structure and syllabus of b.tech. (chemical … and syllabus of b.tech. ... solids, liquids,...

Bansilal Ramnath Agarwal Charitable Trust’s

Vishwakarma Institute of Technology (An Autonomous Institute affiliated to Savitribai Phule Pune University)

Structure and Syllabus of

B.Tech. (Chemical Engineering) Pattern ‘A16’

Effective from Academic Year 2017-18

Prepared by: - Board of Studies in Chemical Engineering

Approved by: - Academic Board, Vishwakarma Institute of Technology, Pune

Signed by,

Chairman – BOS Chairman – Academic Board

Contents

Module III, S.Y. B.TECH. Chemical Engineering ............................................................................... 3 CH201THP: PROCESS CALCULATIONS .................................................................................... 4 CH202THP: BASICS OF ENVIRONMENTAL ENGINEERING ................................................. 6

CH203THL: PHYSICAL AND INORGANIC CHEMISTRY ........................................................ 7

CH204THL: FLUID FLOW OPERATIONS ................................................................................... 9 CH205TH: STRENGTH OF MATERIALS .................................................................................. 11 HS202OPE : COSTING AND COST CONTROL ........................................................................ 13

Skill Development/Professional Development Courses (MIII/MIV), S.Y. B.TECH. Chemical Engineering ........................................................................................................................................ 15

CH206SD: COMPUTING IN MS EXCEL ................................................................................... 16 CH207SD: INDUSTRIAL VISIT .................................................................................................. 17 CH208SD: WATER TREATMENT ............................................................................................... 18 CH209SD: MATLAB .................................................................................................................... 19

CH210PS: SUMMER TRAINING ................................................................................................ 20

Module III, S.Y. B.TECH. Chemical Engineering Course No.

Course Code Course Name Contact Hours / Week Credits

Th. Proj. Based Lab

Regular Lab

S1 CH201THP Process Calculations 3 2 4 S2 CH202THP Basics of Environmental

Engineering 3 2 4

S3 CH203THL Physical and Inorganic Chemistry 3 2 4 S4 CH204THL Fluid-Flow Operations 3 2 4 S5 CH205TH Strength of Materials 3 3

HSS HS202OPE Costing and Cost Control 2 2 Following course to be offered in Semester I only SD/PD

CH206SD CH207SD CH208SD CH209SD CH210PS

Department Specific Elective Computing in MS-Excel Industrial Visits Water Treatment MATLAB Summer Training

2

Following course to be offered in Semester II only PROJ CH220PRJ Mini Project 2 2

Total 23

CH201THP: PROCESS CALCULATIONS

Credits: 04 Teaching Scheme: 05 Hours/ Week Unit 1: Basic Chemical Calculations (07 Hours) Dimensions and Units, Significance Unit conversions of mass, energy and pressure chemical calculations including mole, equivalent weight, solids, liquids, solutions and their properties, properties of gases. Non ideal calculations, for gas and liquid mixtures. Unit 2: Material Balances Without Chemical Reactions (07 Hours) Process flow sheet, Concept, Material balance calculations, Material balance of unit operations such as distillation, crystallization. Recycling, bypass and purge operations, material balance of unsteady state processes. Unit 3: Material Balances Involving Chemical Reactions (07 Hours) Mass balance with chemical reactions, single, multiple reactions, excess and limiting reactants, conversion, yield and selectivity. Material balance with recycle, bypass and purge operation. Material balance of unsteady state processes with chemical reaction. Unit 4: Energy Balance for unit operations (06 Hours) Sensible heat changes in gases, liquids and solids, latent heat of phase change,Enthalpy changes in pure substances and their mixtures, Heat of solutions, Heat of crystallisation, energy balance of unit operations, . Unit 5: Energy Balance for unit processes (06 Hours) Standard heat of formation and combustion, effect of temperature on heat of formation and Heat of reaction. Energy balance unit processes

Unit 6: Complex calculations (07 Hours) Psychometric calculations, calculations for n number of reactions, simultaneous material and energy balance, adiabatic flame temperature calculations. combustion of fuels and combustion calculations. Application of spreadsheet software in process calculations.

List of Project areas: 1. Solve problems based on units and conversions 2. Perform material balance on a chemical plant. 3. Perform energy balance on a chemical plant

Text Books

1. “Stoichiometry “ Bhatt B. I. and Thakore S. M., Tata McGraw-Hill Publication , Fifth Edition, 2010 .

2. “Basic Principles and Calculations in Chemical Engineering ”, Himmelblau D. M. Tata McGraw-Hill Publication, 7th Edition, 1997.

Reference Books 1. “Chemical Process Principles (Part I)” Hougen O. A. and Watson K. M., CBS Publishers

New Delhi, 2nd Edition, 2001. Course outcomes

Student will be able to- 1) Determine the quantities of chemicals in different mode i.e. moles and equivalent mass and

able to convert various physical quantities in different unit systems.

2) Formulate analyse and solve steady state and unsteady state material balances for unit operations and unit processes

3) Make material balances for recycling, by-passing and purging operations.

4) Perform energy balances for unit operations

5) Perform energy balances for unit processes

6) Perform Psychrometric calculations, non ideal calculations for gaseous and liquid mixtures, combustion calculations and solve complex chemical problems.

CH202THP: BASICS OF ENVIRONMENTAL ENGINEERING Credits: 04 Teaching Scheme: 03 + 02 Hours/Week

Unit 1: Introduction (06 Hours) Man interfaces with the environment, Component and factors affecting environment,Different eco systems, Environmental management-objectives and component,Environment education, world and environment

Unit 2: Water Pollution (08 Hours) Waste water characteristics and analysis, Waste water treatment and methods, Physical and Chemical unit process, Biological unit processes Unit 3: Advanced Waste Water Treatment (08 Hours) Advanced waste water treatment, Waste water treatment regulations, Water pollution in process and petrochemical industries Unit 4: Air Pollution (08 Hours) Air pollution sources and effects, Air pollution sampling and measurements, Air pollution control methods and equipments, Control of specific gaseous pollutants, Noise pollution

Unit 5: Land Pollution (06 Hours) Land pollution by different sources and its effects, Control of land pollution and strategies, Solid waste sources and types, Solid waste characteristics, collection and transportation, Waste processing and recovery

Unit 6: Environmental Acts (04 Hours) Water Act, Air Act, Environment protection act, Hazardous waste rules, Biomedical and municipal solid waste, List of Project areas: 1. Field work towards pollution control. 2. Study of working site/ model of advanced waste water treatment plant. 3. Group presentation. Text Books:

1. P. Venugopala Rao; ‘Textbook of Environmental Engineering’; Prentice Hall of India, 2002; 2. M.N.Rao; ‘Air Pollution’; Tata Mc Graw Hill Pub. Company, Ed. 5,2000

. Reference Books: 1. M.N.Rao, A.K.Datta; ‘Waste Water Treatment’; Oxford & IBH Publishing Co.Pvt. Ltd.,

2011

Course Outcomes: The students will be able to – 1. Describe sources of water, air and land pollution 2. Describe principles and methods to control water pollution. 3. Describe principles and advanced waste water treatment methods. 4. Describe principles and methods to control air pollution 5. Describe principles and methods to control soil pollution 6. Describe governing environmental acts.

CH203THL: PHYSICAL AND INORGANIC CHEMISTRY Credits: 04 Teaching Scheme: 05 Hours / Week Unit 1: Kinetics and Molecule in Motion (06 Hours) The kinetic model of gases, Molecular motion in gases and liquids, diffusion. The rates of chemical reactions- experimental techniques, the rates of reactions, Chemical Kinetics: steady state approximation, integrated rate laws, Collision theory. The temperature dependence of reaction rates. Relation between G and emf; Standard potentials, Numerical on reaction rates. Numericals on kinetics and diffusion. First Aid for Chemical Health Hazards, Health Safety and Environment Management Systems Unit 2: Surface Chemistry and Enzyme Catalysis (07 Hours) Adsorption and Chemisorptions, adsorption isotherms (Langmuir, Freundlich, B.E.T.), Chemisorptions and Catalysis, Surface Tension, Gibb's isotherm, Classification and properties of colloids, detergency and their industrial applications. Composition of enzymes, international classification of enzymes, cofactors and coenzymes, primary, secondary, tertiary and quaternary structure of enzymes, how it works as catalyst. Industrially important reactions catalyzed by enzymes. Three dimensional structure of enzymes, families of enzymes, structure of enzyme substrate complex and methods of examining them, basic equations of enzyme kinetics, enzyme inhibition. Colloidal solution, viscosity. Numerical problems on surface tension, isotherms and adsorption. Unit 3: Transition metals and their complexes (06 Hours) Trends in the periodic table; metallurgy; basic principles and applications; purification of elements and metals; transition metal ions and complexes; coordination chemistry, role of metal ions in biological processes; some relevant uses of transition elements; catalysis, Magneto-chemistry, General principles of catalysis Unit 4: Thermodynamics-I (07 Hours) First law of thermodynamics-basic terms, Joule’s experiment, Internal energy, first law, thermodyanamic state and state functions, equilibrium, the phase rule, reversible process constatnt-V and constant-P process, enthalpy, heat capacity. Volumetric properties of pure fluids- PVT behavior of pure substances, virial equation of state, the idea gas, application of virial equations, cubic equation of state.

Unit 5: Thermodynamics-II (07 Hours) Heat effects, latent heat of pure substances, standard heat of reaction, standard heat of formation, temperature dependence of ∆H°, Second law of thermodynamics, entropy, entropy changes of an ideal gas, Third law of thermodynamics, The carnot refrigerator, The vapour compression cycle, liquefaction processes Unit 6: Electrochemistry (07 Hours) Equilibrium properties of electrolyte, Electrode potentials and applications, Electrode Kinetics, Electrochemical and Electro analytical techniques, Bio electrochemistry, Electrochemical energy systems. List of Practicals:

1. Study of adsorption of acetic acid on activated charcoal from solution. 2. Measurement of radius of macromolecule by Ostwald’s viscometer.

3. To standardize Na2S2O3 solution by preparing K2Cr2O7 and to estimate percentage of Cu from brass.

4. Preparation of potassium trioxalato aluminate. 5. Preparation of Tetraamminecopersulphate. 6. To study the effect of concentration of the reactants on the rate of hydrolysis of an ester and

study of kinetics of the reaction. 7. Determination of strength of HCl solution by titrating against NaOH using PH metry. 8. Determination of amount of Ni gravimetrically as Ni-DMG. 9. Study of kinetics of iodination of acetone catalysed by acid iodometrically. 10. Determination of partition coefficient and molecular condition of benzoic acid between

benzene and water. 11. Calculation of Heat of reaction using calorimeter. 12. Synthesis and characterization of metal nanoparticles using Spectrophotometry.

Text Books:

1. B. H. Puri and L.R Sharma.; Principles of Physical Chemistry, 7th Edition S. Chand Company, New Delhi, 1994.

2. D.F Shriver.; P.W Atkins, Inorganic Chemistry, 3rd Edition, Oxford University Press, 2000. 3. G. M Barrow.; Physical Chemistry, 6th Edition, Tata McGraw Hill, 1998. 4. A.M. Mounir; Experimental inorganic and physical chemistry: An investigative, integrated

approach to practical project work; Woodhead Publishing, 1999. 5. H. Kuhn, H. D. Försterling, D. H. Waldeck; Principles of Physical Chemistry, 2nd Edition,

2009

Reference Books: 1. D.P Julio; P.W Atkins; Physical Chemistry, 8th edition, Oxford University Press, 2006. 2. J.M. Smith, H.C Van Ness, M.M. Abbot;. Introduction to Chemical Engineering

Thermodynamics, 7th Edition, Tata McGraw Hill, 2005. 3. R.Reid, J.Praunitz, T.Sherwoo;The Properties of Gases and Liquids, 3rd edition, McGraw-

Hill, New York, 1977.

Course Outcomes: The student will be able to –

1. Find out the rate of chemical reaction and different kinetic parameters e.g. order or reaction, michaelis menten kinetics and rate constant etc.

2. Get adsorption isotherms and its study e.g. surface area determination etc. 3. Find out the structure and catalytic properties of metals, its simple chemical compounds and

complex co-ordination compounds. 4. Find out different thermodynamic parameters of chemical reactions e.g. Helmholtz and

Gibbs energies, Cp and Cv. 5. Get PV diagram of pure substances, calculation and application of virial equation to

calculate volumetric parameters. 6. Get electrochemical reaction and application of the electrochemical system.

CH204THL: FLUID FLOW OPERATIONS

Credits: 04 Teaching Scheme: 05 Hours / Week

Unit 1: Fundamentals of Fluid Flow Operation (07 Hours) Fluids and properties of fluids, Newton’s law of viscosity, rheological classification of fluids pressure and temperature dependence, introduction to rheology of fluids, types of flow, lines to describe the flow. Engineering applications of fluid flow operations, Unit 2: Fluid Statics (06 Hours) The basic equation of fluid statics, pressure-depth relationship, pressure forces on surfaces, pressure measurements, pressure measuring devices. Unit 3: Momentum and Energy Balance Equations (06 Hours) Mass and energy balance equations, Bernoulli’s equation; variable head and variable area meters. Unit 4: Dimensional Analysis and Boundary Layer Theory (07 Hours) Fundamental dimension of quantities, dimensional homogeneity ,Reyleigh’s method and Buckingham’s π method, , concept of hydrodynamic boundary layer, growth over a flat plate, change in nature of boundary layer, and different thicknesses of boundary layer, drag on flat plate, coefficient of drag and its variation, hydrodynamic, thermal and concentration boundary layers Unit 5: Flow through Conduits (07 Hours) Shell balance based solutions for laminar flow through circular tube (Hagen Poiseuelle equation), on inclined plane, through annular space, Concept of Reynolds number; transition and turbulent flow in pipes, Darcy-Weisbach equation, friction factor chart Unit 6: Transportation of fluid (07 Hours) Minor losses and major losses in pipes, concept of equivalent pipe, series and parallel pipe systems, different pipe fittings and valves, cavitation and water hammer, transportation of fluids, centrifugal pump. List of Practicals:

1. Determination of viscosity of liquids 2. Pressure measurements by manometers 3. Reynolds experiment 4. Verification of Bernoulli principle 5. Calibration of venturimeter 6. Calibration of orificemeter 7. Calibration of rotameter 8. Friction in flow through pipes 9. Characteristics of centrifugal pump 10. Minor losses in pipes 11. Verification of Stokes’s law

Text Books: 1. Warren Lee McCabe, Julian Smith, Peter Harriott ; Unit Operations in Chemical Engineering., 7th edition, McGraw Hill Publications

2. Bansal R.K.; A Textbook of Fluid Mechanics and Hydraulic Machines., 9th edition., Laxmi Publications (P) Ltd Reference Books: 1. Den M.M.; Process Fluid Mechanics; 1980., Prentice Hall 2. Yunus A.Cengel and John M. Cimbala.; Fluid Mechanics-Fundamentals and Applications; 3rd edition, Tata McGraw Hill Course Outcomes: The student will be able to –

1. Determine various properties and flow behaviours. 2. Select and use manometers for pressure measurement. 3. Solve fluid flow problems by using conservation equations of mass, momentum, and energy. 4. Develop correlations using dimensional analysis. 5. Design the pipe size and flow meters requirements under laminar and turbulent flow

conditions. 6. Determine the power requirements of pumping and transportation of fluids.

CH205TH: STRENGTH OF MATERIALS Credits: 03 Teaching Scheme: 03 Hours/Week Unit 1: Stress and Strain (8 Hours) Introduction and Review: Equilibrium of a Deformable Body, types of forces, types of support and reaction offered, Coplanar Loadings, Equations of Equilibrium, ,Numerical to find internal loading/support reactions/forces on a given structure. Geometric Properties of an Area: Centroid, , use of parallel & perpendicular axis theorems to find moment of inertia of composite areas, polar moment of inertia, radius of gyration Internal forces developed in structural members ,Concept of types of actions and corresponding stresses (axia loading,bending,shear,torsion), units of stress, Saint-Venant’s Principle, Average Normal Stress and average shear stress followed by numerical, Stress on an Oblique plane under axial loading, stress under general loading conditions, Design consideration with numerical (Ultimate stress, allowable stress, Factor of safety) Hooks law of elasticity and Hooks law of shear, Normal strain, shear strain, Elastic Deformation of an Axially Loaded Member followed by numerical, AFD, Poisson’s Ratio , Generalized Hooks law, Bulk modulus Unit 2: Torsion of circular section (5 Hours) Torsional deformation of a circular determinate shaft, shear stress and angle of twist, Torsion Formula, Absolute Maximum Torsional Stress, TMD, Power Transmission, Constant Torque and Cross-Sectional Area, Multiple Torques, Design of solid circular and tubular shaft, followed by numerical. Unit 3:Shear Forces and Bending Moments (7 Hours) Concept of Shear and bending Moment Diagrams, Sign Convention, Numerical to draw SFD & BMD of Simply supported, Cantilevered ,and Overhanging beams subjected to various loading , Relation among load, shear and bending moment, concept of graphical methods to draw SFD & BMD Unit 4:Stresses in Beams (6 Hours) Bending Stresses: Pure Bending and Nonuniform Bending, Deformation of a Straight member, Application of Flexure Formula Transverse Shear Stress: Shear in Straight Members, Shear stress Formula, Numerical to find shear stress and its distribution. Design of prismatic Beams for given bending and shear stress Unit 5: Transformation of stress (8 Hours) Concept of General state of stress and Plane stress, Sign Convention, Orientation of element, General Equations of Plane-Stress on inclined plane followed by numerical, Principal stresses and maximum shear stresses, Mohr’s Circle of plane Stress with numerical Theories of Failure: For Ductile Materials (Maximum-Shear-Stress and Maximum-Distortion-Energy Theory),Brittle Materials(Maximum-Normal-Stress Theory ), Mohr’s Failure Criterion. Unit 6: Applications of Plane Stresses (6 Hours) Stresses in thin walled pressure vessels, , Principal Stresses in a Beam, Design of Transmission Shafts, Stresses under Combined Loadings Text Books: 1., F. P. Beer, E. Russell Johnston, Mechanics of Materials, Ed. 5 , McGraw-Hill education, 2012 2., R. C. Hibbler , Mechanics of Materials, 8th or 9th , Pearson Prentice Hall, 2011

3., James and Gere, Mechanics of Materials, 5th /6th , Thomson Learning, Inc, 2004 Course Outcomes: Students will be able to: 1. Calculate normal stress, shear stress ,and deformation and applications of the analysis and

design of members subjected to an axial load or direct shear 2. Analyze and design circular determinate shafts subjected to torsional loading for its shear stress

distribution and angle of twist . 3. Establish the shear force and bending moment diagrams for a beam 4. Determine bending and transverse shear stress in homogeneous beam having prismatic cross

section and design beam for a given bending moment and shear force. 5. Determine stress components by analytical and Mohr’s circle method ,for a plane state of

stress and to obtain the maximum normal and maximum shear stress along-with orientation of elements.

6. Analyze stresses developed in thin-walled pressure vessels. and to calculate resultant plane stresses in thin pressure vessels,beam,and circular shafts subjected to combined loading(axial,bending,torsion)

HS202OPE : COSTING AND COST CONTROL Credits: 02 Teaching Scheme: 02 Hours/Week Unit I (07Hrs) Cost A.Cost, Cost Centre. Cost Unit. Cost Allocation: Cost Accumulation and Apportionment.

Elements of Cost: Material Cost. Different methods of pricing of issue of materials – LIFO,

FIFO, HIFO, Weighted Average;Labour Cost: Direct & Indirect Different methods, Direct

Expenses: Constituents and Significance. Accounting for Prime Cost.

Unit II (07Hrs) Overheads

A. Classification: Production, Office & Administration, Selling & Distribution. Treatment

of Overheads: Collection of Overheads - Criteria, Primary and Secondary Distribution of

Overheads: Step Method, Reciprocal Method, Repeated Distribution Method.

Absorption of Overheads: Machine hour, labour hour rate. Preparation of Cost Sheet &

Cost Statement

Unit III (8 Hrs) Costing Methods

A. Job Costing, Unit Costing, Contract Costing, Process Costing. Simple numerical on various methods of costing to enable ascertain cost of product. Standard costing: Concept, Standard Cost, Development and Use of standard costing. Calculation of Variance Numerical on calculation of variances. B. Variance – Variance Analysis. Material variance, Labour Variance, Overhead Variance

Unit IV (07Hrs) Activity Based Costing& Transfer Pricing

A.Concept, Concept of Cost Drivers. Calculation of Costs. Mechanism of Activity Based

Costing. Transfer Pricing: Objective, Methods – Cost Based, Market Prices Based,

Negotiated Prices. Recommended procedure for Transfer Pricing

B. Limitations of Traditional Costing

Total Contact Hours: 28 Text Books : 1. Prasad N. K. ; Cost Accounting ; Book Syndicate Pvt. Ltd., Calcutta 700 009. 2. Bhattacharya A. K., “Principles and Practice of Cost Accounting”, Prentice Hall

India. 3 B K Bhar, “Cost Accounting – Methods and Problems”, Academic Publishers

Reference Books :

1. Colin Drury, “Management and Cost Accounting”, English Language Book Society, Chapman and Hall London.

2. Khan M. Y., Jain P. K., “Financial Management”, Tata McGraw Hill

Course Outcomes:

1. Classify different types of costs and apply it for ascertainment of costs of a product or a process 2. Understand and apply distribution of overheads to ascertain the cost of any product or service. 3. Apply different types of costing methods and techniques according to the suitability for various

production processes and services. 4. Understand and apply the concept of activity based costing for cost ascertainment

Skill Development/Professional Development Courses (MIII/MIV), S.Y. B.TECH. Chemical Engineering

Subject Code Subject Name

CH206SD Computing in MS-Excel

CH207SD Industrial Visits

CH208SD Water Treatment

CH209SD MATLAB

CH210SD Summer Training

CH206SD: COMPUTING IN MS EXCEL Credits: 02 Teaching Scheme: 02 Hours / Week

List of Practical (any 8)

1. Introduction to Ms Excel and basic commands. 2. Introduction to higher level commands. 3. Preparation of flow sheet and plotting of graphs. 4. To study material balance problems with excel. 5. To study energy balance problems with excel. 6. Import and Export of data. 7. Solving Heat transfer problem with excel 8. Solving Process Calculation problem with excel 9. Different operation on Matrix with excel 10. Solving different numerical methods. 11. To study preparation of mass balance. 12. Interfacing of excel with Mat lab.

Text Books

1. Bhatt B. I. and Vora S. M, “Stoichiometry”, Tata McGraw Hill Publications4th Edition, 2004.

2. McCabe W.L. and Smith J. C, “Unit operations in Chemical Engineering”, McGrawHill, 5th

edition. Reference Books

1. Himmelblau D. M., “Basic Principles and Calculations in Chemical Engineering”, Tata McGraw Hill Publications, 7th Edition, 2004.

2. Holman J. P, “Heat Tranfer”, McGraw Hill, 7th edition, 1993.

Course Outcomes: The student will be able to – 1. solve various problems with the use of a spreadsheet for technical computations 2. to use the numerical routines provided in MS Excel to carry out computational tasks.. 3. solve different Chemical engineering problems with numerical methods. 4. calculate mass balance around single equipment. 5.link data between different spreadsheet. 6. solve matrix algebra

Vishwakarma Institute of Technology Issue 01 : Rev No. 1 : Dt. 24/03/17 FF No. : 654

Structure and Syllabus of B.Tech., Chemical Engineering – Pattern A16, rev07/04/17 of 21

FF No.: 654

CH207SD: INDUSTRIAL VISIT Credits: 02 Teaching Scheme: 02 Hours /Week

List of Practical Students will visit minimum three of the industries such as below mentioned chemical process industries in and around Pune. They will study the whole process before visiting the industry. Also they will make detailed report of the visit immediately after visiting an industry. 1 Inorganic chemical industries. 2 Natural product industries. 3 Synthetic organic chemical industries. 3 Polymerization industries. 4 Metallurgical industries 5 Pollution control and toxic chemicals industries Text Books 1. M. Gopala Rao, Marshall Sittig; Dryden’s Outlines of Chemical Technology- For the 21st Century; Third Edition; Affiliated East-West Press Pvt Ltd; New Delhi Reference Books 1. Austin, George T.; Shreve's Chemical Process Industries; Fifth Edition; McGraw-Hill Course Outcomes: The student will be able to –

1. Visualize and understand the various processes in the chemical process industry 2. Visualize and understand the various processing equipment used in the chemical process

industry 3. Understand auxiliary equipment and utility lines in the process plant 4. Learn the process plant layout and equipment layout basics 5. Learn the preliminary idea on process flow, testing, inspection and quality check standards

of the process industry



CH208SD: WATER TREATMENT Credits: 02 Teaching Scheme: 02 Hours / Week

List of practical:

1. Prepare solutions of different concentrations by series of dilution 2. Determine acidity of given water sample. 3. Estimate alkalinity of water sample. 4. Estimate BOD of sample waste water. 5. Determine COD of waste water. 6. Determine pH of sample waste water. 7. Determine TDS of sample waste water. 8. Determine DO of sample waste water. 9. Determine Nitrate concentration in waste water sample. 10. Determine Sulphate concentration in waste water sample. 11. Determine Fluoride concentration in waste water sample.

List of Project areas: 1. Project on water pollution measurements 2. Proto-type model of equipment for water pollution control Text Books:

1. P. Venugopala Rao; ‘Textbook of Environmental Engineering’; Prentice Hall of India, 2002;

Reference Books: 1. A. P. Sincero and G. A. Sincero; ‘Environmental Engineering’; Prentice-Hall of India Pvt.

Ltd. 2010 2. Jerry A. Nathanson; ‘Basic Environmental Technology’; Prentice-Hall of India Pvt. Ltd.,

2005 Course Outcomes: The student will be able to –

1. Prepare solutions of different concentrations by series of dilution 2. Determine acidity of given water sample. 3. Estimate alkalinity of water sample. 4. Estimate BOD of sample waste water. 5. Determine COD of waste water. 6. Determine PH of sample waste water.



CH209SD: MATLAB Credits: 02 Teaching Scheme: 02 Hours / Week List of Practicals Required to perform minimum 10 practical from the list given below:

1. Basic introduction to MATLAB. 2. Basic arithmetic calculations in MATLAB. 3. Differential solving in MATLAB 4. Integration solving in MATLAB. 5. Double intergration solving in MATLAB 6. Plotting Mathematical function in MATLAB. 7. Plotting 2D graphs in MATLAB 8. Plotting 3D graphs in MATLAB 9. Writing and solving single variable function in MATLAB 10. Writing and solving multivariable function in MATLAB 11. Solving matrix based problems in MATLAB.

Course outcomes :

Student will be able to

1. Understand basics of matlab 2. Comprehend mathematical functions in MATLAB. 3. Understand solving differential equations in MATLAB. 4. Understand solving integration equations in MATLAB. 5. Formulate and handle functions in MATLAB. 6. Draw 2D and 3D graphs in MATLAB.



CH210PS: SUMMER TRAINING Credits: 02 Teaching Scheme: 02 Hours / Week Guidelines:

1. Students opting for Internship module should not have any LIVE backlog. 2. HoD to constitute a committee of four senior faculty members for Internship allocation. 3. Students need to maintain minimum attendance of 75% at the place of work and produce

digital record duly signed by competent authority. 4. Total Internship period is approximately 4 weeks. 5. Internship undertaken can be Industrial Internship or Research Internship. 6. Students need to submit weekly reports on Company/Research Project and Plant Study /

Research Report. 7. Final presentation (CVV) would be conducted at the end of semester.

Course Outcomes: The student will be able to –

1. Visualize the plant operation and maintenance 2. Visualize the processing operations in industry

structure and syllabus of b.tech. (chemical … and syllabus of b.tech. ... solids, liquids,...

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