Page 1 of 17
COURSE STRUCTURE OF M.TECH. (CHEMICAL ENGINEERING)
I Semester
Sl. No. Course No. Name of the Course L – T – P Credit
Hours
THEORY
1. CHC51101 Advanced Momentum and Heat Transfer 3 – 1 – 0 7
2. CHC51102 Advanced Mass Transfer 3 – 1 – 0 7
3. CHC51103 Advanced Chemical Engineering
Thermodynamics 3 – 1 – 0 7
4. CHC51104
Advanced Numerical Methods for Chemical
Engineers 3 – 1 – 0 7
5. HSC51153 Engineering Ethics 3 – 0 – 0 6
Total 15 – 4 – 0 34
PRACTICAL etc.
6. CHC51201 Instrumental Methods of Analysis (Lab) 1 – 0 – 2 4
7. CHC51202 Advanced Numerical Methods for Chemical
Engineers (Lab) 0 – 0 – 3 3
8. CHC51403 Term Paper and Presentation 0 – 3 – 0 3
Total 1 – 3 – 5 10
Total 16 – 7 – 5 44
Page 2 of 17
II Semester
Sl. No. Course No. Name of the Course L – T – P Credit
Hours
THEORY
1. CHC52101 Advanced Chemical Reaction Engineering 3 – 1 – 0 7
2. CHC52102 Advanced Process Control 3 – 1 – 0 7
3. Elective – I 3 – 0 – 0 6
CHE52103
CHE52104
CHE52105
CHE52106
CHE52107
CHE52108
CHE52109
Membrane Technology
Polymer Science and Engineering
Introduction to Nanotechnology
Introduction to Biochemical Engineering
Clean Coal Technology
Computational Fluid Dynamics
Green Technology
4. Elective – II 3 – 0 – 0 6
CHE52110
CHE52111
CHE52112
CHE52113
CHE52114
CHE52115
FME52101
Process Intensification
Pollution Control Engineering
Rheology of Complex Fluids
Process Modeling and Simulation
Optimization of Chemical Processes
Introduction to Fluidization Engineering
Mineral Processing
5. Elective – III 3 – 0 – 0 6
CHE52116
CHE52117
CHE52118
CHE52119
CHE52120
CHE52121
Fundamentals of Multiphase Flow
Safety Hazard and Risk Analysis
Petroleum Refining Engineering
Interfacial and Colloidal Phenomena
Mathematical Methods in Chemical Engineering
Design and Analysis of Experiments
Total 15 – 2 – 0 32
PRACTICAL etc.
6. CHC52201 Computer-aided Design of Chemical Process
Plants (Lab) 0 – 0 – 3 3
7. CHC52202 Advanced Chemical Engineering (Lab) 0 – 0 – 3 3
8. CHC52403 Term Paper and Presentation 0 – 3 – 0 3
9. CHC52504 Comprehensive Viva voce 0 – 0 – 0(4) 4
Total 0 – 3 – 6 13
Total 15 – 5 – 6 45
Page 3 of 17
III Semester
IV Semester
Sl. No. Course No. Name of the Course L – T – P Credit
Hours
1. CHC53901 Industrial Training/Minor Project 0 – 0 – 0(6) 6
2. CHC53402 Seminar and Viva voce on Industrial Training/Minor
Project 0 – 0 – 0(4) 4
3. CHC53803 Dissertation (Interim) 0 – 0 – 0(15) 15
4. CHC53404 Seminar and Viva voce on Dissertation (Interim) 0 – 0 – 0(10) 10
5. CHC53005 Evaluation of Teaching Assignment /
Laboratory Development Work etc. 0 – 0 – 0(5) 5
Total 0 – 0 – 0(40) 40
Sl. No. Course No. Name of the Course L – T – P Credit
Hours
1. CHC54801 Dissertation 0 – 0 – 0(20) 20
2. CHC54402 Seminar on Dissertation 0 – 0 – 0(5) 5
3. CHC54503 Viva voce on Dissertation 0 – 0 – 0(10) 10
4. CHC54004 Evaluation of Teaching Assignment /
Laboratory Development Work etc. 0 – 0 – 0(5) 5
Total 0 – 0 – 0(40) 40
Page 4 of 17
COURSE CONTENT OF M.TECH. (CHEMICAL ENGINEERING)
I Semester
Review of vectors and tensors; Review of basic transport processes; Phenomenological theory –
introduction, Eulerian and Lagrangian observers, equations of change integral and differential forms,
Reynolds transport theorem; Constitutive relations – Newtonian and non–Newtonian fluids;
Momentum transfer – Laminar and turbulent velocity profiles, shear stress and pressure drop in
steady, time smoothed equations for turbulent flow; Fundamentals of boundary layer theory – on flat
plate and on an obstacle, turbulent boundary layer, exact solutions of the boundary layer equations for
plane flows; Heat transfer – temperature profiles in laminar and turbulent flows, Graetz problem,
conduction profiles in solids, steady and unsteady free convection, thermal boundary layers –
equations for temperature field; time smoothed equations and analogy with momentum transfer.
Suggested Books
1. Bird, R. B., Stewart W. E., and Lightfoot, E. W., Transport Phenomena, John Wiley & Sons.
2. Brodkey, R. S., and Hershey, H. C., Transport Phenomena – A Unified Approach, McGraw–
Hill.
3. Geankopolis, C. J., Transport Processes and Separation Process Principles, Prentice Hall.
4. Schlichting, H., and Gersten, K., Boundary Layer Theory, Springer.
5. Theodore, L., Transport Phenomena for Engineers, International Textbook Company.
6. Welty, J. R., Wicks, C. E., and Wilson, R. E., Fundamentals of Momentum Heat and Mass
Transfer, John Wiley & Sons.
Introduction to multicomponent diffusion, convective mass transport, correlations for mass transfer
coefficients, review of the models for mass transfer at fluid–fluid interface; Multicomponent,
Multistage Separation – design of stage process (Kremser equation, Fenske–Underwood–Gilliland,
Wang–Henke, Naphtali–Sandholm, Thiele–Geddes); Introduction to reactive separation processes,
advantages and disadvantages of reactive separation processes; Theory of mass transfer accompanied
by reversible and irreversible reactions, reactive absorption of single gas and simultaneous absorption
of two gases; Introduction to reactive distillation; Supercritical fluid extraction.
Suggested Books
1. Astarita, G., Mass Transfer with Chemical Reaction, Elsevier.
2. Danckwerts, P. V., Gas–Liquid Reactions, McGraw–Hill.
3. Doraiswamy, L. K., and Sharma, M. M., Heterogeneous Reactions: Analysis, Examples, and
Reactor Design Vol–2: Fluid–Fluid–Solid Reactions, John Wiley & Sons.
4. Kulprathipanja, S., Reactive Separation Processes, Taylor & Francis.
CHC51101 Advanced Momentum and Heat Transfer 3 – 1 – 0
CHC51102 Advanced Mass Transfer 3 – 1 – 0
Page 5 of 17
5. Seader, J. D., and Henley, E. J., Separation Process Principles, John Wiley & Sons.
6. Treybal, R.E., Mass–Transfer Operations, McGraw–Hill.
Review of basic concepts; Comparisons between classical thermodynamics, statistical and molecular
thermodynamics; Equation of state – Soave–Redlich–Kwong, Peng–Robinson, Benedict–Webb–
Rubin, etc; Phase equilibria – liquid–liquid equilibrium, vapour–liquid equilibrium, solid–liquid
equilibrium, solid–vapour equilibrium; Chemical reaction equilibrium using thermodynamic
approach; Intermolecular forces and the theory of corresponding states, potential energy functions for
different molecular systems; Polar and non–polar molecules; Theories of solutions – van Laar,
Scatchand–Hildebrand theory, lattice theory, Flory–Huggins theory, NRTL, e–NRTL, UNIQUAC,
UNIFAC, SAFT; Thermodynamic analysis of process; Group contribution method for properties of
gases; Exergy analysis – closed system exergy balances, flow exergy, exergy rate balance for control
volumes, exergy efficiency.
Suggested Books
1. Haile, J. M., Molecular Dynamics Simulation: Elementary Methods, John Wiley & Sons.
2. Kyle, B. G., Chemical and Process Thermodynamics, Prentice Hall.
3. Moran, M. J., and Shapiro, H. N., Fundamentals of Engineering Thermodynamics, John
Wiley & Sons.
4. Poling, B. E., Prausnitz, J. M., and O'Connell, J. P., The Properties of Gases and Liquids,
McGraw–Hill.
5. Prausnitz, J. M., Lichtenthaler, R. N., and de Azevedo, E. G., Molecular Thermodynamics of
Fluid–Phase Equilibria, Prentice Hall.
6. Sandler, S.I., Chemical and Engineering Thermodynamics, John Wiley & Sons.
7. Smith, J. M., van Ness, H. C., and Abbott, M. M., Introduction to Chemical Engineering
Thermodynamics, McGraw–Hill.
Introduction to numerical methods; Error analysis; Solution of linear and nonlinear algebraic
equations – eigenvalues and eigenvectors, Gauss–Seidel method Gauss–Jordan method, LU
decomposition, TDMA, etc.; Nonlinear regression analysis; Finite differences and interpolation –
cubic, spline, Hermite polynomial; Numerical solution of simultaneous ordinary and partial
differential equations – initial value and boundary value problems, orthogonal collocation methods,
etc; Numerical solution of differential algebraic equations (DAEs); Application of numerical methods
for chemical engineering systems.
Suggested Books
1. Chapra, S. C., Applied Numerical Methods with MATLAB for Engineers and Scientists,
McGraw–Hill.
2. Davis, M. E., Numerical Methods and Modeling for Chemical Engineers, John Wiley &
Sons.
CHC51103 Advanced Chemical Engineering Thermodynamics 3 – 1 – 0
CHC51104 Advanced Numerical Methods for Chemical Engineers 3 – 0 – 0
Page 6 of 17
3. Gupta, S. K., Numerical Methods for Engineers, New Age International.
4. Hoffman, J. D., Numerical Methods for Engineers and Scientists, CRC Press.
5. Press, W. H., Flannery, B. P., Teukolsky, S. A., and Vetterling, W. T., Numerical Recipes in
C: The Art of Scientific Computing, Cambridge University Press.
6. Press, W. H., Flannery, B. P., Teukolsky, S. A., and Vetterling, W. T., Numerical Recipes in
Fortran 77: The Art of Scientific Computing, Cambridge University Press.
Introduction – why professional ethics?, responsibility in engineering; Ethical Theories and Analysis
– utilitarianism, deontology, virtue ethics, alternative ethical theories, process ethics & material ethics,
resolving problems; Safety, Risk, and Liability; Professionalism – responsibility to clients,
responsibility to employers, work place issues; Codes of Ethics (professional standard) – ACM, IEEE;
Legal Obligations – whistle blowing; intellectual property; professional integrity; The social and
value dimensions of technology; Engineering, environmental and sustainable development.
Suggested Books
1. Boatright, J. R., Ethics and the Conduct of Business, Pearson Education.
2. Ermann, M. D., and Shauf, M. S., Computers, Ethics and Society, Oxford University Press.
3. Fleddermann, C. B., Engineering Ethics, Prentice Hall.
4. Harris, C. E., Pritchard, M. S., and Rabins, M. J., Engineering Ethics: Concepts and Cases,
Wadsworth Publishing.
5. Martin, M. and Schinzinger, R., Ethics in Engineering, McGraw–Hill.
6. Martin, M. and Schinzinger, R., Introduction to Engineering Ethics, McGraw–Hill.
7. Moriarty, G., The Engineering Project: Its Nature, Ethics, and Promise, Penn State University
Press.
8. Pinkus, R. L. B., Shuman, L. J., Hummon, N. P., and Wolfe, H., Engineering Ethics:
Balancing Cost, Schedule, and Risk: Lesson Learned from the Space Shuttle, Cambridge
University Press.
9. Seebauer, E. G., and Barry, R. L., Fundamentals of Ethics for Scientists and Engineers,
Oxford University Press.
HSC51153 Engineering Ethics 3 – 0 – 0
CHC51201
Instrumental Methods of Analysis (Lab)
1 – 0 – 2
CHC51202
Advanced Numerical Methods for Chemical Engineers (Lab)
0 – 0 – 3
CHC51403
Term Paper and Presentation
0 – 3 – 0
Page 7 of 17
II Semester
Overview of isothermal reactors – batch reactor, semi–batch reactor, mixed flow reactor, plug flow
reactor for single and multiple reactions; Overview of the basics of non–ideal flow; Reactor modeling
with the RTD data – single parameter models, compartment models, convection model for laminar
flow; Mixing aspects of fluids in reactors – degree of segregation, early/late mixing; Kinetics of fluid–
particle non–catalytic reactions – application to design; Kinetics of fluid–fluid non–catalytic reactions
– application to design; Kinetics of reactions catalyzed by porous solids – effectiveness factor;
Catalyst preparation and characterization; Catalyst deactivation; Design of non–isothermal stirred
tank and packed bed reactors under steady–state and unsteady–state conditions; Analysis of reactor
stability – hot spot and runaway criteria; Design of multiphase reactors – fluidized bed reactor, trickle
bed reactor, and slurry reactor.
Suggested Books
1. Carberry, J. J., Chemical and Catalytic Reaction Engineering, McGraw–Hill.
2. Fogler, H. S., Elements of Chemical Reaction Engineering, Prentice Hall of India.
3. Froment, G. F., Bischoff, K. B., and De Wilde, J., Chemical Reactor Analysis and Design,
John Wiley & Sons.
4. Hill, C. G., An Introduction to Chemical Engineering Kinetics & Reactor Design, John Wiley
& Sons.
5. Levenspiel, O., Chemical Reaction Engineering, Wiley India.
6. Levenspiel, O., The Chemical Reactor Omnibook, Oregon State University Bookstores.
7. Schmidt, L. D., The Engineering of Chemical Reactions, Oxford University Press.
8. Shah, Y. T., Gas–Liquid–Solid Reactor Design, McGraw–Hill.
9. Smith, J. M., Chemical Engineering Kinetics, McGraw–Hill.
Introduction to dynamic analysis of chemical processes – transfer function and state–space
representation; Stability analysis in transfer function and state–space domain; Design of conventional
controller – Ziegler Nichols tuning, empirical methods of tuning; Model based control – internal
model control and direct synthesis; Complex control schemes – cascade control, feed–forward control
and ratio control; Control of MIMO processes; Model predictive control.
Suggested Books
1. Bequette, B. W., Process Control: Modeling, Design and Simulation, Prentice Hall.
2. Luyben, W. L., Process Modeling, Simulation and Control for Chemical Engineers, McGraw–
Hill.
3. Marlin, T. E., Process Control: Designing Processes and Control Systems for Dynamic
Performance, McGraw–Hill.
4. Nagrath, I. J., and Gopal, M., Control Systems Engineering, New Age International.
5. Ogata, K., Modern Control Engineering, Prentice Hall.
CHC52101 Advanced Chemical Reaction Engineering 3 – 1 – 0
CHC52102 Advanced Process Control 3 – 1 – 0
Page 8 of 17
6. Ogunnaike, B. A., and Ray, W. H., Process Dynamics, Modeling and Control, Oxford
University Press.
7. Seborg, D. E., Mellichamp, D. A., Edgar, T. F., and Doyle, F. J., Process Dynamics and
Control, John Wiley & Sons.
8. Stephanopoulos, G., Chemical Process Control: An Introduction to Theory and Practice,
Prentice Hall.
Elective – I (Any one)
Introduction to membrane separation processes; definitions and terminologies; classification of
membrane processes; preparation and characterization of membranes; Theories of mass transport in
membrane; transport resistance at membrane surface; principles of reverse osmosis, nanofiltration,
ultrafiltration, microfiltration, osmotic controlled filtration, desalination; detailed design and
modeling; design of membrane modules; gas permeation membrane processes – types of membranes
and permeability for separation of gases, types of equipment for gas permeation membrane processes;
basic design of gas separation and pervaporation; liquid membrane; introduction to membrane reactor;
membrane contactor, membrane distillation.
Suggested Books
1. Bungay, P. M., Lonsdale, H. K., and de Pinho, M. N., Synthetic Membranes: Science,
Engineering and Applications, NATO ASI Series.
2. Ho, W. S. W., and Sirkar, K. K., Membrane Handbook, Springer.
Elective – I 3 – 0 – 0
Elective – II 3 – 0 – 0
Elective – III 3 – 0 – 0
CHC52201
Computer–aided Design of Chemical Process Plants (Lab)
0 – 0 – 3
CHC52202
Advanced Chemical Engineering (Lab)
0 – 0 – 3
CHC52403
Term Paper and Presentation
0 – 3 –0
CHC52504
Comprehensive Viva voce
0 – 0 – 0(4)
CHE52103 Membrane Technology 3 – 0 – 0
Page 9 of 17
3. Li, N.N., Fane, A. G., Ho, W. S. W., and Matsuura, T., Advanced Membrane Technology and
Applications, John Wiley & Sons.
4. Rousseau, R. W., Handbook of Separation Process Technology, John Wiley & Sons.
Overview of different polymerization techniques; Technology of polymerization – specific technology
of polymerization, polystyrene, LDPE, HDPE, LLDPE, nylons, butyl rubber, polypropylene, PVC and
PET, copolymerization techniques, SBR and ABS; Kinetics of polymerization, modeling of
polymerization, polymerization reactor design–copolymerization and gas–phase polymerization;
Polymer processing – processing of thermoplastics and thermosetting plastics, compounding, fillers,
plasticizers, coupling agents, antidegradants, cross–linking agents, stabilizers, lubricants, colorants,
and antioxidants, machines for compounding.
Suggested Books
1. Biesenberger J. A., and Sebastian, D. H., Principles of Polymerization Engineering, John
Wiley & Sons.
2. Billmeyer, F. W., Textbook of Polymer Science, John Wiley & Sons.
3. Brazel, C. S., and Rosen, S. L., Fundamental Principles of Polymeric Materials, John Wiley &
Sons.
4. Fried, J. R., Polymer Science & Technology, Prentice Hall of India.
5. Kumar, A., and Gupta, S. K., Fundamentals of Polymer Science and Engineering, Tata
McGraw–Hill.
6. McCrum, N. G., Buckley, C. P. and Bucknall, C. B., Principles of Polymer Engineering,
Oxford University Press.
7. Middleman, S., Fundamentals of Polymer Processing, McGraw–Hill.
8. Tadmor, Z., and Gogos, C. G., Principles of Polymer Processing, John Wiley & Sons.
9. Young, R. J., and Lovell, P. A., Introduction to Polymers, CRC Press.
Introduction to nanotechnology – history, definitions, particle size, chemistry and physics of
nanomaterials, safety issues with nanoscale powders; Preparation of nanomaterials – top down and
bottom up approach; Morphology of nanomaterials; Nanocomposites – nanofillers, high performance
materials, polymer nanocomposites, nanoclays, nanowires, nanotubes, nanoclusters etc.; Introduction
to micro–electromechanical systems (MEMS), nano–electromechanical systems (NEMS) and
nanoelectronics; Introduction to bionanotechnology and nanomedicines.
Suggested Books
1. Ajayan, P. M., Schadler, L. S., and Braun, P. V., Nanocomposite Science and Technology,
Wiley–VCH.
2. Regis, E., Nano: The Emerging Science of Nanotechnology, Back Bay Books.
3. Cao, G., and Wang, Y., Nanostructures and Nanomaterials: Synthesis, Properties, and
Applications, World Scientific.
CHE52104 Polymer Science and Engineering 3 – 0 – 0
CHE52105 Introduction to Nanotechnology 3 – 0 – 0
Page 10 of 17
4. Ying, J., Nanostructured Materials, Academic Press.
5. Fahrner, W. R., Nanotechnology and Nanoelectronics: Materials, Devices, Measurement
Techniques, Springer.
6. Goddard, W. A., Brenner, D. W., Lyshevski, S. E., and Iafrate, G. J., Handbook of
Nanoscience, Engineering, and Technology, CRC Press.
7. Pradeep, T., Nano: The Essentials – Understanding Nanoscience and Nanotechnology,
McGraw–Hill.
Introduction to kinetics of microbial growth and product formation; Introduction of structured,
unstructured, segregated and unsegregated kinetic models; Enzyme kinetics – immobilization
techniques, kinetics of immobilized enzymes and cells; Metabolic stoichiometry and energetics;
Modeling and design of different bioreactors; Scale up, operation and control of bioreactors;
Recombinant DNA technology; Downstream processing in bioprocesses; Industrial application of
bioprocesses.
Suggested Books
1. Bailey, J. E., and Ollis, D. F., Biochemical Engineering Fundamentals, McGraw–Hill.
2. Blanch, H. W., and Clark, D. S., Biochemical Engineering, Marcel Dekker.
3. Doran, P. M., Bioprocess Engineering Principles, Academic Press.
4. Rao, D. G., Introduction to Biochemical Engineering, Tata McGraw–Hill.
5. Shuler, M. L., and Kargi, F., Bioprocess Engineering: Basic Concepts, Prentice Hall.
Chemical and physical characteristics of coal; Introduction to coal utilisation technologies; Coal
combustion, carbonisation, gasification and liquefaction; Combustion – coal stochiometry,
conventional combustion appliances and coal fired power plant; Introduction to clean coal technology
– pre–combustion coal cleaning methods including biological and chemical cleaning methods; Clean
coal technologies for advance power generation – power cycle, PC fired power plant, different type of
FBC process, Integrated coal gasification combined cycle; Emission and carbon management;
Emission control strategies and technology for power plant; CO2 capture and storage; Synthetic crude
from coal, Clean coal application in iron making; UCG, CBM, CWM/COM.
Suggested Books
1. de Souza–Santos, M. L., Solid Fuels Combustion and Gasification, CRC Press.
2. Khartchenko, N. V., Green Power: The Eco–Friendly Energy Engineering, Tech Books
International.
3. Miller, B G., Clean Coal Engineering Technology, Butterworth–Heinemann.
CHE52106 Introduction to Biochemical Engineering 3 – 0 – 0
CHE52107 Clean Coal Technology 3 – 0 – 0
Page 11 of 17
Introduction to computational fluid dynamics; Governing equations of fluid dynamics and heat
transfer; Turbulence modelling; Discretization of the governing equations using finite difference,
finite volume and finite element methods; Properties of discretization schemes, finite volume method
for convection diffusion problems and for unsteady state flow; Structured and unstructured grid
generation and implementation of boundary conditions; Solution algorithms and techniques for
discretized equations; Presentation and validation of CFD results.
Suggested Books
1. Anderson, J. D., Computational Fluid Dynamics: The Basics with Applications, McGraw–
Hill.
2. Chung, T. J., Computational Fluid Dynamics, Cambridge University Press.
3. Fletcher, C. A. J., Computational Techniques for Fluid Dynamics, Vol. 1: Fundamental and
General Techniques, Springer.
4. Fletcher, C. A. J., Computational Techniques for Fluid Dynamics, Vol. 2: Specific
Techniques for Different Flow Categories, Springer.
5. Patankar, S. V., Numerical Heat Transfer and Fluid Flow, Taylor & Francis.
6. Tu, J., Yeoh, G. H., and Liu, C., Computational Fluid Dynamics: A Practical Approach,
Butterworth–Heinemann.
7. Versteeg, H. K., and Malalasekera, W., An Introduction to Computational Fluid Dynamics:
The Finite Volume Method, Prentice Hall.
Concepts of green chemistry and technology; Materials for green chemistry and technology – green
reagents, environmentally benign industrial green catalysis, biocatalysis for industrial processes,
biodegradable polymers, alternative solvents, ionic liquids; Green synthetic methods –
microwave/ultrasound mediated synthesis, electro–organic synthesis; Design and development of
environmentally benign chemical pathways – challenges and opportunities, high–yield and zero–
waste chemical processes, representative processes; Green–energy – thermo–chemical conversion,
combustion, gasification, liquefaction, cogeneration; Biochemical conversion – anaerobic digestion,
alcohol production from biomass; Chemical conversion process – oxidation, hydrolysis and
hydrogenation; Photo–initiated synthesis; Applications and future trends.
Suggested Books
1. Anastas, P., and Warner, J. C., Green Chemistry: Theory and Practice, Oxford University
Press.
2. Clarke, J. H., and Maacquarrie, D., Handbook of Green Chemistry and Technology, Wiley–
Blackwell.
3. Koichi, T., Solvent–free Organic Synthesis Green Chemistry, Wiley–VCH.
4. Matlack, A., Introduction to Green Chemistry, CRC Press.
5. Tundo, P., Perosa, A., and Zecchini, F., Methods and Reagents for Green Chemistry: An
Introduction, Wiley Inter science.
CHE52108 Computational Fluid Dynamics 3 – 0 – 0
CHE52109 Green Technology 3 – 0 – 0
Page 12 of 17
Elective – II (Any one)
Introduction to process intensification – advantages, mechanisms involved; Mixing in intensified
equipment; Compact and micro–heat exchangers; Reactors with enhanced performance – spinning
disc reactors, microreactors, cavitation reactors, microwave reactors; Intensification of separation
processes; HiGee concept; Energy integration in distillation column – vapour recompression cycle,
doubled wall distillation, Petlyuk column; Mass exchange network; Application of process
intensification in process industries – case studies.
Suggested Books
1. Reay, D., Ramshaw, C., and Harvey, A., Process Intensification: Engineering for Efficiency,
Sustainability and Flexibility, Butterworth–Heinemann.
2. Stankiewicz, A. and Moulijn, J. A., Re–engineering the Chemical Process Plant: Process
Intensification, Marcel Dekker.
Introduction to air pollution control; Air pollution control laws and regulations; air pollution
measurements; Mathematical modeling – dispersion model, etc.; Air pollution control techniques;
nature of particulate pollutants; Design of particulate control equipment – bag filter, cyclone
separator, ESP, etc.; Control of volatile organic compounds; Gaseous emission control by adsorption,
absorption, combustion, oxidation and catalytic conversion; Control of specific gaseous pollutants –
SOx, NOx, automotive emission control devices. Sources and classification of water pollutants;
Standards and regulations in water pollution; Wastewater treatment techniques – primary, secondary
and advanced techniques; Sedimentation, chemical precipitation, filtration, biological treatment –
activated sludge process, aerated lagoons, trickling filter, chemical oxidation; Design of ETP.
Sources, classification and management of solid waste; Methods of collection and disposal methods;
Pollution control in selected process industries – sugar industries, dairy, alcohol industries, petroleum
refineries and petrochemical units, fertilizer industries, pulp and paper industries, radioactive wastes.
Suggested Books
1. Davis, M. L., and Cornwell, D. A., Introduction to Environmental Engineering, McGraw–
Hill.
2. de Nevers, N., Air Pollution Control Engineering, Waveland Press.
3. Mahajan, S. P., Pollution Control in Process Industries, Tata McGraw–Hill.
4. Metcalf and Eddy, Wastewater Engineering: Collection, Treatment and Disposal, McGraw–
Hill.
5. Rao, C. S. Environmental Pollution Control Engineering, New Age International.
6. Schnelle, K. B., and Brown, C. A. Air Pollution Control Technology Handbook, CRC Press.
7. Wark, K., Warner, C. F., and Davis, W. T., Air Pollution: Its Origin and Control, Prentice
Hall.
CHE52110 Process Intensification 3 – 0 – 0
CHE52111 Pollution Control Engineering 3 – 0 – 0
Page 13 of 17
Introduction to rheology; Mathematical concepts – tensors, index notation, operations with tensors,
kinematics, deformation measures, balances of mass and momentum, frame invariance; Rheometry,
types of rheometer and rheometric measurements – stress, strain, velocity gradient, strain rate, shear
flow, extensional flow; Rheometric models – viscous fluids, Newtonian, generalized Newtonian
viscoelastic materials, Maxwell, Jeffreys; Macroscopic models – governing equations, constitutive
relations, linear viscoelastic materials, time temperature superposition, relaxation time spectrum non–
linear models; Microscopic models – microscopic origin of stress, elastic dumbbell model, overview
of other models, Rouse, Zimm, Doi–Edwards (reptation).
Suggested Books
1. Bird, R. B., Armstrong, R. C., and Hassager, O., Dynamics of Polymeric Liquids, Volume 1
Fluid Mechanics, John Wiley & Sons.
2. Deshpande A. P., Murali K. J., and Kumar. S., Rheology of Complex Fluids, Springer.
3. Larson, R. G., The Structure and Rheology of Complex Fluids, Oxford University Press.
4. Thien, N. P., Understanding Viscoelasticity: An Introduction to Rheology, Springer.
Basic concepts of process modeling, tools and approaches of simulation; Various modeling techniques
– phenomenological, stochastic and empirical; Multiscale modeling techniques, AI based models –
ANN, Fuzzy and hybrid; Development of mathematical model of process equipments in heat and
mass transfer, and reaction engineering; Simulation and analysis of results.
Suggested Books
1. Aris, R., Mathematical Modeling: A Chemical Engineer’s Perspective, Academic Press.
2. Bequette, B. W., Process Control: Modeling, Design and Simulation, Prentice Hall.
3. Denn, M. M., Process Modeling, Longman.
4. Hangos, K. M., and Cameron, I. T., Process Modelling and Model Analysis, Academic Press.
5. Holland, C. D., Fundamentals and Modeling of Separation Processes, Prentice Hall.
6. Luyben, W. L., Process Modeling, Simulation, and Control for Chemical Engineers,
McGraw–Hill.
7. Najim, K., Process Modeling and Control in Chemical Engineering, CRC Press.
8. Ramirez, W. F., Computational Methods for Process Simulation, Butterworth–Heinemann.
Introduction to process optimization – formulation of optimization problem, classification of
optimization problems; Review of classical optimization techniques – single and multi variable
optimization, Kuhn–Tucker conditions; Nonlinear programming – unconstrained and constrained
optimization, steepest descent; Dynamic programming – multistage decision processes, computational
CHE52112 Rheology of Complex Fluids 3 – 0 – 0
CHE52113 Process Modeling and Simulation 3 – 0 – 0
CHE52114 Optimization of Chemical Processes 3 – 0 – 0
Page 14 of 17
procedure in dynamic programming; Mixed–integer programming – problem formulation; Solving
MINLP problems using branch–and–bound methods; Solving MINLPs using outer approximation.
Suggested Books
1. Beveridge, G. S. G., and Schechter, R. S., Optimization: Theory and Practice (Chemical
Engineering), McGraw–Hill.
2. Deb, K., Multi–Objective Optimization using Evolutionary Algorithms, John Wiley & Sons.
3. Edgar, T. F., Himmelblau, D. M., Lasdon, L. S., Optimization of Chemical Processes,
McGraw–Hill.
4. Rangaiah G. P., Multi–Objective Optimization: Techniques and Applications in Chemical
Engineering, World Scientific.
5. Rao, S. S., Engineering Optimization Theory and Practice, John Wiley & Sons.
6. Ray, W. H., and Szekely, J., Process Optimization with Applications in Metallurgy and
Chemical Engineering, John Wiley & Sons.
Onset and types of fluidization; Characteristics, advantages, disadvantages and industrial applications
of fluidized beds; Minimum–fluidization velocity, pressure drop–velocity relationship, mapping of
fluidization regimes; Types and characteristics of distributor; Models for single rising bubbles and
bubbling fluidized beds; Entrainment and elutriation from fluidized beds; Solid–to–gas heat and mass
transfer characteristics of gas fluidized beds; Design of fluidized bed reactors – cases studies on
catalytic and non–catalytic fluid–solid reactions.
Suggested Books
1. Davidson, J. F., and Harrison, D., Fluidization, Academic Press.
2. Kunii, D., and Levenspiel, O., Fluidization Engineering, Butterworth–Heinemann.
3. Leva, M., Fluidization, McGraw–Hill.
Introduction to mineral processing, scope and importance; Basic unit operations, relative merits and
demerits of processing of ores, definition ore, mineral, gangue, concentrate, tailing, yield, recovery
and ratio of concentration etc.; Comminution – fundamentals of size reduction, purpose, liberation of
minerals, degree of liberation, comminution laws, different types of crushers and grinding mills, their
features and usages; Screening – measurement of particle size, introduction to various size separation
processes and their importance, types of screens, factors influencing screening, screening surfaces and
screen efficiency; Classification – movements of solids in fluid, hindered settling, free settling, equal
settling particles; Reynolds number and its importance; Types of classifiers, their principles and
operations; Concentration operations – types of different gravity concentration units i.e. jigging,
tabling and spiral concentrators, their principles, features and applications; Flotation – fundamental
and practice of flotation, types of reagents and their importance, critical pH curves, flotation circuits,
CHE52115 Introduction to Fluidization Engineering 3 – 0 – 0
FME52101 Mineral Processing 3 – 0 – 0
Page 15 of 17
mass balance. Magnetic and electro–static separation – principles, different types of magnetic and
electrical separators, their features and applications; Dewatering – thickening, filtration and drying
principles and practices.
Suggested Books
1. Gaudin, A. M., Principles of Mineral Dressing, Tata McGraw–Hill.
2. Gupta, A., and Yan, D. S., Mineral Processing Design and Operations – An Introduction,
Elsevier.
3. Jain, S. K., Mineral Processing, CBS Publishers.
4. Kelly, E. G., and Spottiswood, D. J., Introduction to Mineral Processing, John Wiley & Sons.
5. Wills, B. A., Mineral Processing Technology, Butterworth–Heinemann.
Elective – III (Any one)
Introduction to multiphase flow, basic terminology, flow regimes; Motion of single particle and
bubbles in fluids; Bubble growth and collapse in the absence and presence of thermal effects;
Cavitation; Boiling and condensation; Granular flows; Multiphase flow modeling – homogeneous
flow model, separated flow model and drift flux model; Introduction to three–phase flow;
Measurement methods to determine multiphase flow parameters – pressure drop, holdup and flow
rate.
Suggested Books
1. Brennen, C. E., Fundamentals of Multiphase Flows, Cambridge University Press.
2. Butterworth, D., and Hewitt, G. F., Two–phase Flow and Heat Transfer, Oxford University
Press.
3. Crowe, C. T., Multiphase Flow Handbook, CRC Press.
4. Crowe, C. T., Sommerfeld, M., and Yutaka, T., Multiphase Flows with Droplets and Particles,
CRC Press.
5. Govier G. W., and Aziz, K., The Flow of Complex Mixtures in Pipes, Van Nostrand.
6. Hetsroni, G., Handbook of Multiphase Systems, Hemisphere Publishing.
7. Hewitt, G. F., Measurement of Two Phase Flow Parameters, Academic Press.
8. Wallis, G. B., One–dimensional Two–Phase Flow, McGraw–Hill.
Plant safety and safety regulation – importance and objectives of safety, safety in chemical industry,
criteria for setting and layout of chemical plant, factories act and safety regulations; Plant Hazards –
fire, chemical, toxic, explosion, electrical, mechanical and radiation hazards; Control, precautions and
prevention; Standard operating procedure; Safety audit – objective and procedure, audit and safety
reports; Storage and transportation of chemicals – characteristics of chemical with special reference to
safe storage and handling of chemicals, layout of storage, various modes of transport and safety
CHE52116 Fundamentals of Multiphase Flow 3 – 0 – 0
CHE52117 Safety Hazard and Risk Analysis 3 – 0 – 0
Page 16 of 17
precautions in transportation of different types of chemicals; Risk management principles – risk
analysis techniques, hazard and operability (HAZOP) studies, hazard analysis (HAZAN), fault–tree
analysis, consequence analysis, onsite and offsite emergency management plans, human and accident
error analysis, economics of risk management; Specific case studies.
Suggested Books
1. Fawcett, H. H., and Wood, W. S., Safety and Accident Prevention in Chemical Operations,
John Wiley & Sons.
2. Haight, J. M., Handbook of Loss Prevention Engineering, Volume 1, John Wiley & Sons.
3. Handley, W., Industrial Safety Handbook, McGraw–Hill.
4. Mannan, S., Lees' Loss Prevention in the Process Industries: Hazard Identification,
Assessment and Control (3 Volumes), Butterworth–Heinemann.
Introduction; Evaluation of crude oil properties and ASTM methods and standards, concept of ASTM,
TBP, EFV distillation; Process flowsheet of distillation process – ADU and VDU; Crude oil
processing – desalting, distillation, cracking, reforming, hydrotreating, isomerization, alkylation,
polymerization, lube oil manufacturing; Design of crude oil distillation column; Furnace design;
Environmental issues and new trends in petroleum refinery operations.
Suggested Books
1. Gary, J. H., Handwerk, G. E., and Kaiser, M. J., Petrolem Refining: Technologies and
Economics, CRC Press.
2. Meyers, R. A., Handbook of Petroleum Refining Processes, McGraw Hill.
3. Nelson, W. L., Petroleum Refinery Engineering, Mc Graw Hill.
4. Rao, B. K. B., Modern Petroleum Refining Processes, Oxford & IBH.
5. Speight, J. G., The Chemistry and Technology of Petroleum, CRC Press.
6. Watkins, R. N., Petroleum Refinery Distillation, Gulf Publishing Co.
Surface tension, adhesion and capillarity – concepts of surface and interfacial energies and tensions,
Young–Laplace equation of capillarity, examples of equilibrium surfaces, multiplicity, etc., surface
modification; Stability of equilibrium solutions, contact angle and Young's equation, free energies of
adhesion; Kinetics of capillary and confined flows; Mesoscale thermodynamics – Gibbs treatment of
interfaces, concept of excess concentration, variation of interfacial tensions with surfactant
concentration; Emulsions – emulsion formation, some mechanistic details of stabilization, solubility
parameters; Surfactants; Stability of nanoparticle dispersions – DLVO theory and kinetics of
coagulation plus general principles of diffusion in a potential field/Brownian movement; Advanced
and functional interfaces – superhydrophobicity, functional coatings, structural colors, nano–
adhesives, nanocomposites; Modeling of interfacial phenomena.
CHE52118 Petroleum Refining Engineering 3 – 0 – 0
CHE52119 Interfacial and Colloidal Phenomena 3 – 0 – 0
Page 17 of 17
Suggested Books
1. Hiemenz, P. C., and Rajagopalan, R., Principles of Colloid and Surface Chemistry, Marcel
Dekker.
2. Masliyah, J. H., and Bhattacharjee, S., Electrokinetic and Colloid Transport Phenomena, John
Wiley & Sons.
3. Myers, D., Surfaces, Interfaces, and Colloids: Principles and Applications, John Wiley &
Sons.
Mathematical statement of the physical problem; Formulation and solution of ordinary and partial
differential equations for chemical engineering problems; Sturm–Louiville theory; Separation of
variables and Fourier transforms; Laplace transforms; Solution by series – Bessel’s equation.
Suggested Books
1. Jenson, V. G., and Jeffreys, G. V., Mathematical Methods in Chemical Engineering,
Academic Press.
2. Mickley, H. S., Sherwood, T. K., and Reed, C. E., Applied Mathematics in Chemical
Engineering, Tata McGraw Hill.
3. Pushpavanam, S., Mathematical Methods in Chemical Engineering, Prentice Hall of India.
4. Rice, R. G., and Do, D. D., Applied Mathematics and Modeling for Chemical Engineers, John
Wiley & Sons.
Introduction to statistics for engineers – the simplest discrete and continuous distributions, statistical
inference, statistical estimation, tests and estimates on statistical variance, analysis of variance and
covariance, regression analysis, correlation analysis; Design and analysis of experiments –
introduction to design of experiments (DOE), screening experiments, basic experiment –
mathematical modeling, statistical analysis, experimental optimization, response surface
methodology; Planning of experiments – Taguchi method, central composite design, full factorial
combined with mixture design.
Suggested Books
1. Goos, P., and Jones, B., Optimal Design of Experiments: A Case Study Approach, John
Wiley & Sons.
2. Lazic, Z. R., Design of Experiments in Chemical Engineering: A Practical Guide, Wiley–
VCH.
3. Montgomery, D. C., Design and Analysis of Experiments, John Wiley & Sons.
CHE52120 Mathematical Methods in Chemical Engineering 3 – 0 – 0
CHE52121 Design and Analysis of Experiments 3 – 0 – 0
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