module II: (17 hours)
| |
| Friction-loss of friction-simple contact friction problem-wedge, screw jack and its efficiency. Properties of surfaces-first moment and centroid of curve and area-centroid of composite plane figures-theorems of Pappus-guldinus-second moments of plane figures and composite sections-transfer theorem-polar moments of areas-product of areas and principal access (Conceptual level treatment only). Moment of inertia of rigid body-M.I of a lamina-M.I of 3 dimensional bodies (cylinder, circular rod, sphere)
| |
|
| |
| Module III: (17 hours)
| |
| Introduction to structural mechanics-different types of support, loads and beams-reactions and support. Shear forces and bending moments diagrams for Cantilever and simply supported beams (only for concentrated and uniformly distributed load cases).
| |
| Plane trusses-types of trusses (perfect, deficient and redundant, trusses)-Analysis of trusses-Method of joints-Method of sections.
| |
|
| |
| Module IV: (15 hours)
| |
| Kinetics of rectilinear motion-Newton's second law-D'Alembert's principle- Motion on horizontal and inclined surfaces-Analysis of lift motion- Motion of connected bodies.
| |
| Curvilinear motion-equation of motion-Tangential and normal acceleration-Centripetal and centrifugal forces-Motion of vehicles of circular path.
| |
| Work, power and energy-Work done by a force -work of the force gravity and force of spring-Work-energy equation-Transformation and conservation of energy-Applications to problems.
| |
| Kinematics of rotation-rigid body rotation about a fixed axis-rotation under the action of constant moment.
| |
| Introduction to mechanical vibrations-simple harmonic motion-free vibration-Oscillation of spring-Torsional vibration
| |
|
| |
| Text books
| |
| Timoshenko and Young, “Engineering Mechanics”, McGraw Hill Publishers
| |
| Hibbler, “Engineering Mechanics”, Vol.I statics, Vol II Dynamics, Pearson
| |
| Shames. I.H, “Engineering Mechanics-Statics and Dynamics”, Prentice Hall of India
| |
|
| |
| Reference Books
| |
| Beer.F.P and Johnson E.R, “Mechanics for Engineers-Statics and Dynamics”, McGraw Hill Publishers. | | Beer.F.P and Johnson E.R, “Mechanics for Engineers-Statics and Dynamics”, McGraw Hill Publishers. |
| Rajasekharan and Sankarsubrahmanian, “Engineering Mechanics”, VIkas Publishing House | | Rajasekharan and Sankarsubrahmanian, “Engineering Mechanics”, VIkas Publishing House |