TE Chemical Engineering Sem V and VI1_1 Syllabus Mumbai University by munotes
Page 2
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme AC- 29/06/2021
Item No. : 6.3
UNIVERSITY OF MUMBAI
Bachelor of Engineering
in
Chemical Engineering
Third Year Syllabus with Effect from AY 2021 -22
(REV - 2019 ‘C’ Scheme) from Academic Year 2019 – 2020
Under
FACULTY OF SCIENCE & TECHNOLOGY
(As per AICTE guidelines with effect from the academic
year 2019 –2020 )
Page 4
2
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme
Date:
Dr. S. K. Ukarande Dr Anuradha Muzumdar
Associate Dean Dean
Faculty of Science and Technology Faculty of Science and Technology
University of Mumbai University of Mumbai Sr. No. Heading Particulars
1 Title of the Course Third Year Bachelor of C hemical Engineering
2 Eligibility for Admission
After Passing Second Year Engineering as per the
Ordinance 0.624 3
3 Passing Marks 40%
4 Ordinances /
Regulations ( if any) Ordinance 0.624 3
5 No. of Years / Semesters 8 semesters
6 Level Under Graduation
7 Pattern
Semester
8 Status Revised
9 To be implemented from
Academic Year With effect from Academic Year: 2021 -2022
AC – 29/06/2021
Item No. -6.3
UNIVERSITY OF MUMBAI
Syllabus for Approval
Page 5
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Preamble
To meet the challenge of ensuring excellence in engineering education, the issue of quality needs to be
addressed, debated and taken forward in a systematic manner. Accreditation is the principal means of
quality assurance in higher education. The major emphasis of accreditation process is to measure t he
outcomes of the program that is being accredited. In line with this Faculty of Science and Technology
(in particular Engineering)of University of Mumbai has taken a lead in incorporating philosophy of
outcome based education in the process of curriculum development.
Faculty resolved that course objectives and course outcomes are to be clearly defined for each course,
so that all faculty members in affiliated institutes understand the depth and approach of course to be
taught, which will enhance learner’ s learning process. Choice based Credit and grading system enables
a much -required shift in focus from teacher -centric to learner -centric education since the workload
estimated is based on the investment of time in learning and not in teaching. It also foc uses on
continuous evaluation which will enhance the quality of education. Credit assignment for courses is
based on 15 weeks teaching learning process, however content of courses is to be taught in 13 weeks
and remaining 2 weeks to be utilized for revisio n, guest lectures, coverage of content beyond syllabus
etc.
There was a concern that the earlier revised curriculum more focused on providing information and
knowledge across various domains of the said program, which led to heavily loading of students in
terms of direct contact hours. In this regard, faculty of science and technology resolved that to minimize
the burden of contact hours, total credits of entire program will be of 170, wherein focus is not only on
providing knowledge but also on building s kills, attitude and self -learning. Therefore in the present
curriculum skill based laboratories and mini projects are made mandatory across all disciplines of
engineering in second and third year of programs, which will definitely facilitate self -learning of
students. The overall credits and approach of curriculum proposed in the present revision is in line with
AICTE model curriculum.
The present curriculum will be implemented for Third Year of Engineering from the academic year
2021 -21. Subsequently this will be carried forward for Final Year Engineering in the academic years
2022 -23.
Dr. S. K. Ukarande Dr Anuradha Muzumdar
Associate Dean Dean
Faculty of Science and Technology Faculty of Science and Technology
University of Mumbai University of Mumbai
Page 6
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Preamble to the Revision of Syllabus in Chemical Engineering
Development in all fields including Chemical Engineering along with use of soft wares for process
plant and process engineering, there is demand on academician to upgrade the curriculum in
Education. Choice based Credit and grading system enab les a much required shift in focus from
teacher -centric to learner -centric education since the workload estimated is based on the
investment of time in learning and not in teaching. The Curriculum must integrate knowledge of
the basic and advanced sciences with problem solving and creativity abilities.
The Curriculum must be broad enough to cover all areas from design to operation of Process plants.
It should be deep enough to enable the learners to carry out research and develop products to meet
rapidly changing needs and demands. The major challenge in the current scenario is to ensure
quality to the stakeholders. Accreditation is the principal means of quality assurance in higher
education and reflects the fact that in achieving recognition, the institu tion or program of study is
committed and open to external review to meet certain minimum specified standards. The major
emphasis of this accreditation process is to measure the outcomes of the program that is being
accredited. Program outcomes are essenti ally a range of skills and knowledge that a student will
have at the time of graduation from the program.
With these objectives, online meeting was organized on 30th May 2020 which was attended by
heads of the departments and subject faculty of affiliating Institutes. The program objectives and
outcomes were thoroughly discussed in line with AICTE guidelines and the core structure of the
syllabus was formulated keepin g in mind choice based credit and grading system curriculum along
with more emphasis on learning outcomes. Thus Skilled based laboratories and Mini projects are
introduced in appropriate semesters. Views from experts and UG teachers were taken into
conside ration and final Academic and Exam scheme was prepared with the consent of all the
members involved. Subject wise online meetings were held by various subjects convenors to
finalize the detail syllabus of semester V and VI in the month of December 2020.
The Program Educational Objectives finalized for the undergraduate program in Chemical
Engineering are:
1. To prepare the student for mathematical, scientific and engineering fundamentals
2. To motivate the student to use modern tools for solving real life pro blems
3. To inculcate a professional and ethical attitude, good leadership qualities and commitment
to social and environmental responsibilities.
4. To prepare the student in achieving excellence which will benefit individually and society
at large.
Board of Studies in Chemical Engineering
Dr. Parag R Gog ate - Chairman
Dr. Kalpana S. Deshmukh - Member
Dr. Sunil J. Kulkarni - Member
Dr. Ramesh S. Bhande - Member
Dr. Shyamala P. Shingare - Member
Dr. Manisha V. Bagal - Member
Page 7
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme University of Mumbai
Program Structure for B.E. Chemical Engineering (Revised 2019 ) wef 2021 -2022
Semester V
Course code
Course Name
Teaching Scheme
(Contact Hours) Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
CHC501 Mass transfer Operations -I 3 - - 3 - - 3
CHC502 Heat transfer Operations 3 - - 3 - - 3
CHC503 Chemical Reaction
Engineering -I 3 - - 3 - - 3
CHC504 Transport Phenomena 3 - - 3 - - 3
CHDO501X Department Optional
Course 1 3 - - 3 - - 3
CHL501 Mass transfer Operations -I
Lab - 3 - - 1.5 - 1.5
CHL502 Heat transfer Operations
Lab - 3 - - 1.5 - 1.5
CHL503 Chemical Reaction
Engineering -I Lab - 3 - - 1.5 - 1.5
CHL504 Skilled Based Lab:
Professional
Communication and Ethics
II Lab - 2*2 - - 2 - 2
CHM501 Mini Project -2A - 3# - - 1.5 - 1.5
Total 15 14 - 15 8 - 23
Course code
Course Name
Examination Scheme
Theory
Term
Work Pract
/Oral Oral Total Internal Assessment End
Sem
Exam Exam
Duration
(in hrs) Test
1 Test
2 Avg
CHC501 Mass transfer Operations -I 20 20 20 80 3 - - - 100
CHC502 Heat transfer Operations 20 20 20 80 3 - - - 100
CHC503 Chemical Reaction
Engineering -I 20 20 20 80 3 - - - 100
CHC504 Transport Phenomena 20 20 20 80 3 - - - 100
CHDO501X Department Optional
Course 1 20 20 20 80 3 - - - 100
CHL501 Mass transfer Operations -I
Lab - - - - 3 25 25 - 50
CHL502 Heat transfer Operations
Lab - - - - 3 25 25 - 50
CHL503 Chemical Reaction
Engineering -I Lab - - - - 3 25 25 - 50
CHL504 Skilled Based Lab:
Professional
Communication and Ethics
II Lab - - - - - 25 - 25 50
CHM501 Mini Project -2A - - - - - 25 - 25 50
Total 100 400 - 125 75 50 750
Department Optional Course 1 (Semester V)
Engineering Stream (Elective
Code) Technology Stream (Elective Code) Management Stream
Food Engineering(CHDO5011) Advanced Material Sciences
(CHDO5012) Total Quality Management
(CHDO5013)
*Indicates Theory class to be conducted for full class;
# indicates work load of Learner (Not Faculty), for mini project.
For mini project faculty load: 1 hour per week per four groups
Page 8
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme University of Mumbai
Program Structure for B.E. Chemical Engineering (Revised 2021 -2022)
T.E Semester VI
Course code
Course Name
Teaching Scheme
(Contact Hours) Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
CHC601 Mass Transfer Operation II 3 - - 3 - - 3
CHC602 Chemical Reaction
Engineering II 3 - - 3 - - 3
CHC603 Pollution Control
Technology 3 - - 3 - - 3
CHC604 Process Engineering and
Economics 3 - 1 3 - 1 4
CHDO602X Departmental Optional
Course 2 3 - - 3 - - 3
CHL601 Mass Transfer Operation II
Lab - 3 - - 1.5 - 1.5
CHL602 Chemical Reaction
Engineering II Lab - 3 - - 1.5 - 1.5
CHL603 Pollution Control
Technology Lab - 3 - - 1.5 - 1.5
CHL604 Skilled Based Lab: Piping
Design Engineering Lab - 3 - - 1.5 - 1.5
CHM601 Mini Project – 2B - 2# - - 1 - 1
Total 15 14 1 15 7 1 23
Course code Course Name
Examination Scheme
Theory
Term
Work Pract/
Oral Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs.) Test 1 Test
2 Avg
CHC601 Mass Transfer Operation II 20 20 20 80 3 - - - 100
CHC602 Chemical Reaction
Engineering II 20 20 20 80 3 - - - 100
CHC603 Pollution Control
Technology 20 20 20 80 3 - - - 100
CHC604 Process Engineering and
Economics 20 20 20 80 3 25 - - 125
CHDO602X Departmental Optional
Course 2 20 20 20 80 3 - - - 100
CHL601 Mass Transfer Operation II
Lab - - - - 3 25 25 - 50
CHL602 Chemical Reaction
Engineering II Lab - - - - 3 25 25 - 50
CHL603 Pollution Control
TechnologyLab - - - - 3 25 25 - 50
CHL604 Skilled Based Lab: Piping
Design Engineering Lab - - - - - 25 - 25 50
CHM601 Mini Project – 2B - - - - - 25 - 25 50
Total 100 400 - 150 75 50 775
Department Optional Course 2 (Semester VI)
Engineering Stream (Elective Code) Technology Stream (Elective Code) Management Stream (Elective Code)
Piping Engineering (CHDO6021) Polymer Technology (CHDO6022) Industrial Organization and Management
(CHDO6023)
# indicates work load of Learner (Not Faculty), for Mini Project; For mini project faculty load: 1 hour per week per four groups
Page 9
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHC501 Mass Transfer Operation I 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of End
Sem
Exam
TW
PR/O
R
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
Prerequisites
1. Knowledge of chemistry, physics, physical chemistry, mathematics.
2. Knowledge process calculations (Material and energy balance).
3. Basics of unit operations.
4. Basic understanding of equilibrium.
5. Understanding of physical and chemical properties of compounds.
6. Students should have basic knowledge of properties su ch as heat capacity, enthalpy, sensible
heat and SI system of units.
Objectives
1. To understand the basic principles of mass transfer by diffusion in gases, liquids and solids .
2. To understand types of mass transfer coefficients and then the basic of interphase mass transfer.
3. To understand the operations of various equipment’s used fo r gas -liquid contact.
4. To understand the gas absorption, absorption with chemical reaction.
5. To study drying and draw drying curve and calculate time of drying. To study working
principles of different types of dryers.
6. To study humidification -dehumidification and calculations for number of stages, HTU,
NTU and HETP.
Detailed Syllabus
Module
No Course Contents No. of
Hours
1
Molecular Diffusion in Gases and Liquid:
Basics of Molecular Diffusion, Fick's First Law of Molecular Diffusion,
Various fluxes and relations between them, Molecular Diffusion in binary
gas mixtures - Steady state diffusion of one component in non -diffusing
second component, Equimolal counter diff usion of two components.
Molecular Diffusion in binary liquid solutions - Steady state diffusion of
one component in non -diffusing second component, Steady State
Equimolal counter diffusion of two components.
Diffusivity of gases. Theoretical and experiment al determination of
diffusivities, Diffusivities of liquids and their determination. Diffusion in 8
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Solids: Fick’s law of diffusion in solids, Types of Solid Diffusion,
Diffusion through Polymers, Diffusion through Crystalline Solids,
Diffusion in Porous Sol ids.
2 Mass Transfer Coefficients:
Definition of Mass Transfer Coefficient, F -Type and K -Type Mass
Transfer Coefficients and relations between them, Mass Transfer
Coefficients in Laminar and Turbulent Flow. Heat, Mass and Momentum
Transfer Analogies and dimensionless numbers, Interphase Mass Transfer -
Individual and Overall Mass Transfer Coefficients and relation between
them. Methods of contacting two insoluble phases - Continuous Contact,
Stage -wise Contact. 8
3 Equipments for Gas -Liquid Contacting:
Classification of equipments for gas -liquid contacting
• Gas dispersed and liquid continuous phase -Sparged Vessels
(Bubble Columns), Mechanically Agitated Vessels, Tray Towers.
• Liquid dispersed phase and gas continuous phase - Venturi
Scrubbers, Wetted Wall Towers, Spray Towers and Spray Chambers,
Packed Towers.
• Comparison of Packed Towers with Tray Towers. 3
4 Gas Absorption:
Solubility of gases in liquids, Effect of temperature and pressure on
solubility, Ideal and Non-ideal solutions, Choice of solvent for gas
absorption, Single component gas absorption - Multistage Cross Current,
Co-current, Counter current Operation.
Absorption with Chemical Reactions. 7
5 Drying:
Introduction to drying, Equilibrium, Different types of moisture contents,
Rate of Drying and drying curve, Batch Drying and calculation of time of
drying, Continuous drying. Equipments for drying. 7
6 Humidification and Dehumidification:
Introduction, Va pour Pressure Curve, Properties of Vapour -Gas mixtures
[Understanding various terms], Theory of wet bulb temperature, Adiabatic
Saturation Curves, Humidity Charts, Adiabatic operation: (Air water
systems) water coolers, cooling towers. 6
Note - Video, Digital, NPTL content should be used for understanding principles of working of
Mass Transfer Equipment .
Course Outcomes
1. The students will be able to understand the molecular diffusion, classification of various mass
transfer operations and their principles.
2. Students will be able to determine mass transfer coefficients.
3. Students will be able to determine interfacial co ncentrations, overall and individual mass
transfer coefficients.
4. Students will be able to select contact pattern/equipment for absorption, drying, humidification
and perform calculation for HTU, NTU, HETP.
5. Students will be able calculate number of st ages, minimum solvent requirement for gas
absorption.
6. Students will be able to determine time of drying and understand the concept efficiency of
cooling tower, adiabatic saturation and perform calculations for cooling tower.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme
Assessment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests
First test based on approximately 40% of contents and second test based on remaining contents
(approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be p roportional to number of
respective lectures.
2. Question paper will comprise of total six questions, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module 3
then part (b) will be from any module other than module3)
5. Only Four questions need to be solved .
Text Books
1.Treybal R.E., Mass transfer operation, 3 Ed., McGraw Hill New York, 1980.
2.Datta B.K., Mass Transfer and separation processes, Eastern economy edition, PHI learning
private ltd, New Delhi, 2009
Reference Books:
1.McCabe W.L. and Smith J.C., Unit operation in chemical engineering, 5 Ed., McGraw Hill, New
York 1993.
2.Geankoplis C.J., Transport processed and unit operations, Prentice Hall , New Delhi 1997.
3.Coulson J.M. Richardson J.F., Backhurst J.R. and Harker J.H., Coulson and Richardson
chemical engineering, vol 1 & 2, Butterworth Heinman, Ne w Delhi, 2000.
4.R.K. Sinnot (Ed) Coulson and Richardson chemical engineering, vol 6, Butterworth Heinman,
New Delhi, 2000.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHC50 2 Heat Transfer Operations 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hours -- -- -- 100
Units and Dimensions, Fluid Flow Principles, Laws of Thermodynamics, Chemical Reaction
Engineering, Process Safety.
Students should be able:
1. To understand scope of the heat transfer unit operations in chemical industry and basic
mode of heat transfer and conduction.
2. To demonstrate the knowledge of various analogies and empirical equation in
convective heat transfer system.
3. To develop heat transfer system with phase change i.e. condensation & boiling.
4. To understand various laws and rate of heat transfer by radiation.
5. To study preliminary design, construction, working of heat exchangers.
6. To understand construction and working of evaporators .
Module
no. Course Contents No. of
Hours
1 Introduction: Fundamentals of heat transfer, basic modes of heat
transfer. Concept of driving force and heat transfer coefficients, rate
expressions for three modes i. e. conduction, convection, radiation.
Steady State Conduction: Fourier's Law, thermal conductivity,
conduction through a flat slab, composite slab, conduction through a
cylinder wall, composite cylinder, Conduction through hollow sphere,
composite sphere. Critical radius of insulation.
Unsteady state conduction: -Lumped Parameter Analysis – systems with
negligible internal resistance. Biot number, Fourier number. 7 Prerequisites
Course Objectives
Detailed Syllabus
Page 13
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 2 Heat Transfer without Phase Change:
Individual and Overall Heat Transfer Coefficient: Types of flow,
energy balance, rate of heat transfer, individual and Overall Heat Transfer
Coefficients, LMTD, Wilson plot and fouling factors.
Natural Convection: Introduction, Natural convection currents. Heat
transfer correlations for free convection. Coefficient of thermal
expansion, Dimensional analysis for Natural convection.
Forced Convec tion: Introduction, thermal and hydrodynamic boundary
layer. Dimensional analysis, Heat transfer in laminar and turbulent flows
inside and outside tubes. Significance of various dimensionless numbers.
Empirical correlations. Reynolds’s Analogy, Prandtl’ An alogy,
Coulburn’s Analogy. 8
3 Heat Transfer with Phase Change:
Condensation: Introduction, types of condensation, Nusselt’s theory of
condensation, correlations for vertical and horizontal tube, plate.
Boiling: Heat transfer to boiling liquids, regimes of pool boiling of
saturated liquid, correlations for esti mating the boiling heat transfer
coefficients. Numericals on condensation. 4
4 Heat Transfer by Radiation: Introduction , Transmissivity, Absorptivity
& reflectivity, Grey body, Black body, opaque body etc. Laws of radiation.
Radiative heat exchange between surfaces, Multiple
reflection method, Radiation shield. 4
5 Heat Exchangers: Introduction, Classification, Preliminary process
design of Double pipe heat exchangers. Design of Shell & tube heat
exchangers by Kerns method. Effectiveness -NTU method. Heat transfer
in agitated vessels and correlations, Extended surface heat exchangers, Fin
efficiency and fin effectiveness, calculation of rate of heat transfer. 10
6 Evaporators:
Types of Tubular Evaporators, Performance Capacity and Economy,
Boiling Point Elevation, Mass and Enthalpy Balances For Single Effect
Evaporators. Multiple effect Evaporators, Methods of Feeding. Numerical
on single effect evaporator. 6
On completion of the course the students will be able to:
1. Evaluate rate of heat transfer for steady and unsteady state conduction systems.
2. Calculate LMTD and convective heat transfer coefficients.
3. Calculate heat duty in condensation and boiling process.
4. Analyze radiative heat transfer systems.
5. Identify, Design and select tubular type of heat exchangers.
6. Calculate heat load and efficiency in the evaporators.
Assesment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests . First test based on approximately 40% of contents and
second test based on remaining contents (approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks): Course Outcomes
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 1. Weightage of each module in end semester examination will be proportional to
number of respective lecture.
2. Question paper will comprise of total six questions, each carrying 20 marks.
3. Question 1 will be compulsory and should cover maximum contents of the
Curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from
Module 3 then part (b) will be from any module other than module3).
5. Only Four Questions need to be solved.
Recommended Books
1. MaCabe W. L., Smith J. C., Harriot P., Unit Operations of Chemical
Engineering, 5th edition, McGraw Hill,1993.
2. Cengel, Y. A. (2006). Fluid mechanics: fundamentals and applications. New
Delhi, India: Tata McGraw -Hill Publishing.
3. D. Q. Kern, Process Heat Transfer, McGraw hill, 1997.
4. R. K. Sinnot, Coulson & Richardsons Chemical Engineering Design,
Vol 1 & 6, Elsevier Science & Technology Books.
Reference Books
1. Holman J. P., Heat Transfer, 9th Edition, McGraw Hill, 2008.
2. B. K. Datta, Heat Transfer: Principles and applications, PHI learning.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHC503 Chemical Reaction Engineering -I 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
Prerequisites
1. Students should know basic chemistry pertaining to chemical reactions, chemical formula
etc.
2. Students are required to be aware of chemical process and unit operations used for the
manufacturing of chemical products.
3. Students should have knowledge of simple to complex numerical methods of solving one
and two dimensional Mathematical equations.
Objectives
1. To understand the different types of reactions
2. To formulate rate equation from reaction mechanism.
3. To analyse kinetic data for various type of reactions and develop Kinetic model for
homogeneous reactions
4. To design reactors for different kind of reactions.
5. To analyse different reactor combinations for various type of reactions.
6. To evaluate the effect of temperature on reactor performance for adiabatic and
non adiabatic operation.
Detailed Syllabus
Module
No Course Contents No. of
Hours
1 Introduction to Reaction Engineering :
Classification of reactions, Definitions of reactions rate, Variables
affecting reaction rate, Speed of chemical reactions.
Kinetics of homogenous reactions :
Formulation of rate equation. Molecularity and Order of reaction. Rate
constant k, Temperature dependant term of rate equations from
Arrhenius theory. 06
2 Elementary and Nonelementary Reactions: Representation of an
elementary and non elementary reaction. Kinetic Models for non 06
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme elementary reactions. Reaction mechanism and its influence on
kinetics, search for plausible mechanism via reaction kinetics.
3 Methods of analysis of experimental data :
For constant volume and Variable Volume Batch Reactor
a) Integral Method of analysis of experimental data.
b) Differential Method of analysis of experimental data.
c) Concept of Half Life/Fractional Life. Overall order of
irreversible reaction.
d) Analysis of total pressure data.
First order Reversible reaction. Irrev ersible reaction in parallel and in
series. Homogeneous catalyzed reactions, Auto catalytic reactions,
Shifting Order reactions. 08
4 Design of Reactors:
Ideal batch reactor and concept of batch time. Flow reactor and concept
of space time / space velocity and holding time/residence time. Ideal
Mixed Flow reactor(MFR) and Plug Flow Reactor (PFR).
Design for single reactions: Single reactor performance of reversible
and irreversible first order, pseudo first order, second order reactions
for MFR, PF R. Graphical and analytical techniques. 06
5 Combination of reactors:
PFR in series/ parallel, unequal size MFR in series, performance of the
above for the first order reactions. Introduction to Semi batch and
Recycle Reactor. Design for Irreversible rea ctions in series and parallel
with same or different order in various combinations. 06
6 Heat and pressure effects:
Calculations of heats of reaction and equilibrium constants from
thermodynamics, General graphical design procedure. Optimum
temperature progression, Energy balances equations in adiabatic and
non-adiabatic case. Exothermic reaction in mixed flow. 07
Course Outcome
On completion of the course the students will be able to:
1. Identify and analyze different types of homogeneous reactions.
2. Apply the knowledge they have gained to develop kinetic models for different types of
homogeneous reactions.
3. Derive Batch, CSTR, and PFR performance equations from general material balances .
4. Develop skills to choo se right type of reactor among single, multiple and recycle reactor.
5. Perform design calculation for isothermal plug, mixed, and batch reactors for different reactions.
6. Understand the effect of temperature on reactor performance for adiabatic and non-
adiaba tic operation of batch and flow reactors.
Assessment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests . First test based on approximately 40% of contents and
second test based on remaining contents (approximately 40% but excluding contents covered in
Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number of
Page 17
15
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme respective lecture
2. Question paper will comprise of total six questions, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from
module 3 then part (b) will be from any module other than module3)
5. Only Four questions need to be solved .
Recommended Books:
1. Levenspiel O., Chemical Reaction Engineering, John Wiley&Sons,3ed.,1999.
2. Smith J.M., Chemical Reaction Engineering, 3ed.,Tata McGrawHill,1980.
3. Fogler, H.S. Elements of Chemical Reaction Engineering, 4ed.,PHI, 2008
Reference Books:
1. Hill C.G., Chemical Reac tion Engineering.
2. Walas, Reaction Kinetics for Chemical Engineers, McGraw Hill, 1959.
Page 18
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHC504 Transport Phenomena 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
1. Basic transport properties, laws and equations.
2. Engineering Mathematics: Differential equations and Vector tensors.
3. Engineering Physics and Engineering Chemistry.
1. To apply differential equations , vector tensors in Chemical Engineering Transport Processes.
2. To explain the analogies between different transport processes.
3. To apply the equation of continuity, equation of motion and equation of energy in Chemical
Engineering processes.
4. To perfo rm momentum transfer analysis for solving various industry oriented problems
5. To analyze various industry oriented problems and solve based on energy transfer principles
6. To perform mass transfer analysis for solving various industry oriented problems
Detailed Syllabus
Module
No Course Contents No. of
Hours
1 1.1 Introduction to differential equations (1st and 2nd order)
1.2 vector tensors ( Gradient, Divergence and Curl),
1.3 Importance of Transport Phenomena (Macroscopic and
Microscopic approach) 04
2 2.1 Introduction to analogies between momentum, heat and mass
transfer, Defining Dimensionless numbers
2.2 Temperature and Pressure dependency of viscosity, thermal
conductivity and mass diffusivity in gases and liquids. 06
3 3.1 Eulerian and Lagrangian approach, Equation of continuity, Equation
of motion and Equation of energy 05 Prerequisites
Course Objectives
Page 19
17
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 4 4.1 Mechanism of momentum transport: Newton’s law of viscosity,
Newtonian & Non -New tonian fluids
4.2 Velocity distribution in laminar flow: Shell momentum balances and
boundary conditions a) Flow of falling film b) Flow through the circular
tube c) Flow through an annulus d) Flow in a narrow slit e) Adjacent flow
of two immiscible fluids . 07
5 5.1 Mechanism of energy transport: Fourier’s law of heat conduction
5.2 Temperature distribution in solids and in laminar flow, shell
energy balance and boundary conditions a) Heat conduction with
electrical heat source b) Heat conduction with a nuclear heat source c)
Heat conduction with a viscous heat source. e) Heat conduction with
variable thermal conductivity f) Heat conduction in composite wall and
cylinder g) Heat conduction in a cooling fin 10
6 6.1 Mechanism of mass transport: Definitions of concentrations,
velocities and mass fluxes, Fick’s law of diffusion
6.2 Concentration distribution in solids and in laminar flow, Shell
mass balances and boundary conditions a) Diffusion through stagnant gas
film b) Diffusion wit h heterogeneous chemical reaction c) Diffusion with
homogeneous chemical reaction d) Diffusion into a falling liquid film
(Gas absorption) 07
Course Outcomes
On completion of the course the students will:
1. Apply the differential equations , vector tensors in Chemical Engineering Transport
Processes.
2. Compute transport properties for liquids and gases using various empirical correlations.
3. Analyze different flow processes based on equation of continuity, equation of motion and
equation of ener gy.
4. Analyze and solve industry oriented problems based on momentum transfer analysis.
5. Apply energy transfer principles to determine temperature distribution for various
geometries.
6. Determine the concentration gradients in laminar flow and solids based on m ass transfer
analysis.
Assessment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests. First test based on approximately 40% of contents
and second test based on remaining contents (approximately 40% but excluding contents
covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be p roportional to number of
respective lectures.
2. Question paper will comprise of total six questions, each carrying 20 marks.
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module
3 then part (b) will be from any module other than module 3).
5. Only Four questions need to be solved.
Page 20
18
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Recommended Books
1. Bird, R.B., W.E. Stewart and E.N. Lightfoot, Transport Phenomena, Wiley, New York,
2nd ed., 2002
2. William J. Thomson, Introduction to Transport Phenomena, Prentice Hall,2000
3. Ismail Tosun, Modelling In Transport Phenomena A Conceptual Approach, Elsevier
Science B.V. 2002 1st Edition
Reference Books
1. Christie J. Geankoplis, Transport Processes and Separation Process Principles, 4th
Edition, 2004
2. Brodkey, R.S. and H.C. Hershey, Transport Phenomena: A Unified Approach,
McGraw -Hill, New York. 1988
3. Bodh Raj, In troduction to Transport Phenomena (Momentum, Heat and Mas), PHI
Learning Pvt. Ltd, Eastern Economy Edition.
4. Grewal B.S., Higher Engineering Mathematics, Khanna Publisher 44th Edition
Page 21
19
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHDO5011 Department Elective 1: Food Technology 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- - -- 100
Prerequisites
1. Knowledge of Chemical Engineering.
2. Food biotechnology
3. Food microbiology
Objectives
To impart knowledge to the students about
1. Various unit operations involved in Food processing.
2. The role of HEAT transfer in Food processing.
3. The laws to prevent adulteration.
4. Proper packaging & storage of materials.
5. The importance of microorganisms in food processing and
6. To encourage students for Entrepreneurship.
Detailed Syllabus
Module
no Course Contents No. of
Hours
1 Food Biochemistry and Food Microbiology: Food Constituents:
Carbohydrates, Proteins, Enzymes, Vitamins, Lipids and Minerals,
Flavors, Nutritional & sensory characteristics, Food fortification. Water
activity , role of microorganisms , D & Z values, TDT cu rve, Indian laws
regulating Foods and Food processing 5
2 Ambient Temperature Process: Raw material preparation, Size reduction
of solid, fibrous foods ; Emulsification and Homogenization in liquids ,
Mixing and Forming, Extraction and expression ,Membrane
concentration ,Fermentation : Theory , Types, Equipment’s and Effect
on foods. Numericals 7
3 Thermal Processing: Theory, Equipment, Effect on foods, blanchi ng,
extrusion, pasteurization, Heat Sterilization, Incontainer Ultra high
temperature(UHT)/aseptic processes, Numericals 7
Page 22
20
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 4 Freezing and Refrigeration: Types, Equipments , refrigerants, effects of
low temperature on quality, chilling, freezing , freeze drying and freeze
concentration. Numericals 6
5 Food Storage & Packaging: Modified Atmosphere Storage ( MAS ),
Hurdle Technology, Modified atmosphere packaging(MAP) Food
Adulteration & Quality Management: food safety., HACCP, GMP, GHP,
GLP. 6
6 Food Processing: Manufacturing and processing of food products: Fruit
juice processing, Alcoholic beverages, Milk and Milk Products; Milk
powder, cheese, Ice cream, Tea coffee, cocoa, Bread , Biscuits ,
confectionary(hard boiled sweets & chocolates) 8
Course Outcome
On completion of the course the students will be able to:
1. Know about essential nutrients in food and fortifying, if needed.
2. Give importance to hygiene in Food Units.
3. Apply HACCP in processing units.
4. Start own unit, with the guidance from CFTRI, Mumbai/ Mysore.
5. Do higher studies in India/ abroad.
6. Apply value addition/ modification in processing units.
Assessment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests . First test based on approximately 4 0% of contents and
second test based on remaining contents (approximately 40% but excluding contents covered in
Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number of
respective lecture
2. Question paper will comprise of total six questions, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module 3
then part (b) will be from any module other than module3)
5. Only Four questions need to be solved .
Recommended Books:
1. Fellows. P. Food Processing Technology: principles and practice. Woodhead publishing Ltd,
England
2. B. Sivasankar. Food processing and Preservation, Prentice Hall of India pvt ltd
Reference Books:
1.Toledo.R. Fundamentals of Food process Engineering, CBS publishers, New Delhi
2.D.G.Rao.Fundamentals of Food engineering, PHI Learning pvt ltd
3.Sukumar Dey. Outlines of Dairy Technology (free download available)
4. Minnife, Bernard. Cocoa, chocolates & confectionaries, Springer
Page 23
21
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHDO5012 Department Elective 1: Advanced Material Sciences 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
1. Mechanical, Electrical, Magnetic and Optical Properties of Materials .
2. Commonly used Materials of Construction and their Selection .
3. Corrosion in Materials.
1. To identify various advanced materials such as conducting polymers, high temperature
polymer s, stainless steels, composites and ceramics .
2. To evaluate the propert ies of the advanced materials used in chemical engineering .
3. To outline the engin eering applications of the advanced materials.
4. To describe the fabrication methods of the advanced materials used in chemical engineering.
5. To explain the properties and applications of nanomaterials.
6. To evaluate the different types of thin film coating methods and outline their applications.
Detailed Syllabus
Module
no Course Contents No. of
Hours
1 Advanced Metallic Materials :
Stainless Steels: Types, properties of stainless steels, failure of stainless
steels.
High Temperature Alloys: Properties and types.
Titanium Alloys and Cobalt -Chromium Alloys: Composition, properties and
applications.
Nitinol as Shape Memory Alloy and its applications. 06
2 Advanced Polymeric Materials :
Structure, preparation, and application of various conducting polymers, high
temperature polymers and liquid crystal polymers.
Biomedical applications of polymers such as hydrogels, polyethylene,
polyurethanes, polyamides and silicone rubber. 06
3 Ceramic Materials : 06 Prerequisites
Course Objectives
Page 24
22
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Properties of ceramic materials, classification of ceramic materials, ceramic
crystal structures. Preparation and application of ceramic materials:
Alumina, Partially Stabilized Zirc onia, Sialon, Silicon Nitride, Silicon
Carbide. Processing of Ceramics.
4 Composite Materials :
Necessity of composite materials, classification of composite materials,
types of matrix materials and reinforcements, reinforcement mechanism.
Fiber Reinforced Plastic Processing :
Open Moulding Processes : Filament Winding Process Closed Moulding
Processes : Pultrusion and Pulforming, Sheet Moulding Compound Process
Carbon -Carbon Composites : Fabrication and Properties 07
5 Metal Composites :
Advantage of metal composite over metal, types of reinforcement and matrix
fabrication types, properties, various fabrication processes: diffusion
bonding process, in -situ process.
Ceramic Composites :
Matrices and reinforcements, properties, fabrication methods: slurry
infiltration process, chemical vapour infiltration process. 07
6 Carbon Nanotubes: Synthesis, properties and applications.
Nanoshells : Types, properties and applications.
Nanosensors : Assembly methods, nanosensors based on optical, quantum
size, electrochemical and physical properties.
Thin Film Coatings : Physical and chemical vapour deposition coatings,
hardfacing, thermal spraying, diffusion process. 07
Course Outcomes
On completion of the course the students will be able to:
1. Identify various types of advanced materials such as metals and alloys, polymers, ceramics and
composites.
2. Evaluate and utilize the properties of various advanced polymeric, ceramic and metallic
materials and discuss their a pplications in various fields.
3. Select and analyze different types of composite materials, their properties and applications.
4. Explain the fabrication of various composite materials.
5. Outline the types of nanotubes and nanosensors and their applicat ions.
6. Evaluate the different thin film coating methods and discuss their applications in various fields.
Assessment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests . First test based on approximately 40% of contents and
second test based on remaining contents (approximately 40% but excluding contents covered in
Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number of
respective lectures.
2. Question paper will comprise of total six questions, each carrying 20 marks.
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be m ixed in nature (for example if Q.2 has part (a) from module
3 then part (b) will be from any module other than module 3).
Page 25
23
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 5. Only Four questions need to be solved .
Recommended Books:
1. B.K. Agrawal, Introduction to Engineering Materials, Tata McGraw Hill Education Pvt. Ltd.,
1988.
2. A.K. Bhargava, Engineering Material: Polymers, Ceramics and Composites, PHI Learning Pvt.
Ltd., 2nd Edition 2012.
3. Sujata V. Bhat, Biomaterials, Narosa Publication Pvt. Ltd., 2nd Edition, 2005.
4. Dr. H.K. Shivanand and B.V. Babu Kiran, Composite Material, Asian Books Private Limited,
2010.
5. T. Pradeep, Nano : The Essentials, Tata McGraw -Hill Education Pvt. Ltd., 2010.
Reference Books:
1. William Smith, Javed Hashemi, Ravi Prakash, Material Science and Engineering, 5th Edition,
Tata McGraw Hill Education Company Ltd., 2013.
2. Kenneth G. Budinski, Engineering Materials : Properties and Selection, 4th Edition, Prentice
Hall,1992.
3. James A. Jacob and Thomas F. Kilduff, Engineering Materials Technology : Structures,
Processing, Properties, and Selection, 5th Edition, Pearson/Prentice Hall, 2005.
4. D.A. Hansen and R.B. Puyear, Material Selection for Hydrocarbon and Chemical Plants, Marcel
Dekker, Inc., 1996.
5. C.P. Dillon, Materials Selection for the Chem ical Process Industries, Materials Technology
Institute, Incorporated, 2004.
6. W.D. Callister, Jr. and D.G. Rethwisch, Callister’s Materials Science and Engineering, 10th
Edition, John Wiley and Sons, 2020.
Page 26
24
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHDO5013 Department Elective I : Total Quality Management 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term Work/
Practical/Oral
Total Internal Assessment End Sem
Exam Duration of
End Sem
Exam TW PR OR
Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
1. Basic knowledge regarding Quality Improvement Processes and their applications in chemical
industries.
2. Commitment and steps required to provide an environment for changing attitudes must be
provided.
Learners should be able to:
1. Become acquainted with the significance and features of TQM philosophy.
2. Be familiarized with various quality tools and their uses in problem solving.
3. to appraise on the modern productivity improvement approaches and their interface with TQM.
4. Know various quality standards, quality auditing and certification methodology.
5. obtain an insight into the ongoing global trends in quality approach and practices with special
forms to the customer relationship.
6. Make the learners aware of the quality, system a nd standards in TQM.
Detailed Syllabus
Module
no Course Contents No. Of
Hours
1 Introduction to TQM :
● Definition of Quality, Concept, Principles, Features, Dimensions
and Quality in manufacturing and service segments of TQM
● Approach & barriers in implementation of TQM
● Cost of quality prevention, appraisal and failure costs, hidden
costs, trade -o between quality and cost 6
2 Planning for Quality and Quality improvement:
● Planning for quality: Need for quality policies and objective.
Significance of top management commitment, strategic planning for
quality 6 Prerequisites
Course Objectives
Page 27
25
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme ● Quality improvement : Management of controllable defects,
operator
controllable defects, sporadic and chronic problems of operator
controllable defects, sporadic and chroni c problems of quality, Pareto’s
principle and Bench marking (Definition and significance, data
collection for benchmarking and its use)
3 Customer relations:
● Customers, user and consumers, , types of customers, customer
perception and expectations and product awareness
● Quality feedback and redressal
● Basic principles of reliability (quality and reliability), Product
life cycle, trade -o between maintainability 6
4 Vendor relations :
● Vendor as a partner, vendor selection, vendor evaluation
● Push -Pull view of supply chain and cycle view of chain
management 5
5 SQC Tool :
● Histograms, Pie charts, Scatter diagrams, Cause and Effect
diagram etc.
● Statistical Process Control:
Process variability : Variables and process variation, measures of
accuracy and centering, precision or spread, normal distribution
Process Control : Control charts for variables (X -chart, R - chart,
Pie -chart) and attributes (np -charts, p -chart, c -charts, U -chart)
Process capability : OC curve, acceptance sampling, single and
double sampling producers and consumer's risk 8
6. Quality System:
● Quality standards :
∙ ISO 9001:2000 Quality management system.
∙ ISO 14001:2004 Environmental management system.
∙ ISO 27001:2005 Information security management system
● Quality assurance: Nature of assurance, reports on quality,
measuring performance, internal audit, surveillance audit, quality
certification methodolo gy and implications.
● Productivity improvement Tools/ Approaches/ Techniques:
Principles of Six -Sigma, approaches like JIT, Lean manufacturing zero
defect concept, KANBAN, QFD, FMEA, Basics of DOE and Shining
concepts of quality. Productivity improvement te chniques like 5S,
POKAYOKE, SMED, KAIZEN and Concurrent Engineering 8
Course Outcomes
After completing the course, the learners should be able to:
1. Appreciate the importance of quality and its dimensions in striving for excellence.
2. Understand the conscious compromise between cost and quality for problem solving.
3. Develop skill in the selection of various manufacturing processes and service functions.
4. Improve capability in the use of appropriate quality tools in various manufacturing and
service func tions.
5. Integrate quality approaches for productivity improvement.
6. Acquire knowledge base and develop skills for conducting quality audits.
Page 28
26
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Assessment
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests . First test based on approximately 40% of contents of
syllabus and second test based on remaining contents of syllabus (approximately 40% but
excluding contents covered in Test I)
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will b e proportional to number of
respective lectures.
2. Question paper will comprise of total six questions, each carrying 20 marks.
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example, if Q.2 has part (a) from module
3, then part (b) will be from any module other than module3)
5. Only Four questions need to be solved .
Reference Books:
1. Juran, J. M., Gryana, F. M., Quality planning and analysis, TMH.
2. Bester Fidd, D. H., et. al., Total quality management, Prentice Hall.
3. Erossbly, Pillip b., Quality is free, Mentor/New American Library.
4. Fergenbaum, Armand V., Total Quality Control, McGraw -Hill Inc.
5. Logothetis, N., Managing For Total Quality, Prentice Hall
Recommended Text Books:
1. Aurora, K. C., Total Quality Management, S. K. Kataria and Sons.
2. Ishikawa, K., What is total quality control? The Japanese way, Prentice Hall
Page 29
27
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHL501 Mass Transfer Operation I Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 25 -- 50
Prerequisities
1. Knowledge of chemistry, physics, physical chemistry, mathematics.
2. Knowledge process calculations (Material and energy balance).
3. Basics of unit operations.
4. Basic understanding of equilibrium.
5. Understanding of physical and chemical properties of compounds.
6. Students should know precautions to be taken in labor atories.
Objectives
1.To understand the basic principles of mass transfer by molecular diffusion in gases, liquids and
solids To study diffusion through solids
2. To understand and determine mass transfer coefficients for various systems.
3. To understand the working of various equipment used for contacting gas - liquid systems and
to calculate NTU, HTU, Number of stages etc.
4. To understand the unit operation of gas absorption and carry material and energy balance.
Also students will carry out the calculations for tray and packed column.
5. To study and draw drying curve and calculate time of drying.
6. To study humidification and calculations for number of stages, HTU, NTU and HETP.
List of Suggested Experiments (any 8 can be performed)
• To determine the diffusivity of given liquid sample.
• To study diffusion through porous solids and determine effective diffusivity.
• To estimate the mass transfer coefficient in flow process system (eg.benzoic acid +
water).
• To determine mass transfer co -efficient in gas liquid system by evaporation.
• To study absorption in packed tower.
• To determine the efficiency of cooling tower and study of Humidification and wat er-
cooling operations.
Page 30
28
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • To study the operation of a fluidized bed drier and analyze drying curve.
• To determine rate of absorption and study absorption in spray tower.
• To study batch drying and plot drying curve.
• To study hydrodynamics of packed bed and stud y variation in pressure drop with velocity.
• To determine Mass Transfer Coefficient in a packed extraction column.
• Experiments demonstrating determination of mass transfer coefficient/diffusivity/
number of transfer units, HTU, HETP are envisaged
• Note: Vir tual platforms can be used for better understanding of concepts (Virtual platform
should be used for at least one Experiment).
Course Outcomes
1. Students will be able to determine diffusivity of given samples.
2. Students will be able to understand diffusion through solids.
3. Students will be able to determine mass transfer coefficient for various systems.
4. Students will understand various contact patterns and equipment for mass transfer.
5. Students will be able to carry out mass and energy balance for gas absorption,
Humidification -dehumidification and calculate number of stages, NTU and HTU.
6. Students will be able to calculate time of drying, number of stages. Also, they will be
able to calculate efficiency and effectiveness of cooling tower.
Term work
Term work should evaluated based on performance in practical.
Practical journal: 20 marks
Attendance: 05 marks
Total: 25 marks
Practical Examination
• Duration for practical examination will be same as assigned to respective lab .
• A student will become eligible for practical examination after completing 8 experiments
Page 31
29
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHL502 Heat Transfer Operations Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 25 - 50
1. Knowledge of fluid, flow pattern and properties of fluids.
2. Knowledge of flow measurement and temperature measurement devices.
3. Knowledge of basic process calculations and process safety.
Students should be able to:
1. To give the in -hand experience of lab -scale experiments on conductive heat transfer
systems.
2. Define the fundamental concepts to students in the area of convective heat transfer
systems.
3. To determine the heat transfer rate and heat transfer coefficient in phase change systems
such as condensation and boiling.
4. Apply the knowledge of radiative heat transfer in an effective manner for different
applications.
5. To observe and note down the steady state temperatures and evaluate the heat transfer
coefficient, effectiveness of heat exchangers.
6. To determine the heat transfer rate, understand the working and application of agitated
vessel and evaporators in chemical industries.
On completion of the course the students will be able to:
1. Determine the thermal conductivity and heat transfer rate by using Fourier’s law.
2. Evaluate the heat transfer coefficient for natural and force convection.
3. Estimate the heat transfer coefficient in dropwise and filmwise condensation.
4. Determine the rate of heat transfer in radiation.
5. Analyze heat exchanger performance by using the method of log mean temperature
difference.
6. Measure the heat transfer coefficient in agitated vessel and efficiency in evaporator. Prerequisites
Lab Objectives
Lab Outcome
Page 32
30
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme
Experiment
No. Name of Experiment Lab
Hours
1 Heat Transfer through various Insulating materials 3
2 Composite Wall 3
2 Unsteady State Conduction 3
3 Natural Convection 3
4 Forced Convection 3
5 Film wise and Dropwise Condensation 3
6 Emissivity Measurement Apparatus 3
7 Double Pipe Heat Exchanger 3
8 Shell and Tube Heat Exchanger 3
9 Plate Heat Exchanger 3
10 Finned tube heat exchanger 3
11 Agitated vessel 3
12 Evaporator 3
13 Design of Shell and Tube Heat Exchanger by Kerns method (Virtual
Lab.) 3
Assessment:
Term Work (25 marks)
Distribution of marks will be as follows:
Laboratory work: 15 marks
Assignments: 05
Attendance: 05
End Semester Practical Examination/Orals (25 marks):
Practical Examination will be based on experiments performed in the laboratory.
Reference Books
1. Holman J. P., Heat Transfer, 9th Edition, McGraw Hill, 2008.
2. B. K. Datta, Heat Transfer: Principles and applications, PHI learning.
3. R. K. Sinnot, Coulson & Richardsons Chemical Engineering Design, Vol 1
& 6, Elsevier Science & Technology Books.
List of Experiments (Minimum Eight)
Page 33
31
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHL503 Chemical Reaction Engineering -I Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 25 - 50
Prerequisites
1. Basic knowledge of chemistry & kinetics.
2. Knowledge of data fitting
3. Concept of Molarity, Normality
4. Knowledge of lab safety rules.
Course Objectives
1. Understand the importance of reaction kinetics
2. Analyse effect of temperature on rate of homogeneous reaction
3. Selection of appropriate analysis technique depending on type of homogeneous reaction
4. Visualise operation of various reactor types
5. Evaluating performance of single and multiple reactors
6. Choose appropriate reactor set -up for various type of homogeneous reactions.
Course Outcome
On completion of the course the students will be able to:
1. Employ various methods to determine the kinetics of homogeneous reaction.
2. Acquire analytical skills for the analysis of varying concentration and temperature data
3. Analyze experimental data collected to determine the kinetics of reaction and interpret the
result.
4. Understand operation and design of Batch and flow reactors.
5. Compare performance of different reac tor types.
6. Select appropriate Reactor Set up for different homogeneous reactions,
List of Experiments (minimum eight)
Experiment
no. Details of Experiment Lab
Hours
1 Differential and Integral Analysis (Order of Reaction at Room
Temperature) 3
Page 34
32
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 2 Arrhenius Constants (Verification of Laws) 3
3 Order and Rate constant using Half Life Method 3
4 Study of Pseudo Order Reaction 3
5 Acidic Hydrolysis 3
6 Batch Reactor 3
7 Plug Flow Reactor (PFR) 3
8 Continuous Stirred Tank Reactor (CSTR) 3
9 Continuous Stirred Tank Reactors Series (Three CSTRs In Series) 3
10 PFR – CSTR In Series Combination 3
11 Experiments from Virtual Lab 3
Assessment:
Term Work (25 marks)
Distribution of marks will be as follows:
Laboratory work: 15 marks
Assignments: 05
Attendance: 05
End Semester Practical Examination/orals (25 marks)
Practical Examination will be based on experiments performed in the laboratory.
Reference Boo ks
1. Levenspiel O., Chemical Reaction Engineering, John Wiley & Sons, 3ed.,1999.
2. Smith J.M., Chemical Reaction Engineering, 3ed.,Tata McGrawHill,1980.
3. Fogler, H.S. Elements of Chemical Reaction Engineering, 4ed.,PHI, 2008
4. www.vlab.co.in
5. http://www.olabs.edu.in/
6. http://amrita.olabs.edu.in/
Page 35
33
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHL504 Skilled Based Lab: Professional Communication and Ethics
II Lab 2
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 2* + 2 Hours
(Batch wise) - - 2 - 2
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/
OR
Internal
OR Test-I Test-II Average
- - - - - 25 -- 25 50
*Theory class to be conducted for full class.
Course Rationale
This curriculum is designed to build up a professional and ethical approach, effective oral and
written communication with enhanced soft skills. Through practical sessions, it augments
student's interactive competence and confidence to respond appropriately and creatively to the
implied challenges of the global Industrial and Corporate requirements. It further inculcates
the social responsibility o f engineers as technical citizens.
Course Objectives
Learners should be able to:
1. discern and develop an effective style of writing important technical/business documents.
2. investigate possible resources and plan a successful job campaign.
3. understand the dy namics of professional communication in the form of group discussions,
meetings, etc. required for career enhancement.
4. develop creative and impactful presentation skills.
5. analyse personal traits, interests, values, aptitudes and skills.
6. understand the imp ortance of integrity and develop a personal code of ethics.
Course Outcomes
Learners will be able to:
1. plan and prepare effective business/ technical documents which will in turn provide
solid foundation for their future managerial roles.
2. strategize their personal and professional skills to build a professional image and
meet the demands of the industry.
3. emerge successful in group discussions, meetings and result -oriented agreeable
solutions in gr oup communication situations.
4. deliver persuasive and professional presentations.
5. develop creative thinking and interpersonal skills required for effective professional
communication.
6. apply codes of ethical conduct, personal integrity and norms of o rganizational behaviour.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme
Detailed Syllabus
Module Contents Hours
1 ADVANCED TECHNICAL WRITING :PROJECT/PROBLEM BASED
LEARNING (PBL)
1.1 Purpose and Classification of Reports:
Classification on the basis of:
• Subject Matter (Technology, Accounting, Finance, Marketing, etc.)
• Time Interval (Periodic, One -time, Special)
• Function (Informational, Analytical, etc.)
• Physical Factors (Memorandum, Letter, Short & Long)
1.2. Parts of a Long Formal Report:
● Prefatory Parts (Front Matter)
● Report Proper (Main Body)
● Appended Parts (Back Matter)
1.3. Language and Style of Reports
● Tense, Person & Voice of Reports
● Numbering Style of Chapters, Sections, Figures, Tables and Equations
● Referencing Styles in APA & MLA Format
● Proofreading through Plagiarism Checkers
1.4. Definition, Purpose & Types of Proposals
• Solicited (in conformance with RFP) & Unsolicited Proposals
• Types (Short and Long proposals)
1.5. Parts of a Proposal
● Elements
● Scope and Limitations
● Conclusion
1.6. Technical Paper Writing
• Parts of a Technical Paper (Abstract, Introduction, Research Methods,
Findings and Analysis, Discussion, Limitations, Future Scope and
References)
• Language and Formatting
• Referencing in IEEE Format 06
2 EMPLOYMENT SKILLS
2.1. Cover Letter & Resume
• Parts and Content of a Cover Letter
• Difference between Bio -data, Resume & CV
• Essential Parts of a Resume
• Types of Resume (Chronological, Functional & Combination)
2.2 Statement of Purpose
● Importance of SOP
● Tips for Writing an Effective SOP
2.3 Verbal Aptitude Test
• Modelled on CAT, GRE, GMAT exams
2.4. Group Discussions
• Purpose of a GD
• Parameters of Evaluating a GD 06
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • Types of GDs (Normal, Case -based & Role Plays)
• GD Etiquettes
2.5. Personal Interviews
• Planning and Preparation
• Types of Questions
• Types of Interviews (Structured, Stress, Behavioural, Problem Solving &
Case -based)
• Modes of Interviews: Face -to-face (One -to one and Panel) Telephonic,
Virtual
3 BUSINESS MEETINGS
1.1. Conducting Business Meetings
• Types of Meetings
• Roles and Responsibilities of Chairperson, Secretary and Members
• Meeting Etiquette
3.2. Documentation
• Notice
• Agenda
• Minutes 02
4 TECHNICAL/ BUSINESS PRESENTATIONS
1.1 Effective Presentation Strategies
• Defining Purpose
• Analyzing Audience, Location and Event
• Gathering, Selecting &Arranging Material
• Structuring a Presentation
• Making Effective Slides
• Types of Presentations Aids
• Closing a Presentation
• Platform skills
1.2 Group Presentations
• Sharing Responsibility in a Team
• Building the contents and visuals together
• Transition Phases 02
5 INTERPERSONAL SKILLS
1.1. Interpersonal Skills
• Emotional Intelligence
• Leadership & Motivation
• Conflict Management & Negotiation
• Time Management
• Assertiveness
• Decision Making
5.2 Start -up Skills
• Financial Literacy
• Risk Assessment
• Data Analysis (e.g. Consumer Behaviour, Market Trends, etc.) 08
6 CORPORATE ETHICS
6.1Intellectual Property Rights
• Copyrights
• Trademarks
• Patents 02
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • Industrial Designs
• Geographical Indications
• Integrated Circuits
• Trade Secrets (Undisclosed Information)
6.2 Case Studies
• Cases related to Business/ Corporate Ethics
List of assignments:
(In the form of Short Notes, Questionnaire/ MCQ Test, Role Play, Case Study, Quiz, etc.)
1. Cover Letter and Resume
2. Short Proposal
3. Meeting Documentation
4. Writing a Technical Paper/ Analyzing a Published Technical Paper
5. Writing a SOP
6. IPR
7. Interpersonal Skills
8. Aptitude test (Verbal Ability)
Note:
1. The Main Body of the project/book report should contain minimum 25 pages (excluding Front and
Back matter).
2. The group size for the final report presentation should not be less than 5 students or exceed 7
students.
3. There will be an end –semester presentation based on the book re port.
Assessment :
Term Work :
Term work shall consist of minimum 8 experiments.
The distribution of marks for term work shall be as follows:
Assignment : 10 Marks
Attendance : 5 Marks
Presentation slides : 5 Marks
Book Report (hard copy) : 5 Marks
The final certification and acceptance of term work ensures the satisfactory performance of laboratory
work and minimum passing in the term work.
Internal oral:
Oral Examination will be based on a GD & the Project/Book Report presentation.
Group Discussion : 10 marks
Project Presentation : 10 Marks
Group Dynamics : 5 Marks
Books Recommended:
Textbooks and Reference books:
1. Arms, V. M. (2005). Humanities for the engineering curriculum: With selected chapters from
Olsen/Huckin: Technical writing and professional communication, second edition . Boston,
MA: McGraw -Hill.
2. Bovée, C. L., &Thill, J. V. (2021). Business communication today . Upper Saddle River, NJ:
Pearson.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 3. Butterfield , J. (2017). Verbal communication: Soft skills for a digital workplace . Boston, MA:
Cengage Learning.
4. Masters, L. A., Wallace, H. R., & Harwood, L. (2011). Personal development for life and work .
Mason: South -Western Cengage Learning.
5. Robbins, S. P., Judge, T. A., & Campbell, T. T. (2017). Organizational behaviour . Harlow,
England: Pearson.
6. Meenakshi Raman, Sangeeta Sharma (2004) Technical Communication, Principles and
Practice. Oxford University Press
7. Archana Ram (2018) Place Mentor, Tests of Aptitude F or Placement Readiness. Oxford
University Press
8. Sanjay Kumar &PushpLata (2018). Communication Skills a workbook, New Delhi: Oxford
University Press.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester V
Course Code Course Name Credits
CHM501 Mini Project -2A 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 - 25 50
Objectives:
1. To acquaint with the process of identifying the needs and converting it into the problem.
2. To provide knowledge of unit operation and unit process.
3. To familiarize the process of solving the problem in a group.
4. To acquaint with the process of applying basic engineering fundamentals to attempt
solutions to the problems.
5. To inculcate the process of self -learning and research.
6. Design and development of Small project based on various process and software
Course Outcome:
At the end of this course, students will be able to:
1. Identify problems based on societal /research needs.
2. Reproduce, improve and refine technical aspects for engineering projects.
3. Draw the proper inferences from available results through theoretical/ experimental /
simulation
4. Identify, discuss and justify the technical aspects of the chosen project with a
comprehensive and systematic approach.
5. Students will be able to practice acquired knowledge within the chosen area of technolog y
for project development.
6. Work as an individual or in a team in development of technical projects, which leads to
lifelong learning.
Guidelines for Mini Project
➢ Students shall form a group of 3 to 4 students, while forming a group shall not be allowed
less than three or more than four students, as it is a group activity.
➢ Students should do survey and identify needs, which shall be converted into problem
statement for mini project in consultation with faculty supervisor/head of
department/internal committee of faculties.
➢ Students hall submit implementation plan in the form of Gantt/PERT/CPM chart, which
will cover weekly activity of mini project.
➢ A log book to be prepared by each group, wherein group can record weekly work progress,
guide/supervisor can veri fy and record notes/comments.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme ➢ Faculty supervisor may give inputs to students during mini project activity; however, focus
shall be on self -learning.
➢ Students in a group shall understand problem effectively, propose multiple solution and
select best possibl e solution in consultation with guide/ supervisor.
➢ Students shall convert the best solution into working model using various components of
their domain areas and demonstrate.
➢ The solution to be validated with proper justification and report to be compiled in standard
format of University of Mumbai.
➢ With the focus on the self -learning, innovation, addressing societal problems and
entrepreneurship quality development within the students through the Mini Projects, it is
preferable that a single project of appropriate level and quality to be carried out in two
semesters by all the groups of the students. i.e. Mini Project 2 in semester V and VI.
➢ However, based on the individual students or group capability, with the mentor’s
recommendations, if the proposed Mini Project adhering to the qualitative aspects
mentioned above gets completed in odd semester, then that group can be allowed to work
on the extension of the Mini Project with suitable improvements/modifications or a
completely new project idea in even s emester. This policy can be adopted on case by case
basis.
Guidelines for Assessment of Mini Project:
Term Work
• The review/ progress monitoring committee shall be constituted by head of departments of
each institute. The progress of mini project to be eval uated on continuous basis, minimum
two reviews in each semester.
• In continuous assessment focus shall also be on each individual student, assessment based
on individual’s contribution in group activity, their understanding and response to
questions.
• Distri bution of Term work marks for both semesters shall be as below;
➢ Marks awarded by guide/supervisor based on log book : 10
➢ Marks awarded by review committee : 10
➢ Quality of Project report : 05
Review/progress monitoring committee may consider following point s for assessment based
on either one year or half year project as mentioned in general guidelines.
One-year project:
• In first semester entire theoretical solution shall be ready, including components/system
selection and cost analysis. Two reviews will be conducted based on presentation given by
students group.
• First shall be for finalization of problem
• Second shall be on finalization of proposed solution of problem.
• In second semester expected work shall be procurement of components/systems, building
of wo rking prototype, testing and validation of results based on work completed in an
earlier semester.
• First review is based on readiness of building working prototype to be conducted.
• Second review shall be based on poster presentation cum demonstration of wo rking model
in last month of the said semester.
Half -year project:
• In this case in one semester students’ group shall complete project in all aspects including,
• Identification of need/problem
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • Proposed final solution
• Procurement of components/systems
• Building prototype and testing
• Two reviews will be conducted for continuous assessment,
• First shall be for finalization of problem and proposed solution
• Second shall be for implementation and testing of solution.
Assessment criteria of M ini Project.
Mini Project shall be assessed based on following criteria;
1. Quality of survey/ need identification
2. Clarity of Problem definition based on need.
3. Innovativeness in solutions
4. Feasibility of proposed problem solutions and selection of best solutio n
5. Cost effectiveness
6. Societal impact
7. Innovativeness
8. Cost effectiveness and Societal impact
9. Full functioning of working model as per stated requirements
10. Effective use of skill sets
11. Effective use of standard engineering norms
12. Contribution of an individual’s as member or leader
13. Clarity in written and oral communication
• In one year, project, first semester evaluation may be based on first six criteria’s and
remaining may be used for second semester evaluation of performance of students in mini
project.
• In case of half year project all criteria’s in generic may be considered for evaluation of
performance of students in mini project.
Guidelines for Assessment of Mini Project Practical/Oral Examination:
• Report should be prepared as per the guidelines issued by the University of Mumbai.
• Mini Project shall be assessed through a presentation and demonstration of working model
by the student project group to a panel of Internal and External Examiners preferably from
industry or research organizations having experie nce of more than five years approved by
head of Institution.
• Students shall be motivated to publish a paper based on the work in Conferences/students
competitions.
Mini Project shall be assessed based on following points;
1. Quality of problem and Clarity
2. Innovativeness in solutions
3. Cost effectiveness and Societal impact
4. Full functioning of working model as per stated requirements
5. Effective use of skill sets
6. Effective use of standard engineering norms
7. Contribution of an individual’s as member or leader
8. Clarity in written and oral communication.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme University of Mumbai
Program Structure for B.E. Chemical Engineering (Revised 2021 -2022)
T.E Semester VI
Course code
Course Name
Teaching Scheme
(Contact Hours) Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
CHC601 Mass Transfer Operation II 3 - - 3 - - 3
CHC602 Chemical Reaction
Engineering II 3 - - 3 - - 3
CHC603 Pollution Control
Technology 3 - - 3 - - 3
CHC604 Process Engineering and
Economics 3 - 1 3 - 1 4
CHDO602X Departmental Optional
Course 2 3 - - 3 - - 3
CHL601 Mass Transfer Operation II
Lab - 3 - - 1.5 - 1.5
CHL602 Chemical Reaction
Engineering II Lab - 3 - - 1.5 - 1.5
CHL603 Pollution Control
Technology Lab - 3 - - 1.5 - 1.5
CHL604 Skilled Based Lab: Piping
Design Engineering Lab - 3 - - 1.5 - 1.5
CHM601 Mini Project – 2B - 2# - - 1 - 1
Total 15 14 1 15 7 1 23
Course code Course Name
Examination Scheme
Theory
Term
Work Pract/
Oral Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs.) Test 1 Test
2 Avg
CHC601 Mass Transfer Operation II 20 20 20 80 3 - - - 100
CHC602 Chemical Reaction
Engineering II 20 20 20 80 3 - - - 100
CHC603 Pollution Control
Technology 20 20 20 80 3 - - - 100
CHC604 Process Engineering and
Economics 20 20 20 80 3 25 - - 125
CHDO602X Departmental Optional
Course 2 20 20 20 80 3 - - - 100
CHL601 Mass Transfer Operation II
Lab - - - - 3 25 25 - 50
CHL602 Chemical Reaction
Engineering II Lab - - - - 3 25 25 - 50
CHL603 Pollution Control
TechnologyLab - - - - 3 25 25 - 50
CHL604 Skilled Based Lab: Piping
Design Engineering Lab - - - - - 25 - 25 50
CHM601 Mini Project – 2B - - - - - 25 - 25 50
Total 100 400 - 150 75 50 775
Department Optional Course 2 (Semester VI)
Engineering Stream (Elective Code) Technology Stream (Elective Code) Management Stream (Elective Code)
Piping Engineering (CHDO6021) Polymer Technology (CHDO6022) Industrial Organization and Management
(CHDO6023)
# indicates work load of Learner (Not Faculty), for Mini Project; For mini project faculty load: 1 hour per week per four groups
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 1. Knowledge of chemistry, physics, physical chemistry and mathematics.
2. Knowledge of process calculations.
3. Knowledge of diffusion, mass transfer coefficients, modes of contact of two immiscible
phases.
4. Basic understanding of equilibrium.
5. Understanding of physical and chemical properties of compounds.
6. Students should know precautions to be taken in laboratories .
1. To understand Vapor liquid equilibrium and study different types of distillation and
equipment’s for distillation.
2. To study various contact patterns and equipment of extraction and leaching.
3. To study batch, semi batch and continuous adsorption.
4. To study crystallization principles and equipment.
5. To calculate no of stages, HTU, NTU, Height of bed, Efficiency for above operations
wherever applicable.
6. To study principles of various membrane separation methods.
Detailed Syllabus
Module Course Contents Hours
1
Distillation:
Introduction to Distillation, Concept of relative volatility, Minimum and
maximum boiling Azeotropes. Methods of distillation [binary mixtures]
- Flash Distillation, Differential distillation, Rectification. Calculations
of number of ideal stages in multis tage countercurrent rectification.
McCabe Thiele Method. Ponchon -Savarit Method, Lewis -Sorel
Method, Concepts of [Brief Discussion] -Steam Distillation, Azeotropic
Distillation, Extractive Distillation, Reactive Distillation, Molecular
Distillation, Membran e distillation, Introduction to Multicomponent
Distillation, 12
2 Liquid -Liquid Extraction:
Introduction to Liquid -Liquid Extraction, Choice of Solvent for Liquid -
Liquid Extraction, Triangular coordinate system, Ternary Equilibria 08 Semester VI
Course Code Course Name Credits
CHC601 Mass Transfer Operation II 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
Prerequisites
Objectives
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme [Binodal Solubility Curve with effect of temperature and pressure on it],
Single Stage Operation, Multistage Cross Cu rrent Operation, Multistage
Counter Current Operation [with and without reflux], Equipments for
liquid -liquid extraction.
3 Leaching:
Representation of Equilibria, Single stage leaching, Multistage Cross
Current Leaching, Multistage Counter Current Lea ching, Equipments
for Leaching. 06
4 Adsorption and Ion Exchange:
Introduction to Adsorption, Types of Adsorption, Adsorption
Isotherms, Single Stage Adsorption, Multistage Cross Current
Adsorption, Multistage Counter Current adsorption, Equipment’s for
Adsorption, Break through curve, Ion Exchange Equilibria, Ion
Excha nge Equipment’s. 08
5 Crystallization:
Solubility curve, Super saturation, Method of obtaining super saturation,
Effect of heat of size and growth of crystal, Rate of Crystal growth and
∆L law of crystal growth, Material and energy balance for crystallize rs,
Crystallization equipment -description. 03
6 Membrane separation Technique:
Need of membrane separation, and its advantages, classification of
membrane separation process, Principles of Ultrafiltration,
Nanofiltration. Reverse osmosis. 02
Note: Video, Digital, NPTL content can be used for equipment section of each chapter /unit
operation.
Course Outcomes
At the end of the course student will be able to:
1. Understand equilibrium in all separation processes.
2. Design the mass transfer equipments for various operations.
3. Understand principles of different distillation operations.
4. Choose the separation operation which will be economical for the given separation.
5. Design adsorption column and find optimum process par ameters.
6. Understand membrane separation processes, their principles and working.
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests
First test based on approximately 40% of contents and second test based on remaining contents
(approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number of
respective lectures.
2. Question paper will comprise of total six questions, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module 3
then part (b) will be from any module other than module3)
5. Only Four questions need to be solved.
Text Books
1. Treybal R.E., Mass transfer operation, 3 Ed., McGraw Hill New York, 1980.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 2. Datta B.K., Mass Transfer and separation processes, Eastern economy edition, PHI
learning private ltd, New Delhi, 2009
Reference Books:
1. McCabe W.L. and Smith J.C., Unit operat ion in chemical engineering, 5 Ed., McGraw Hill
New York 1993.
3. Geankoplis C.J., Transport processed and unit operations, Prentice Hall , New Delhi 1997.
4. Coulson J.M. Richardson J.F., Backhurst J.R. and Harker J.H., Coulson and Richardson
chemical eng ineering, vol 1 & 2, Butterworth Heinman, New Delhi, 2000.
5. R.K.Sinnot (Ed) Coulson and Richardson chemical engineering, vol 6, Butterworth Heinman,
New Delhi, 2000.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHC602 Chemical Reaction Engineering -II 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hours -- -- -- 100
1. Students should know basic chemistry pertaining to chemical reactions , chemical formula
and basic kinetics
2. Students are required to be aware of chemical process and unit operations used for the
manufacturing of chemical products.
3. Stu dents should have knowledge of s imple to complex numerical methods of solving one
and two dimensional Mathematical equations.
Objectives
1. To understand the concept of Residence Time Distribution (RTD) in case of non ideal flow
2. To predict the performance of real reactor based on RTD studies
3. To understand the difference between performance of homogeneous and heterogeneous
reaction.
4. To find the model equation and use this model to design the reactors used for heterogeneous
non catalytic reactions.
5. To develop kinetic model and Design strategy fo r heterogeneous catalytic reactions.
6. To apply the knowledge they have gained to develop kinetic model and use this model to design
the reactors used for Fluid -Fluid reactions.
Detailed Syllabus
Module Course Contents Hours
1 Non Ideal flow reactors:
Concept of residence time distribution (RTD), Measurement and
characteristics of RTD, RTD in Ideal batch reactors, Plug Flow Reactor
and CSTR. Zero Parameter Model –Segregation and Maximum mixedness
model. One parameter model –Tanks in series model and Dispersion
Model. Introduction to two parameter model 10
2 Hetrogeneous Reaction System: Introduction
Rate Steps involved in hetrogeneous reactions. Overall Rate Expression
for Linear and Nonlinear Process. Types of hetrogeneous reaction system
with industrial examples 04
3 Non Catalytic Heterogeneous Reactions: 08 Prerequisites
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Kinetics: General mechanism of reaction. Various models. Specific cases
with respect: (a) Film diffusion controlling. (b) Ash diffusion controlling.
(c) Chemical reaction controlling.
Design of reactors for non -catalytic reactions :
Experimental reactors for heterogeneous Reactions, Non -Catalytic Fluid
Solid Reactions in Flow Reactor. Application to design of continuous s olid
flow reactors; various design considerations, Application of fluid bed
reactors and their design consideration.
4 Catalytic Heterogeneous Reactions : Properties of solid catalysts,
Physical adsorption and Chemisorption, Surface area and pore size
distribution, Langmuir - Hinshelwood model, and General mechanism of
solid catalyzed fluid phase reactions. Derivations for LHHW model
mechanism -various case s, Concept of effectiveness factor of catalyst and
its dependence on catalyst properties and kinetic parameters. 07
5 Introduction to Catalytic Reactors : Packed Bed Reactor , Fluidized Bed,
Trickle Bed and Slurry Reactor. Experimental Methods for finding
reaction rates. Numericals based on Design of Packed Bed Reactor
(Calculation of weight/volume of catalyst). 04
6 Kinetics of fluid -fluid reactions : Reaction with mass transfer, the rate
equation pertaining to fast to very slow reactions.
Applications to design: Design of gas -liquid, heterogeneous reactors for
straight mass transfer case. 06
Course Outcome
On completion of the course the students will be able to:
1. understand the concept of Residence Time Distribution (RTD) in various reactors
2. Obtain the actual design parameters to design Real Reactor based on various models.
3. find out kinetic model equation and use this model to design the
reactors used for hetero geneous non catalytic reactions.
4. Classify catalysts and predict physical properties of catalyst, surface area, void volume, solid
density pore volume distribution.
5. develop kinetic model for catalytic reaction based on reaction mechanism
6. Analyse reactor des ign for catalytic reaction.
7. identify kinetic regime and design the reactors as per specification for Fluid -Fluid reactions
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests
First test based on approximately 40% of contents and second test based on remaining contents
(approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number of
respective lecture
2. Question paper will comprise of total six questions, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module 3
then p art (b) will be from any module other than module3)
5. Only Four questions need to be solved .
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Recommended Books:
1. Levenspiel O., Chemical Reaction Engineering, John Wiley&Sons, 3ed.,1999.
2. Smith J.M., Chemical Reaction Engineering, 3ed., Tata McGraw Hill,1980.
3. Fogler, H.S. Elements of Chemical Reaction Engineering, 4ed.,PHI, 2008
4. Hill C.G., Chemical Reaction Engineering
Reference Books:
1. Walas, Reaction Kinetics for Chemical Engineers, McGraw Hill, 1959.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHC603 Pollution Control Technology 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hours -- -- -- 100
Basic concepts of Fluid Flow Operations, Solid Fluid Mechanical Operations,
Mass Transfer Operations and Chemical Reaction Engineering.
Course Objectives
1. The aim of the course is to provide basic understanding of air and water pollution control,
regulations, and standards.
2. Course will provide basics of water pollution sources, properties, measurement and
control techniques.
3. Course will provide air pollutions sources, properties, measurements, control methods,
design of pollution control devices and efficiency analysis, as well as their applications.
4. Course will provide understanding of solid waste and noise pollution management.
5. Course will provide understanding of waste management in chemical industries.
6. Course will provide understanding of zero discharge management in chemical industries.
Detailed Syllabus
Module Course Contents Hours
1 Introduction to Pollution Control:
Importance of environmental pollution control, Environmental Legislation &
Regulations, Industrial pollution emissions & Indian standards for ambient air,
noise and water emission and effluents, Water (prevention & control of
pollution) act, Air (prevention & control of pollution) act.
Environmental audit: Definition and concepts, Introduction to ISO and ISO
14000. 4
2 Water Pollution and wastewater treatment technologies:
Classification of sources and effect of water pollutant on human being and
ecology, Sampling, measurement and standards of water quality,
Determination of organic matters: DO, BOD, COD, and TOC. Mathematical
model for BOD, Re -oxygenation and de -oxygenation in natural purification
process.
Determination of inorganic substances : nitrogen, phosphorus, trace
elements, alkalinity.
Physical characteristics : suspended solids, dissolved solids, colour and odour,
Bacteriological measurements. 10 Prerequisites
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Primary treatment : pre-treatment, settling tanks and their sizing.
Secondary treatment : micro -organisms growth kinetics, aerobic biological
treatment, activated sludge pr ocess, evaluation of biokinetic parameters,
trickling filters, rotating biological contractors, anaerobic treatment, sludge
treatment and disposal.
Tertiary treatment : Advanced methods for removal of nutrients,
suspended and dissolved solids, Advanced biol ogical systems,
Oxidation methods ( Chemical Oxidatio n – Chlorine/Hypochlorite/Chlorine
Dioxide, Hydrogen Peroxide, Hydroxyl Radical, Oxygen (Atomic and
Molecular) and Ozone, Catalytic Oxidation - Fenton’s Reagent (H2O2 +
Ferrous Ion), Photo Catalysis (UV + TiO2), Supercritical Water Oxidation) ,
Recovery of materials from process effluents.
3 Air pollution management:
Air pollutants sources, classification and characterization of air pollutants,
effect on health, vegetation & materials, types of inversion, behaviour and fate
of air pollutants,
Meteorological aspects of air pollutants: Temperature lapse rate & stabil ity,
wind velocity & turbulence, plume behavior, measurement of meteorological
variables, wind rose diagrams, Plume Rise, estimation of effective stack height
and mixing depths. Development of air quality models -Gaussian dispersion
model
Sampling: Sampling of particulate and gaseous pollutants (Stack, Ambient &
indoor air pollution), Monitoring and analysis of air pollutants (like PM2.5,
PM10, SOX, NOX, CO, NH3)
Air pollution control: Source correction methods for air pollution control,
Cleaning of gaseous effluents, Particulate emission control, Equipment, system
and processes for particulate pollutants and gaseous pollutants. 12
4 Solid Waste Management and noise pollution:
Waste sources and generation rates, Traditional methods of waste collection
and disposal, Factors influencing waste generation and health hazards,
Waste processing: Size and volume reduction, recycling of solid wastes,
hazardous waste characterization, tr eatment and disposal, e -waste management
rules, plastic waste, biomedical waste, solid waste management in rural areas
and recent advances in solid waste management.
Noise pollution: generation, control and management. 8
5 Industrial waste management: Case studies of i) petroleum refineries and
petrochemical units, ii) fertilizer industry 2
6. Zero discharge technology adapted in selected industries: Case studies of i)
Sugar industry ii) Pulp and paper 3
Course Outcomes
After successfully completing the course, the students will be able to:
1 Identify sources, types of pollutants and determine their impact on the environment, related
laws and standards.
2 To understand sampling, measurement of various water pollutants, natural purification
process, design various waste water treatments methods.
3 Analyze sampling, measurements, meteorological aspects air pollutant dispersion, its
control and equipment’s used for air pollution control.
4 To manage so lid waste and noise pollution control.
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50
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 5 Analyze and select appropriate treatment process for specific effluents emerging from
chemical industries.
6 To minimize use of resources in chemical industries.
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests
First test based on approximately 40% of contents of syllabus and second test based on remaining
contents of syllabus (approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number of
respective lecture
2. Question paper will comprise of total six question s, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module 3
then part (b) will be from any module other than module3)
5. Only Four questions need to be solved .
Recommended Text Books:
1. Rao, C.S., Environmental Pollution Control Engineering, New Age International (P) Ltd.
2. Peavy, H. S., Rowe, D.R., Tchobanoglous, G., Environmental Engineering, McGraw -Hill
Book Company Limited
3. Metcalf et al., Waste Water Treatment, Disposal & Reuse, Tata McGraw Hill Publishing
Company Limited.
4. Mahajan, S.P., Pollution Control in Process Industries, Tata McGraw Hill Publishing
Company Limited.
5. Davis, M. L. And Cornwell, D. A. , Introduction to Environmental Engineering, aGraw -
Hill Series in Water Resources and Environmental Engineering
Reference Books:
1. Hilary Theisen and Samuel A, Vigil, George Tchobanoglous, “Integrated Solid Waste
Management”, McGraw - Hill, New York, 1993
2. Frank Woodard, Industrial waste treatment Handbook, Butterworth Heinemann, New
Delhi, 2001.
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51
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHC604 Process Engineering and Economics 04
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - 01 03 - 01 04
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs. 25 -- -- 125
1. Knowledge of Physics, Chemistry and Mathematics.
2. Knowledge of different types of chemical processes.
3. Knowledge of fluid flow operations.
4. Knowledge of mass transfer operations.
5. Knowledge of equipments used for gas -liquid contact.
6. Preliminary knowledge of economics.
1. Students should know the fundamental concepts in process engineering.
2. Students should know different methods of interest and depreciation calculations.
3. Students should know various flow diagrams and methodology for process design of piping
and fluid moving devices.
4. Students should know the methodology for process design of distillation and absorption
columns.
5. Students should know various short cut methods of sizing and cost estimation of process
equipments and understand different types of costs and cost estimates.
6. Students should understand cash flow in an industrial operation and know break -even and
profitability analysis.
Detailed Syllabus
Module Course Contents Hours
1 Process Engineering for Chemical Engineers:
Basic functions of Process Engineering; Role and responsibilities of Process
Engineer; Chemical Products; Formulation of the Design Problem; The Hierarchy
of Chemical Process; Continuous and Batch Processes; New Design and Retrofit;
Approaches to Chemical Process Design and Integration; Process Control;
Importance of safety and environmental aspects. 05
2 Economics for Chemical Engineers:
Different types of Interest: Simple int erest, compound interest, nominal &
effective interest rates; Present worth & Discount; Annuities; Perpetuity & 06 Prerequisites
Objectives
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52
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Capitalized cost; Depreciation: Concept causes and types, methods of depreciation
accounting without interest consideration and with interest co nsideration
3 Process design of piping and fluid moving devices:
Block diagrams; Process flow diagram; Piping and Instrumentation Diagram;
Process design of piping; Process design of fluid moving devices: Process design
of pumps, revision of formulae for power requirement for fans, blowers and
adiabatic compressor; Process Design for orifice meter. 09
4 Process design of separation systems:
Process design of Distillation Column
Packed tower DC vs Tray tower DC; Design steps in DC design (12 steps);
Underwood’s method for 𝑅𝑀𝑖𝑛 calculation; FUG method for design of
multicomponent distillation; Selection of tray: Types and factors to be considered
during tray selection; Short pa th distillation unit (SPDU): Concept, working and
applications.
Process Design of Absorber
Equipment used for absorption and selection criteria; Shortcut method for design
of Absorption column (based on Kremser’s Equation) 09
5 Equipment sizing and cost e stimation:
Equipment sizing
Shortcut methods for sizing of major process equipment: Process vessels,
distillation columns, pumps, compressors, heat exchangers,
Cost Estimation
Shortcut methods of costing (Bare module cost) of above equipment (based on
Guthrie’s method); Six Tenth rule and its application for cost estimation of
equipment; Types of costs and capital cost estimates; Concept of total product cost. 05
6 Profitability analysis:
Cash flow in an industrial operation (Concept of tree diagram.); Break even
analysis; Different methods of profitability analysis: Rate of return -on-investment
method, discounted cash flow method, net present worth method, capitali zed cost
method, pay -out period method; Comparison of alternative investments based on
incremental rate of return; replacement analysis. 05
Course Outcome
On completion of the course the students will be able to:
1. Understand the functions of process engineering and various approaches of chemical
process design.
2. To calculate different types of interests and annual depreciation costs using different
methods.
3. To draw various flow diagrams and carry out process design of piping and various flow
moving devices.
4. To carry out process design of multicomponent distillation and absorption columns using
various approaches.
5. Evaluate basic design aspects of major process equipments, carry out their quick cost
estimation a nd demonstrate their knowledge of different types of costs and capital cost
estimates.
6. Demonstrate their knowledge of cash flow in an industrial operation and perform break -
even and profitability analysis using different methods.
Tutorials
• Minimum 8 tut orials should be conducted.
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53
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • At least one tutorial on each module is expected and tutorial on modules 2 to 6 must include
numerical problems.
• One tutorial will be based on solving detailed process design along with cost estimation by
using appropriate soft ware/platform.
• One tutorial will be based on contents beyond syllabus.
Term work
• Term work should consist of minimum 8 tutorials from entire syllabus which are to be
given at regular intervals batch wise.
• Tutorial: 20 marks Attendance: 05 marks Total: 2 5 marks
Assessment
• Internal Assessment consists of two tests which should be conducted at proper intervals.
• End Semester theory examination Question paper will comprise of 6 questions each
carrying 20 questions.
• Total 4 questions need to be solved
• Question no.1 will be compulsory based on entire syllabus wherein sub questions can be
asked.
• Remaining questions will be randomly selected from all the modules
• Weightage of marks should be proportional to number of hours assigned to each module
Text Books
1. Process Engineering and Design: Shuchen B. Thakore, Bharat I Bhatt, Second Ed.,
McGraw Hill Education(I) Pri vate Limited,2011
2. Robin Smith, Chemical Process Design and Integration, John Wiley and Sons
3. Systematic Methods Of Chemical Process Design, Loren T Biegler, Grossman E.I., West -
berg, A.W. Prentice Hall Intl ed., 1997.
4. Richard M. Felder, Ronald W. Rousseau, Elementary Principles of Chemical Processes,
John Wiley &Sons
5. Atul Sathe, Shubhada Kanchan, "Chemical Engineering Economics", Vipul Prakashan,
Mumbai.
6. Indrajit N. Yadav, "Chemical Engineering Economics" Sai - publication, Pune 211d
edition, 2017
Referenc e Books
1. Chemical Engineering Design, R. K. Sinnott, Coulson and Richardson Chemical
Engineering Series, Volume 6, fourth edition, Elsevier Butterworth -Heinemann, 2005.
2. Conceptual Design of Chemical Processes, J.M. Douglas, McGraw Hill International
Edition s, 1988.
3. Chemical Process Equipment: selection & design, Walas, S.M., Butterworth,
London,1980.
4. Strategy of Process Engineering, John D.F. Rudd& C.C. Watson, Wiley & Sons
International, 1968.
5. Process Design Principles: synthesis analysis & evaluation, Sieder, W.D., Seader J.D. &
Lewin D.R., John Wiley & Sons, 1998.
6. Analysis, Synthesis, and Design of Chemical Processes, Richard Turton, Richard C. Bailie,
Wallace B. Whiting, Joseph A. Shaeiwitz, PHI Learning Private Limited, New Delhi, 2011.
7. Peters, M. S. and Timmerhaus, K. D. , "Plant design and economics for chemical
engineers", latest edition, Mcgraw Hill, New York.
8. Pravin Kumar "Fundamentals of Engineering Economics" Wiley India.
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54
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 9. Kharbanda, 0. P. and Stallworthy, E. A. "Capital cost estimating for process industries",
Butterworths, Londen
10. K. K Dewett and Adarsh chand, " Modern Economic Theory", latest edition. S Chand and
Company.
Page 57
55
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHDO6021 Piping Engineering 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
1. Basics of Chemical Engineering Process
2. Fluid flow fundamentals
1. To introduce students to the crucial role of piping engineer in turn key projects
2. Student will able to select suitable material of construction of pipe
3. Students will understand selection of right piping elements
4. Students will be able to design piping syst em for a chemical process industry
5. To make students understand the approval drawings and execute the work adhering to
procedures and standards
6. To understand the layout and manage the work with adequate safety and reliability
Detailed Syllabus
Module Course Content Hours
1. Introduction to Piping
• Introduction to piping
• Pipe and tube
• Pipe classification
• Manufacturing processes of pipe
• General definitions
• Length, area, surface & volume acronyms and abbreviation.
• Concept of high point vent and low point drain.
• Duties & responsibilities of piping field engineer 6
2. Materials of Piping
• Selection of material for piping,
• Desirable properties of piping materials
• Iron Carbide Diagram
• Materials for various temperature and pressure conditions,
• Materials for corrosion resistance.
• Pipe coating and insulation 4 Prerequisites
Objectives
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56
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • Color coding of piping as per types fluid passing through piping
(IS 2379:1990)
3. Codes and Standard
• Codes and standards such as, ANSI codes for pressure piping
31.1 and 31.3. International standards, DIN and API. 2
4. Piping Components
• Pipe sizes and schedule number
• Pipe fittings
• Pipes joints & bending (Cold & Hot Bending)
• Welding defect (NDT)
• Valves: Types of valves and selection
• Strainers & traps, sight glass,
• Flame arresters,
• Inline mixers and static mixtures.
• Jacketed piping
• Expansion joints
• Threaded joints
• Types of piping support and Pipe rack 8
5. Piping System Design
• Flows through Pipes.
• Loss of energy / head in pipes, Loss of head due to friction.
• Minor energy losses,
• Water hammer in pipes
• Design Principles and Line Sizing
• Miter Joint Calculation.
• Stress intensification factor
• Flexibility an alysis
• Various stresses in piping and stress analysis
• Pipeline designation 12
6. Piping Drawing
• Piping drawing symbols and abbreviations
• Classification/Types of drawing
• Introduction to simple piping drawings
• Plot Plan
• G.A.Drawing
• Process flow diagram (P.F.D)
• Piping and instrumentation diagram (P&ID) / Engineering flow
diagram. 7
Course Outcome
On completion of the course the students will be able to:
1. Recognize role of piping engineer
2. Understand Pipe Material selection
3. Choose the piping fundamentals, codes and standards
4. Select piping system components
5. Examine piping system
6. Choose and Design different piping drawing
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests
Page 59
57
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme First test based on approximately 40% of contents and second test based on remaining contents
(approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be proportional to number
of respective lecture
2. Question paper will comprise of total six questions, each carrying 20 marks
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from
module 3 then part (b) will be from any module other than module3)
5. Only Four questions need to be solved .
Recommended Books:
1. Deutsch D. J. Process piping systems, Chemical engineering magazine. Mc -Graw hill.
2. Ed Bausbacher and Roger Hunt, ‘Process Plant Layout and Piping Design’, First Edition,
Prentice Hall, 1993
3. Robert A. Rhea, Roy A Parisher, “Pipe Drafting and Design”, Second Edition, Gulf
Professional Publishing , 2003
Reference Books:
1. Handbook of piping design - S.K. Sahu Elsevier Publishers
2. Piping/mechanical hand book - Mohinder L. Nayyar. Peter H. O. Fischer, Manager,
Pipeline Operations, Bechtel
3. Piping Design Handbook by John J. Mcketta, by Marcel Dekker, Inc, New York.
Page 60
58
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHDO6022 Department Elective VI: Polymer Technology 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - - 03 - - 03
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR
OR Test-I Test-II Average
20 20 20 80 03 Hrs -- -- -- 100
1. Chemistry, Physics, Chemical reaction Engineering .
1. Understand thermodynamics of polymer structure
2. Understand different kind of Polymerization Process with their properties & applications.
3. Understand techniques of Polymerization, uses and applications.
4. Understand different molding methods of Polymer processing.
5. Understand different kind of polymers and their properties & applications
6. Understand polymer Rheology and Morphology
Detailed Syllabus
Module Course Contents Hours
1 Introduction:
Introduction, basic concepts and definition, Classification of Polymers,
Factors influencing the polymer properties, Polymer Structure (Linear,
Branch and Cross Linked),
Glass Transition Temperature, Significance and different methods of
measurement of Glass transition temperature, Molecular Weights,
Polydispersity Index, Different Methods of determination of Molecular
weight, Effect of Molecular weight on Engineering Prop erties of
Polymers 04
2 Free Radical addition (Chain - growth ) Polymerisation
Introduction, Mechanism, Kinetics of homogeneous polymerization
Step -growth (Condensation) Polymerisation
Features; Definition, mechanism and kinetics, Derivation of Carother’s
equation. 06
3 Polymerisation Techniques :
Bulk polymerization, Solution polymerisation, Emulsion polymerisation,
Suspension polymerisation and Interfacial Polymerisation with their 09 Prerequisites
Objectives
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59
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme merits Comparison of the various processes advantages and
disadvantages.
Co-Polymerisation:
Introduction, Copolymer equation, Monomer reactivity ratios,
Significance and method of determination, Types of copolymerisation
(Ideal, alternating a nd block copolymerisation)
4 Polymer Processing:
Different moulding methods of polymers. Injection moulding, blow
moulding, thermo forming (Vacuum, Pressure and mechanical
thermoforming), film blowing, Filament winding, Pultrusion 04
5 Manufacturing Processes:
Manufacturing of typical polymers with flow -sheet diagrams properties
& application: PE, PP Nylons, ABS Manufacturing of thermoset
polymers such as Phenolic resins
Polymer Degradation:
Introduction, random and chain end degradation, Types of degradation
(Thermal, Mechanical, Degradation by ultrasonic waves, degradation by
high energy radiation) 10
6 Polymer Rheology and Morphology
Concept of rheology; Newtonian and Non –Newtonian fluids - flow
curves; apparent viscosity, Power law, Viscoelasticity, free volume or
molecular hole concept,
Concept of morphology, Requirements for crystallinity, Effects on
mechanical and optical properties 06
Course Outcomes
On completion of the course the students will be able to:
1. Students will understand the basic concepts, Polymer structure and applications of various
techniques used for molecular weights of polymers.
2. Students will demonstrate an ability to distinguish different Polymerisation reactions and their
mechanisms and kinetics.
3. Students will have deep understanding of the various analytical Polymerisation techniques used for
identification and characterization of polymeric materials.
4. Student will have the knowledge of moulding processes along with their parameter and process
control.
5. Students will have the knowledge of manufacturing process, properties and applications of variety
of polymer.
6. Student should be able to understand various Rheological and Morphological parameters of
polymers.
Internal Assessment (20 Marks):
Consisting Two Compulsory Class Tests
First test based on approximately 40% of contents and second test based on remaining contents
(approximately 40% but excluding contents covered in Test I).
End Semester Examination (80 marks):
1. Weightage of each module in end semester examination will be p roportional to number of
respective lectures.
2. Question paper will comprise of total six questions, each carrying 20 marks.
3. Question 1 will be compulsory and should cover maximum contents of the curriculum.
4. Remaining questions will be mixed in nature (for example if Q.2 has part (a) from module
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60
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 3 then part (b) will be from any module other than module 3).
5. Only Four questions need to be solved .
Recommended Books:
1. Gowarikar V.R. et.al., Polymer Science Wiley Eastern 1984.
2. Premamoy Ghosh, Polymer Science and Technology, 3rd Edition, Tata Mc. Graw -Hill
Publishing Company, New Delhi, 2010.
Reference Books:
1. Fried J R, Polymer Science and Technology, Prentice Hall of Indi a Pvt. Ltd., New Delhi,
Eastern Economy Edition, 2000.
2. R. Sinha, Outlines of Polymer Technology: Manufacture of Polymers, Prentice Hall of India
Pvt. Ltd., New Delhi, 2002.
3. Bhatnagar, M.S., a Textbook of Polymers, Vol .1, S.Chand & Co.Ltd., New D elhi 2004.
4. Bhatnagar, M.S., a Textbook of Polymers, Vol .II, S.Chand & Co.Ltd., New Delhi 2004
Page 63
61
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHDO6023 INDUSTRIAL ORGANIZATION AND MANAGEMENT 03
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
03 - 00 03 - - 03
Theory Term -
Work/Practical/Oral
Total Internal Assessment End
Sem.
Exam Duration of
End Sem.
Exam
TW
PR
OR Test
-I Test-
II Averag
e
20 20 20 80 03 Hrs. -- -- -- 100
• Communication skills
• Basic Mathematical skills
• Analytical, logical and reasoning skills
• Understand basic concepts of business, administration and management.
• Recognize functions of management such as planning, organizing and decision making.
• Interpret corporate/company governance structures and laws governing industries.
• Know production and quality management.
• Explain basics of marketing and sales management.
• Illustrate financial management of companies.
Module
no Course Contents No. Of
Hours
1 INTRODUCTION TO BUSINESS AND MANAGEMENT AND
FUNCTIONS OF MANAGEMENT
Business and Management
• Definition, Objectives, Characteristics, Divisions and Principles of
Business/Management, Types of Business
• Difference between Policies -Goals -Objectives and Role of a Manager
• Difference of relationship between business, administration and
management
• Types of Management, Typical Management Structure, Management
Structure Chart for Medium Scale Industry
Development of Management Thought (Taylor, Fayol, Follet, Gilbreth,
Gantt)
Functions of Management
• Planning: Types of Plans, Steps in P lanning,
Management by Objectives (MBO)
• Organization: Definition ,Importance, Process, Characteristics, 05 Prerequisites
Course Objectives
Detailed Syllabus
Page 64
62
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Principles and Structure of Organization
• Types of Organizations: Military, Functional, Line and Staff,
Committee,Matrix; Departmentalization, Span of Management
• Decision Making: Theories, Types, Techniques
and Process of Decision Making
Quantitative methods in Decision Making and Markov Analysis
(Numericals based on Decision Making)
2 PERSONNEL MANAGEMENT
Functions and Elements
• Personnel Policies and Procedures
• Role of a Personnel Manager
• Functions of Personnel Management (Manpower Planning,
Recruitment, Selection, Training and Development)
• Elements of Personnel Management (Organization, Job, People)
Difference between Personnel Management and Human Resource
Management, Socio -psychological aspects of personnel management 08
3 CORPORATE MANAGEMENT STRUCTURES AND LAWS
GOVERNING INDUSTRIES
Industrial Ownership
● Types of Company Ownership:
Single Ownership, Partnership, Joint Stock Company, Co -operative,
Government Companies
• Organs of Company Management and their Functions:
Shareholders, Board of Directors, CEO, Managing Director, Manager,
Secretary, State Regulation of Management, Company Law Board
Corporate, Social and Environment Responsibility
• CSR through Triple Bottom Line and Sustainable Business
• Relation between CSR and Corporate Governance
• Chronological Evolution of CSR in India; Models of CSR in India,
Carroll's Model; Drivers Of CSR; M ajor Codes in CSR; Initiatives in
India
• Environmental Policy and Law
• Environmental Audit (ISO -19011, Qualities of Environmental
Auditor, Contents Of EA Reports)
Case Studies (Eg. , Nestle’s bottled water enterprise, Adani’s coal mines
in Australia, China’s development of cattle ranches in Brazillian Amazon 06
4 PRODUCTION AND QUALITY MANAGEMENT
Production System
● Input -Output Model
● Application of Microeconomics in Industries
● Productivity and Measures to Increase Productivity
Production, Planning and Production Control
● Routing, Scheduling, Dispatching, Follow -up and Expediting
● Types of Production Systems
● Supervision and Functions of Supervisor
Quality Management
● Definition of Quality, Dimensions of Quality
● Quality Control: Meaning, Objectives and Benefits
● Demings 14 Points for Management
● Juran’s Quality Trilogy
● TQM, ISO 9000,ISO 14000 06
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63
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme ● Inspection, Cost of Quality, Quality Control Tools for Improvement,
Quality Circles, Statistical Quality Control
5 MARKETING AND SALES MANAGEMENT
Sales Management
Sales Organization, Functions of Sales Department, Duties of Sales
Manager, ‘The Selling’ and Functions of Sales Department,The Selling
and Marketing Concepts
Marketing
● Definition,Principles and Functions of Marketing
● Marketing Research, Pricing Policies, Sales Forecasting, Marketing
Mix, Advertising, Sales Promotion
● Channels of Distribution, Pricing, Product mix and International
Marketing 06
6. International Trade
Concepts of International Trade, Government Aids for Export Promotion
(Export Houses, Export Promotion Counsel, Patent and Patent Rights)
Management Laws
Concepts of Contract Act, Offer and acceptance, Types of Contacts, Void
Contract, Concept of Guarantee and Warranty
Finance and Accounts
• Definition and Difference between Finance and Accounts
• Functions, Objectives, Role and Scope of Financial Management
• Sources of Finance, Cash Management and Capitalization
• Definitions of Assets, Liabilities, Book Keeping, Capital and Types
of Capital, Discounts, Commission, Debtor, Creditor and Turnover
Mechanics Of Accounting:
• Cash Books, Sales Book, Purchase Book, Debit/Credit Note, Journal,
Ledger
• Financial Accounting, Accounting Equation, Balance Sheet, Income
Statements, Preparation and Analysis of Financial Statements,
Analysis and Interpretation of Financial Statements, Cash Flow
Statements and Ratio Analysis
Management Information System:
MIS Definition, Objectives, Functions, Difference between Data and
Information, Information as Organizational Resource, Qualities of Good
Information, Management Information Categories, Designing
Information Systems, Integrated Information Systems 08
Course Outcomes
Learners should be able to:
• Apply concepts and knowledge of management to excel in their careers.
• Prepare detailed plans, organization structures and use modern tools for decision making.
• Utilize the knowledge of corporate government structures and government laws to upgrade
their skills.
• Identify concepts of production and quality management to improve productivity and
quality in manufacturing plants.
• Relate concepts of marketing and sales to improve profitability of busine ss.
• Analyses the tools of finance and accounting to keep control and improve profitability in
the industry.
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64
BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Internal Assessment (20 Marks):
Two Class Tests (Compulsory):
• First test will be based on approximately 40% of content of the syllabus.
• Second test will be based on the remaining content of the syllabus (approximately 40% but
excluding contents covered in Test I).
End Semester Examination (80 marks):
• Weightage of each module in end semester examination will be proportionate to number
of respective lectures.
• Question paper will comprise of total six questions, each carrying 20 marks.
• Question 1 will be compulsory and should cover maximum contents of the curriculum.
• Remaining questions will be mixed in nature (for example if Q.2 has part (a) from
module 3 then part (b) will be from any module other than module 3)
• Only Four questions need to be solved .
Reference Books:
1. Industrial Engineering and Management -O.P. Khanna, Dhanpat Rai publications
2. Fundamentals of Business Organization and Management, Y.K. Bhushan, S. Chand
3. Industrial Organization and Management: Dani, Sabhalok, Parikh, Shahani -Manan
Prakashan
4. Engineering M anagement, A.K. Gupta, S. Chand
5. Basic Financial Accounting for Management, Paresh Shah, Oxford Press
6. Industrial Organization and Management, Basu S.K ,Prentice Hall India Learning Private
Limited
7. Work Organization and Human Resource Management, Editors: Carolina Machado · J.
Paulo Davim, Springer
8. Personnel Management – C.B. Mammoria, Himalaya
9. Case Studies in Personnel Management Industrial Relations and Trade Unions, Dr.
Anandram, Everest Publishing House
10. Cases in Personnel Management, Shyamkant Gokhale, Everest Publication
11. Environmental Audit: ISO -19011, Qualities of Environmental Auditor, Contents of EA
reports
12. R. K. Trivedy – Handbook of Environmental Laws, Guidelines, Compliance & Standards,
Vol. 1 & 2 Environ – Media karad, India
13. Sharma, J.P., Corpor ate Governance and Social Responsibility of Business, Ane Books
Pvt. Ltd, New Delhi
Recommended Text Books:
1. Management for Business and Industry -C.S. George Jr.
2. Principles of Management – Knoots and O. Donnell
3. Business Organization and Management – M.C. Shulka
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHL601 Mass Transfer Operation II Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 3 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 25 -- 50
1. Knowledge of chemistry, physics, physical chemistry, mathematics.
2. Knowledge process calculations (Material and energy balance).
3. Basics of unit operations.
4. Basic understanding of equilibrium.
5. Understanding of physical and chemical properties of compounds.
6. Students should know precautions to be taken in labor atories.
1. To understand different types of distillations and to obtain VLE data for binary systems. Also,
to check experimental and theoretical results for flash, differential and fractional distillation.
Students will also find no of stages at total reflux for fractional distillation.
2. To study extraction and find distribution coefficient in binary system. Also, to perform cross
current multistage extraction and compare it with single stage extraction.
3. To determine recovery in s ingle and multistage leaching.
4. To verify isotherms for adsorption. Also, to draw break through curve for fixed bed adsorption
and determine breakthrough time.
5. To determine yield in crystallization.
6. To study distillation, adsorption, extraction leaching equipments and their working.
• Verification of Rayleigh’s Equation
• To determine the percentage recovery of solute by solid liquid leaching operation
(multistage cross -current).
• To determine the vapour -liquid equilibrium curve.
• To find out distribution coefficient. [Eg. acetic acid between water and toluene]
• To verify Freundlich adsorption isotherm
• To find the yield of cr ystals in batch crystallizer.
• To prepare the ternary phase diagram of Binodal curve and tie line relationship for ternary
system Prerequisites
Lab Objectives
List of Experiments
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • To study distillation of total reflux in a packed column.
• To determine the efficiency of steam distillation
• To study the perfor mance of Swenson Walker crystallizer and also to determine the yield.
• To carry out multistage cross current operation in liquid liquid extraction and compare with
single stage operation
• To carry out multistage cross current adsorption and compare with si ngle stage operation.
• Note: Virtual platforms can be used for better understanding of concepts (Virtual platform
should be used for at least one Experiment).
Lab Outcomes
1. Students will be able to determine no of stages at total reflux for fractional
distillation. They will be able determine experimental and theoretical recovery of separation.
2. Students will be able to calculate recovery for single and multistage extr action.
3. Students will be able to verify isotherms and determine nature of adsorption. Also,
they will be able to determine break through and exhaustion time and parameters affecting
breakthrough curve.
4. Students will be able to find recovery in single and multistage leaching operations.
5. Students will be able to determine recovery in batch crystallization.
6. Students will be able to find number of stages, minimum reflux ratio, no of stages at total reflux
for tray columns and NTU, HTU, height of bed for packed columns. They will be able to decide
suitable equipment for given separation.
Term work
Term work should evaluated based on performance in practical.
Practical journal: 20 marks
Attendance: 05 marks
Total: 25 marks
Practical Examination
• Duration for practical examination will be same as assigned to respective lab per week
A student will become eligible for practical examination after completing 8 out of 10 experiments
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHL602 Chemical Reaction Engineering -II Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 25 - 50
Prerequisites
1. Basic knowledge of chemistry
2. Knowledge of data fitting , differential equation
3. Concept of Molarity, Normality
4. Knowledge of lab safety rules.
Course Objectives
1. Understand techniques to determine residence time distribution studies in different types
of reactor.
2. Apply RTD studies for analysis of Non ideal reactor.
3. Identify mode of operation in case of Semi batch reactor
4. Understand adiabatic mode of reactor operation and predict batch operation time
5. Determination of catalyst properties and significance in reactor design
6. Develop kinetics of Solid Fluid non catalytic reaction .
Course Outcome
On completion of the course the students will be able to:
1. employ various methods to determine residence time distribution in different types of
reactor.
2. interpret RTD data and predict the behavior of real reactor.
3. acquire analytical skills for the analysis of Adiabatic batch reactor.
4. understand operation of Semi batch reactor.
5. analyze experimental data collected to determine catalyst properties
6. able to determine controlling resistance in case of non catalytic reaction.
List of Experiments (minimum eight)
Experiment no. Details of Experiment Lab Hours
1 Residence Time Distribution (RTD) In Continuous Stirred
Tank Reactor (CSTR) - Pulse Input 3
2 Residence Time Distribution (RTD) In Plug Flow Reactor
(PFR) – Pulse Input 3
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 3 Residence Time Distribution (RTD) In Packed Bed Reactor
(PBR) – Pulse Input 3
4 Residence Time Distribution (RTD) In Continuous Stirred
Tank Reactor (CSTR) – Step Input 3
5 Residence Time Distribution (RTD) In Plug Flow Reactor
(PFR) – Step Input 3
6 Void volume, Porosity and solid density of catalyst 3
7 Semi batch reactor 3
8 Solid fluid heterogeneous non – catalytic reaction 3
9 Study of adsorption isotherm and calculation of specific
surface area of catalyst 3
10 Adiabatic batch reactor 3
11 Experiments from Virtual Lab 3
Assessment:
Term Work (25 marks)
Distribution of marks will be as follows:
Laboratory work: 15 marks
Assignments: 05
Attendance: 05
End Semester Practical Examination/orals (25 marks)
Practical Examination will be on experiments performed in the laboratory
Reference Books
1. Levenspiel O., Chemical Reaction Engineering, John Wiley&Sons,3ed.,1999.
2. Smith J.M., Chemical Reaction Engineering, 3ed.,Tata McGra wHill,1980.
3. Fogler, H.S. Elements of Chemical Reaction Engineering, 4ed.,PHI, 2008
4. www.vlab.co.in
5. http://www.olabs.edu.in/
6. http://amrita.olabs.edu.in/
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHL603 Pollution Control Technology Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 25 - 50
Prerequisites
Basic concepts of Fluid Flow Operations, Solid Fluid Mechanical Operations,
Mass Transfer Operations and Chemical Reaction Engineering.
Course Objectives
1. The aim of the course is to provide basic understanding of air and water pollution control,
regulations, standards.
2. Course will provide basics of water pollution sources, properties, measurement and
control techniques.
3. Course will provide air pollutions sources, properties, measurements, control methods,
design of pollution control devices and efficiency analysis, as well as their applications.
4. Course will provide understanding of solid waste and noise pollution management.
5. Course will provide understanding of waste management in chemical industries.
6. Course will provide understanding of zero discharge management in chemical industries.
Course Outcomes
After successfully completing the course, the students will be able to
1 Acquire the knowledge and understanding of the methods and technologies to reduce the
effects of pollution.
2 Understand the basic concepts of water and waste water quality standards.
3 Acquire a working knowledge of parameters to be examined in water and waste waters for
various purposes.
4 Get a working knowledge of preparation of standard solutions and reagents.
5 Do experimental projects on water and air quality measurements.
6 Test and assess water and air samples.
Experiment no. List of Experiments (minimum 8 practical to be performed) Hours
1 To determine the concentration of CO 2 present in waste water sample. 3
2 To determine the alkalinity of a water sample. 3
3 Determination of dissolved oxygen (DO) present in various water
samples. 3
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme 4 Determination of chemical oxygen demand (COD) present in waste
water sample. 3
5 Determination biological oxygen demand (BOD) present in waste
water sample 3
6 To determine pH, TDS, SS of wastewater. 3
7 Measurement of gaseous pollutant present (any one) in air. 3
8. Measurement of particulate matter pollutant present in air. 3
9. Measurement of sound level at various locations. 3
10. Determination of Sludge Volume Index and design of clarifier for
settling sludge. 3
Term work
Term work shall be evaluated based on performance in practical.
Practical Journal: 20 marks
Attendance: 05 marks
Total: 25 marks
Practical Examination
Duration for practical examination would be the same as assigned to the respective lab per week.
A student becomes eligible for practical examination after completing a minimum of eight out
of ten experiments
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHL604 Skilled based lab: Piping Design Engineering Lab 1.5
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 03 - - 1.5 - 1.5
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 - 25 50
1. Basic computer skills including MS EXCEL is essential.
2. Basic Knowledge of Fluid Flow Operation
3. Process Equipment design material Selection
1. To understand crucial role of piping engineer in chemical engineering projects
2. To understand the piping fundamentals, codes and standards
3. To understand materials used for pipings and fittings
4. To un derstand the control valve sizing, line hydraulics, pump head calculations, pipe rack
design
5. To create piping layout ,P & ID ,isometric drawings and plot plan
6. To understand stress analysis, network analysis, flexibility analysis and surge analysis for
chem ical plants
Course Outcome
On completion of the course the students will be able to:
1. To apply piping standards in design of complex piping networks.
2. To solve complex engineering problem of selection of appropriate material for pipes and
fittings for chemical plants
3. To identify, analyze and solve pipe sizing, pump sizing, valve sizing and pipe -valve -pump
selection problems
4. To design and draw piping n etworks, piping layout ,P & ID ,isometric drawings and plot
plan by considering legal, environmental, societal and ethical aspects
5. To use modern IT tools such as MS Excel/Libre office Calc/WPS spreadsheets, DWSIM,
AutoCAD 2D and 3D,CAE demo and Edraw Fluid flow for design and analysis of piping
networks
6. To carry out stress analysis, network analysis, flexibility analysis and surge analysis for
chemical plants which will benefit society and environment by following strict ethical
standards. Prerequisites
Course Objectives
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme
List of Experiments (Minimum eight)
For all the experiments select any suitable chemical industry or section of chemical industry and
do the calculations or drawings. The piping experiments must be carried out on piping network
and not on isolated piece of pipe.
Experiment no. Details of Experiment Lab Hours
1 Introduction to Code and Standards: IS, AWWA, IWWA,
ASME, ANSI, BS, HIS, CPHEEO Manual, ISO, DIN and
Material selection of pipes and fittings. 3
2 Equivalent diameter calculations of pipelines 3
3 Control valve sizing and selection of valves 3
4 Pipe sizing, thickness calculation and Pump head
calculations 3
5 Line hydraulics and network analysis: Flow rate and
Pressure drop calculations 3
6 Pipe stress analysis for piping and piping support by using
CAE 3
7 Piping layouts for a given chemical process on AutoCAD 3
8 Preparation of Piping and Instrument Diagram for a given
chemical process on AutoCAD/DWSIM 3
9 Developing plot plan from given data on Autocad 3
10 Pipe rack design 3
11 Piping engineering of standard piping modules like
distillation column piping, heat exchanger piping, tank
piping, vessel / drum piping, reformers piping. Any one of
this module should be given to students . 3
12 Flexibility analysis calculations for pipin g 3
13 Water hammer /surge analysis for piping 3
Note: All the Experiments (Minimum eight) should perform using any open source software (such
as MS Excel/Libre office Calc/WPS spreadsheets, DWSIM, Autocad 2D and 3D, CAE demo and
Edraw etc.,) or any paid software (PDMS,CAESAR, Smart Plant 3D, Smart Plat Review, Revit,
Plant 3D, SP3D, Navisworks, Smart Plant Review, Smart P&ID etc.) if available in institute.
Assessment:
Term Work (25 marks)
Distribution of marks will be as follows:
Laboratory work: 20 marks
Attendance : 05 marks
End Semester Orals (25 marks)
Orals on experiments carried out in the laboratory.
Recommended Books
1. Warren L. Mccabe, Julian C. Smith, Peter Harriott, Unit Operations of Chemical
Engineering, McGraw H ill International Edition.
Reference Books
1. The Engineer’s guide to plant layout and piping design in oil and gas industries by Geoff
Barker, Gulf professional publishing
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme Semester VI
Course Code Course Name Credits
CHM601 Mini Project -2B 1
Course Hours Credits Assigned
Theory Practical Tutorial Theory Practical Tutorial Total
- 02 - - 1 - 1
Theory Term
Work/Practical/Oral
Total Internal Assessment End
Sem
Exam Duration of
End Sem
Exam
TW
PR/OR
OR Test-I Test-II Average
- - - - - 25 - 25 50
Objectives:
1. To acquaint with the process of identifying the needs and converting it into the problem.
2. To provide knowledge of unit operation and unit process.
3. To familiarize the process of solving the problem in a group.
4. To acquaint with the process of applying basic engineering fundamentals to attempt
solutions to the problems.
5. To inculcate the process of self -learning and research.
6. Design and development of Small project based on various process and software
Course Outco me:
At the end of this course, students will be able to:
1. Identify problems based on societal /research needs.
2. Reproduce, improve and refine technical aspects for engineering projects.
3. Draw the proper inferences from available results through theoretical/ experimental /
simulation
4. Identify, discuss and justify the technical aspects of the chosen project with a
comprehensive and systematic approach.
5. Students will be able to practice acquired knowledge within the chosen area of technology
for pro ject development.
6. Work as an individual or in a team in development of technical projects, which leads to
lifelong learning.
Guidelines for Mini Project
➢ Students shall form a group of 3 to 4 students, while forming a group shall not be allowed
less than t hree or more than four students, as it is a group activity.
➢ Students should do survey and identify needs, which shall be converted into problem
statement for mini project in consultation with faculty supervisor/head of
department/internal committee of facu lties.
➢ Students hall submit implementation plan in the form of Gantt/PERT/CPM chart, which
will cover weekly activity of mini project.
➢ A log book to be prepared by each group, wherein group can record weekly work progress,
guide/supervisor can verify and r ecord notes/comments.
➢ Faculty supervisor may give inputs to students during mini project activity; however, focus
shall be on self -learning.
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme ➢ Students in a group shall understand problem effectively, propose multiple solution and
select best possible soluti on in consultation with guide/ supervisor.
➢ Students shall convert the best solution into working model using various components of
their domain areas and demonstrate.
➢ The solution to be validated with proper justification and report to be compiled in stand ard
format of University of Mumbai.
➢ With the focus on the self -learning, innovation, addressing societal problems and
entrepreneurship quality development within the students through the Mini Projects, it is
preferable that a single project of appropriate level and quality to be carried out in two
semesters by all the groups of the students. i.e. Mini Project 2 in semester V and VI.
➢ However, based on the individual students or group capability, with the mentor’s
recommendations, if the proposed Mini Project adhering to the qualitative aspects
mentioned above gets completed in odd semester, then that group can be allowed to work
on the extension of the Mini Project with suitable improvements/modifications or a
completely new project idea in even semester. Thi s policy can be adopted on case by case
basis.
Guidelines for Assessment of Mini Project:
Term Work
• The review/ progress monitoring committee shall be constituted by head of departments of
each institute. The progress of mini project to be evaluated on continuous basis, minimum
two reviews in each semester.
• In continuous assessment focus shall also be on each individual student, assessment based
on individual’s contribution in group activity, their understanding and response to
questions.
• Distribution of Term work marks for both semesters shall be as below;
➢ Marks awarded by guide/supervisor based on log book : 10
➢ Marks awarded by review committee : 10
➢ Quality of Project report : 05
Review/progress monitoring committee may consider following points for assessment based
on either one year or half year project as mentioned in general guidelines.
One-year project:
• In first semester entire theoretical solution shall be ready, including components/system
selection and cost analysis. Two reviews wil l be conducted based on presentation given by
students group.
• First shall be for finalization of problem
• Second shall be on finalization of proposed solution of problem.
• In second semester expected work shall be procurement of components/systems, building
of working prototype, testing and validation of results based on work completed in an
earlier semester.
• First review is based on readiness of building working prototype to be conducted.
• Second review shall be based on poster presentation cum demonstration of working model
in last month of the said semester.
Half -year project:
• In this case in one semester students’ group shall complete project in all aspects including,
• Identification of need/problem
• Proposed final solution
• Procurement of components/systems
• Building prototype and testing
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BE Chemical Engineering University of Mumbai TE Syllabus Revised 2019 ‘C’ Scheme • Two reviews will be conducted for continuous assessment,
• First shall be for finalization of problem and proposed solution
• Second shall be for implementation and testing of solution.
Assessment criteria of Mini Project.
Mini Project shall be assessed based on following criteria;
1. Quality of survey/ need identification
2. Clarity of Problem definition based on need.
3. Innovativeness in solutions
4. Feasibility of proposed problem solutions and selection of best soluti on
5. Cost effectiveness
6. Societal impact
7. Innovativeness
8. Cost effectiveness and Societal impact
9. Full functioning of working model as per stated requirements
10. Effective use of skill sets
11. Effective use of standard engineering norms
12. Contribution of an individual’s as member or leader
13. Clarity in written and oral communication
• In one year, project, first semester evaluation may be based on first six criteria’s and
remaining may be used for second semester evaluation of performance of students in mini
project.
• In case of half year project all criteria’s in generic may be considered for evaluation of
performance of students in mini project.
Guidelines for Assessment of Mini Project Practical/Oral Examination:
• Report should be prepared as per the guideli nes issued by the University of Mumbai.
• Mini Project shall be assessed through a presentation and demonstration of working model
by the student project group to a panel of Internal and External Examiners preferably from
industry or research organizations h aving experience of more than five years approved by
head of Institution.
• Students shall be motivated to publish a paper based on the work in Conferences/students
competitions.
Mini Project shall be assessed based on following points;
1. Quality of problem a nd Clarity
2. Innovativeness in solutions
3. Cost effectiveness and Societal impact
4. Full functioning of working model as per stated requirements
5. Effective use of skill sets
6. Effective use of standard engineering norms
7. Contribution of an individual’s as member or leader
8. Clarity in written and oral communication.
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