bsc syllabus 2009

8/2/2019 BSc Syllabus 2009

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Department of Chemical Engineering & Polymer Science, SUST

B. Sc. Engg. Session: 2009-2010

First Year Semester I

Course No. Course Title Hours/Week Theory + Lab.

Credits

CEP-111* Elements of Chemical Engineering - I 2 + 0 2.0

CEP-112 Physical Chemistry - I 2 + 0 2.0

CEP-113 Inorganic Chemistry 2 + 0 2.0

CEP-115 Chemistry Sessional-I 0 + 6 3.0

PHY-101C Mechanics, Properties of Matter & Waves 3 + 0 3.0

MAT-102E Mathematics (Geometry, Matrix & Vector Calculus) 3 + 0 3.0

IPE-102* Mechanical Engg. Drawing Sessional 0 + 3 1.5

ENG-101 English Language -I 2 + 0 2.0

ENG-102 English Language Sessional 0 + 2 1.0

Total 14 + 11 = 25 19.5

First Year Semester II

Course No. Course Title Hours / Week

Theory + Lab.

Credits

CEP-116 Physical Chemistry - II 2 + 0 2.0

CEP-117 Analytical Chemistry 2 + 0 2.0

CEP-119* Elements of Chemical Engineering - II 2 + 0 2.0

CEP-120 Chemistry Sessional-II 0 + 6 3.0

MAT-103E Mathematics (Diff. & Integral Calculus) 3 + 0 3.0

PHY-109 Heat, Electricity, Magnetism and Modern Physics 3 + 0 3.0

STA-105 General Statistics 3 + 0 3.0

ENG-103ENG-104

English LanguageEnglish Language Sessional

2 + 00 + 2

2.01.0

CEP-121 Oral 1.0

CEP-122 Mass & Energy Balance Sessional 0 + 4 2.0

Total 17 +12=29 24.0

Second Year Semester I

Course No. Course Title Hours/Week

Theory + Lab.

Credits

CEP-211* Fluid Mechanics 3 + 0 3.0

CEP-212* Chemical Engineering Thermodynamics 3 + 0 3.0

CEP-213* Polymer Chemistry 3 + 0 3.0CEP-214 Fluid Mechanics Sessional 0 + 6 3.0

CEP-215 Organic Chemistry 2 + 0 2.0

CSE-105 Introduction to Electric and Electronic Circuits Theory 3 + 0 3.0

CSE-106 Introduction to Electric and Electronic Circuits Lab 0 + 3 1.5

IPE-205* Engineering Mechanics 3 + 0 3.0

IPE-204 Workshop Practice Sessional 0 + 2 1.0

MAT-202E Mathematics (Differential Equations & MathematicalMethods)

3 + 0 3.0

Total 20+ 11= 31 25.5


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Second Year Semester II

Course No. Course Title Hours/Week

Theory + Lab.

Credits

CEP-216* Heat Transfer 3 + 0 3.0

CEP-218* Polymer Properties 2 + 0 2.0

CEP-219 Chemical Process Technology -I 2 + 0 2.0

CEP-220 Heat Transfer Sessional 0 + 6 3.0

IPE-207 Mechanics of Solids 3 + 0 3.0

CSE -203A Introduction to Computer Language 2 + 0 2.0

CSE-204A Introduction to Computer Language Sessional 0 + 6 3.0

MAT-206E Mathematics (Numerical Analysis) 3 + 0 3.0

CEP-221 Oral 1.0

CEP-222* Industrial Tour 0.0

Total 15+ 12 = 27 22.0

Third Year Semester I

Course

No.

Course Title Hours/Week

Theory + Lab.

Credits

CEP-311* Mass Transfer- I 3 + 0 3.0

CEP-312 Chemical Process Technology - II 2 + 0 2.0

CEP-313* Polymer Processing Technology 3 + 0 3.0

CEP-314 Instrumental Analysis 2+ 0 2.0

CEP-315 Fuel and Energy 2 + 0 2.0

CEP-316 Chemical Process Principles Sessional 0 + 4 2.0

CEP-317 Polymer Chemistry Sessional 0 + 4 2.0

Total 12+ 8= 20 16.0

Third Year Semester II

Course No. Course Title Hours/WeekTheory + Lab.

Credits

CEP-318* Chemical Reaction Engineering 3 + 0 3.0

CEP-319 Science and Engineering of Materials 3 + 0 3.0

CEP-321 Electrochemical Engineering 2 + 0 2.0

CEP-322* Mass Transfer II 3 + 0 3.0

CEP-323 Process Equipment Design Sessional 0 + 6 3.0CEP-325 Fuel and Energy Sessional 0 + 4 2.0

CEP-326 Polymer Characterization Sessional 0 + 4 2.0

CEP-327 Mass Transfer Sessional 0 + 6 3.0

CEP-328 Field Work/In-plant Training- I 2.0

CEP-329 Oral 1.0

Total 11 + 20 = 31 24.0


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Fourth Year Semester I

Course

No.

Course Title Hours/Week

Theory + Lab

Credits

CEP-411 Corrosion Engineering 2 + 0 2.0

CEP-412* Process Control 3 + 0 3.0

CEP-414* Process Design 3 + 0 3.0

CEP-415 Industrial Economics and Management 3 + 0 3.0

CEP-417 Chemical Reaction Engineering Sessional 0 + 4 2.0

CEP-418 Plant Design Sessional 0 + 6 3.0

CEP-419 In-plant Training-II / Field Work 2.0

Total 11 + 10 = 21 18.0

Fourth Year Semester IICourse No. Course Title Hours/Week

Theory + Lab.

Credits

CEP-420 Transport Phenomena 2 + 0 2.0

CEP-421 Environmental Engineering 3 + 0 3.0

CEP-422 Natural Gas and Petroleum Engineering. 2 + 0 2.0

ELECTIV

E

I 2 + 0 2.0

ELECTIV

E

II 2 + 0 2.0

CEP-429** Thesis 0 + 6 3.0

CEP-430 Oral 1.0

CEP-431** Project 0 + 6 3.0Total 11 + 6 = 17 15.0

Course No. 429/431 will be offered in lieu of Course No. 427& 428

* & ** degree will not be awarded without completion of these coursesTheory courses are mandatory for attending corresponded laboratory/sessional courses.


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Detailed Syllabus

CEP 101 PROCESS TECHNOLOGY (For IPE)

2 Hours / week, 2 Credits

Pulp and Paper Industries: Raw materials, mfg. of different types of pulp paper boards, black lacquerrecovery, deinking of waste paper, pulp and paper industries in Bangladesh. Soap and Detergent Industries:Raw materials, mfg. of different types of soap, recovery of the glycerin, classification of the detergents,industrial processing for the alkyl aryl sulphonates (AAS), environmental pollution by detergents.

Biodegradability of detergents. Introduction of Chemical fertilizer:Nitrogenousfertilizer : Raw materials ofammonia production of synthesis gas in ammonia plants, technology of urea manufacturing; Process used in

Urea industries of Bangladesh . Cement industries: Composition, properties and uses different types of

cements, manufacture of cement by different methods, setting and hardening of cement, testing of cement.

Lubricants: Various types of lubricants, Production of lubricants, Properties of Various types of lubricants.

References:

1. G.N Pandey A Text Book of Chemical Technology Vol. I and II2. N. Austin Chemical Process Industries.3. Anderson and Winzet Introduction to Chemical Engineering

4. Riegls Industrial Chemistry5. B. K. Sharma Industrial Chemistry

6. S.S. Dara A text book of Engineering Chemistry.

CEP -111* ELEMENTS OF CHEMICAL ENGINEERING-I

2 Hours/Week, 2 Credits

Principles of chemical engineering calculation: Units, dimensions, conversion and system of units, force andweight, process data representation and analysis, the chemical equation and stoichiometry. Process variables:

Classification, flow rate, mass, volume, composition, pressure, temperature. Material balance: MaterialBalances for Steady State Processes - Properties of gases, liquids and solids equations of state, phase

equilibria for ideal mixtures, Reactions and stoichiometry, Non-Reacting single phase systems - Single andmultiple units without recycle, Systems with recycle, bypass and purge, Non-Reacting multi-phase systems -

Processes involving vaporization and condensation, Reacting systems.

References:

1. R. Felder, R. Rousseau Elementary Principle of Chemical Processes2. Himmelblau, Basic Principles and Calculations in Chemical Engg.

3. Badger and Banchero, Introduction to chemical engineering

4. R.W. Field Chemical Engineering :Introductory Aspects

CEP- 112 PHYSICAL CHEMISTRY-I

2 hours/week, 2 credits

Properties of Gases and The Kinetic Molecular Theory: The kinetic theory of gases, Boyle's Law , Graham's

Law of Diffusion, The distribution of molecular velocities, Vander Waals' Equation. Intermolecular Forces,Condensed Phases, and The Change of phases: vander Wals Forces, The Hydrogen Bond, The intermolecularpotential energy function,Vaporization, fusion and sublimation. Gas-Liquid Equilibrium, Equilibrium vapor

pressure. Nature of the equilibrium state. Normal boiling point. Vapor phase of solids, one-component phasediagram. Critical temperature and pressure. Energy, Enthalpy and Thermochemistry: State functions. Heat

and Work. Work of expansion, Mechanical equivalent of heat.Energy and Enthalpy - at constant volume andpressure, relationship between H and E. Bond Enthalpies. Heat capacity. Chemical Equilibrium: The ideal

Law, Equilibrium constant, Magnitude of equilibrium constant and the direction of reaction, factors affectingequilibrium constant, Le Chatelier's Principle. Numerical values of equilibrium constant. Catalysis:Characteristics of catalysed reaction, types of catalysis, theory of catalysis, catalyst inhibitor, retardation andpoisioning and enzyme catalysed reaction.

References:

1. Segal B G Chemistry: Experiment and Theory2. Barrow G M Physical Chemistry


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3. Atkins Physical Chemistry4. Alberty Physical Chemistry

CEP - 113 INORGANIC CHEMISTRY ( General Chemistry 3 Hours/week, 3 Credits)

2 Hours/Week, 2 CreditsNuclear Chemistry: Introduction, Nuclear binding energy, Radioactivity and nuclear reactions, Ortho- and

para-hydrogen, The separation of stable & unstable isotopes, The application of isotopes. Quantum Theoryand Atomic Structure: Introduction, The older quantum theory, Bohrs theory of the atomic spectrum of

hydrogen, The extension of Bohrs theory to systems containing more than one electron, Wave mechanics, TheSchroodinger equation, Application of wave mechanics to simple problems, The hydrogen atom and other one-

electron species. Electronic Configuration and Some Physical Properties of Atoms: Introduction, The periodictable, Hunds rule and state symbols for free atoms and ions, Ionization energies, Electron affinities, Atomic

dimensions, Reletive effects. Electronic Configuration of Molecules: Introduction, Molecular orbital theory:

homonuclear & heteronuclear diatomic molecules, Valence bond theory: diatomic molecules.

Reference:

Alan G. Sharpe Inorganic Chemistry

Bonding in Organic Molecules: Bonding, Structural formulas of organic compounds, electronegativity and

dipoles, atomic orbital, electron configurations, molecular orbital and bonding LCAO, sigma and pi- bonds,hybrid orbital, bond angles and bond energies. Classes and nomenclature of organic compounds. Aliphatichydrocarbons: Preparation, uses, physical and chemical properties of saturated and unsaturated hydrocarbon.

Dienes and polymerization: isolated double bond, Allen cumulated double bonds, conjugated double bonds,polymerization, Diels-Alder reaction. Aromatic Hydrocarbon : structure and bonding in benzene;

aromaticity, electrophilic aromatic substitution; Fridel Craft alkylation and acylation, direction and ease ofaromatic substitution resonance and inductive effect, the steric effect, principles of higher substitution. Halides:

Structure and preparations: The halide exchange: SN2 and SN1 mechanism reactions, General SN2 reaction ofhalides, Grignard reagent. Alcohols: General preparations, physical properties and general reactions, Distinction

between primary, secondary and tertiary alcohols. Phenols: Preparation, properties and reactions, electrophilicaromatic substitutions. Acidity of phenols, synthesis and naturally occurring phenol derivatives. Ethers and

Epoxides: General preparations, The Williamson Synthesis, epoxide, physical properties, reaction. Carbonylcompounds: General methods of preparation, reactions, nucleophilic addition to carbonyls. Carboxylic acids

and derivatives: preparation, properties and uses.

References:

1. Bhal and Bhal Organic Chemistry.

2. R.T Morrison & R.N. Boyd Organic Chemistry References:1. Bhal and Bhal Organic Chemistry.

2. R.T Morrison & R.N. Boyd Organic Chemistry3. F.A Carey Advance Organic chemistry

4. T.W.G. Solomon Organic Chemistry5. I. L. Finer, vol. I & II Organic Chemistry

6. Solomon and Solomon Organic Chemistry.

CEP 115 CHEMISTRY SESSIONAL-I

6 Hours/week, 3.0 Credits

Laboratory Classes based on qualitative analysis (introduction to lab techniques and chemical analysis).

CEP 116 PHYSICAL CHEMISTRY-II

2 Hours/week, 2 Credits

Solutions: Colligate properties;lowering thevapor pressure, elevation of b.p. depression of freezing point, andosmotic pressure, Roults law. Chemical kinetics: Order and molecularity of reactions, rate equations, for zero,

first, second and third order reaction. Theories of reaction rates. Chain reactions, reaction in solutions, kinetic

model for non-elementary reactions. Phase Digram: The phase Rule and its application for one and twocomponent systems, constant temperature, constant boiling mixture, deliquescence, congruent and incongruent

melting point, vapor pressure of saturated solutions. Colloid: ionic purification and properties of colloids, origin

of electrical charge and charge particles, ionic miscelles. Photochemistry: Photon, law of photo chemistry,


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absorption law and mechanism of photochemical reaction, fluorescence, phosphorescenceand chemiluminescences.

References:

1. G.M. Barrow Physical Chemistry2. Haque & Nawab Physical Chemistry

3. Bernice G. Segal Chemistry, Experimental & Theory4. Gurdeep Raj Advanced Physical Chemistry

CEP 117 ANALYTICAL CHEMISTRY


Introduction: Some General Aspects of Volumetric Titrimetry, Standard Solution Volumetric Calculations

,Weight Titrimetry. Aqueous-Solution Chemistry: The chemical composition of aqueous solutions, Chemical

Equilibrium .Activities and Activity Coefficients : The effects of electrolytes on Chemical Equilibrium, activitycoefficients, Systematic Method for Performing Equilibrium Calculations: A systematic method for solving

multiple-equilibrium, the calculation of solubility by systematic method, separation of ions control of the

concentration of a precipitating reagents. Theory of Neutralization Titrations: solutions and indicators forneutralization titrations, titration curves for strong acids and strong bases , buffer solutions, titration curves for

weak acid , titration curve for weak bases, the composition of buffer solutions as function of p H. Theory of

Oxidation/Reduction Titrations : Equilibrium Constants for oxidation/reduction reaction, redox titration curves,oxidation/reduction indicators, potentiometric end points. The assessment of analytical data, definitions andbasic concepts: The nature and origin of errors; the evaluation of results and methods; stability of

measurements; the analysis of data; the application of statistical tests; limit of detection.

References:

1. Skoog and West Fundamentals of Analytical Chemistry

2. G. Christian Analytical Chemistry3. Fifield and Kealy Principle of Analytical Chemistry

CEP 119* ELEMENTS OF CHEMICAL ENGINEERING-II2 Hours/week, 2 Credits

Energy and Energy Balance: Form of energy, Kinetic and potential energy, energy balance on closed system

and open system at steady state,. Energy balance procedure. Balance on Nonreactive process: State properties

and hypothetical process paths, change in pressure at constant temperature,change in temperature, phase changeoperations, mixing and solutions. Balance on reactive process: Forms of energy, energy balance procedure,

heats of reaction, measurement and calculation of heat of reaction, formation reaction, heats of formation, heatsof combustion, energy balance on reactive processes, fuel and combustion. Introduction to Computer Aided

Process Calculations - Degrees of Freedom and Specifications, Use of Spreadsheets, Tearing and Iterativetechniques in Flow sheeting.

References:

1. R. Felder, R. Rousseau Elementary Principle of Chemical Processes

2. Himmelblau, Basic Principles and Calculations in Chemical Engg.3. Badger and Banchero, Introduction to chemical engineering

4. R.W. Field "Chemical Engineering :Introductory Aspects", Macmillan, London (1988).

CEP 120 CHEMISTRY SESSIONAL-II


Laboratory classes based on lab unit operation and chemical analysis.

CEP-121 Oral

1 Credit

CEP 122 MASS & ENERGY BALANCE SESSIONAL


Laboratory classes based on elements of chemical engineering theory courses

CEP -211* FLUID MECHANICS

3Hours/Week, 3Credits


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Fluid Properties: Definition of Fluid, Properties of fluid, Fluid Statics: Pressure measurement, manometer.Kinetics of Fluid flow: Types of flow, Eulers acceleration formula ,Reynolds transport theorem ,equation of

continuity, momentum balance equation, energy balance equation, Bernoullis equation: equation of motionfor incompressible fluid : Navier -Stokes equations and Euler equation of motion . Steady Incompressible flow

in Pressure conduits : Laminar and Turbulent Flow, Critical Reynolds number, Hydraulic radius ,Entranceconditions ,Velocity profile , Pipe roughness , Major and minor head loss. Fluid flow measurement: Pitot tube,

orifice meter, venturimeter, rotameter. Pumps and compressors: .Introduction and classification of pumps,Pumps performance, Mixed and axial flow pumps, Matching pumps to system characteristics. Different types of

compressors, Positive displacement and Rotary compressors characterization and efficiency. Turbines:Operation and characteristics. Governing systems.

References:

1. Franzini Daugherty Fluid Mechanics with engineering applications.

2. Frank M. White Fluid Mechanics3. Streeter, Wylie, Bedford Fluid Mechnics

4. McCabe Smith Unit operation of chemical Engineering

CEP 212* CHEMICAL ENGINEERING THERMODYNAMICS


The first and second law of thermodynamics: Alternative statement of second law, Heat engine, temperaturescale, carnot cycle, entropy, entropy changes and irreversibility, lost work, third law of thermodynamics.Thermodynamic properties of fluids: Relationship among the thermodynamic properties, single phase and two

phase systems, types of thermodynamic diagrams. Thermodynamics of flow processes: Fundamental equations,flow in pipes, expansion processes, compression processes. Conversion of heat into work by power cycle:

Vapor cycle, steam power plant, internal combustion engine, Otto engine, Diesel engine, gas-turbine power plant, Jet engine. Refrigeration and Liquefaction: Carnot refrigeration cycles, vapor compression cycle,

comparison of refrigeration cycle, absorption refrigeration, heat pumps, and liquefaction process. Systems of

variable composition ; Ideal and non-ideal behavior: Relationships among thermodynamic properties, partial

molal properties, fugacity and fugacity coefficient, fugacities in ideal solutions, activity and activity coefficients.

Phase equilibria: Nature and criteria of phase equilibrium, the phase rule and Duhems theorem, vapor-liquid

solutions, Gibbs-Duhem equation.

References:1. J. M. Smith & H.C. Van Ness Introduction to Chemical Engineering Thermodynamics

2. J.M. Smith Chemical Engineering Thermodynamics

3. G.M. Barrow Physical Chemistry

4. B.G. Kyle Chemical & Process Thermodynamics

5. Narayanan Introduction to Chemical Engg. Thermodynamics

CEP 213* POLYMER CHEMISTRY

3 Hours/Week, 3 CreditsPolymer Chemistry Fundamentals: Basic concepts, definitions & classifications of monomers and polymers;

Concepts of plastics, rubbers & fibers; glass transition temperature, softening temperature, melting temperature,average molecular weights and molecular weight distribution. Theories & Principles of polymerization:

General kinetics & mechanisms of polymerization--free radical, step growth, ionic & stereospecific

polymerization, Copolymerization-its technical significance, copolymerization equations & copolymercomposition; random, block & graft copolymerization, monomer reactivity ratio; ideal, alternate & azeotropiccopolymerization. Techniques of polymerization: Bulk, solution, suspension & emulsion polymerization, their

comparative studies & relative importance. Some important polymer reactions: hydrolysis, acedolysis,aminolysis, hydrogenation, addition & substruction reactions. Polymer degradation: Thermal,

mechanochemical, oxidative & photo degradation.

References:

1. V.R. Gowariker, Polymer Science

2. F.W. Billmeyer, A text book of polymer Science

3. George Odian, Principles of Polymer4. R. J Young and P.A Lovel, Introduction to polymer

CEP 214 FLUID MECHANICS SESSIONAL

6 Hours/ week, 3.0 Credits


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Laboratory Classes based on fluid mechanics theory course.

CEP 215 ORGANIC CHEMISTRY


Bonding in Organic Molecules: Bonding, Structural formulas of organic compounds, electronegativity anddipoles, atomic orbital, electron configurations, molecular orbital and bonding LCAO, sigma and pi- bonds,

hybrid orbital, bond angles and bond energies. Classes and nomenclature of organic compounds. Aliphatichydrocarbons: Preparation, uses, physical and chemical properties of saturated and unsaturated hydrocarbon.

Dienes and polymerization: isolated double bond, Allen cumulated double bonds, conjugated double bonds,polymerization, Diels-Alder reaction. Aromatic Hydrocarbon : structure and bonding in benzene;

aromaticity, electrophilic aromatic substitution; Fridel Craft alkylation and acylation, direction and ease ofaromatic substitution resonance and inductive effect, the steric effect, principles of higher substitution. Halides:

Structure and preparations: The halide exchange: SN2 and SN1 mechanism reactions, General SN2 reaction of

halides, Grignard reagent. Alcohols: General preparations, physical properties and general reactions, Distinctionbetween primary, secondary and tertiary alcohols. Phenols: Preparation, properties and reactions, electrophilic

aromatic substitutions. Acidity of phenols, synthesis and naturally occurring phenol derivatives. Ethers and

Epoxides: General preparations, The Williamson Synthesis, epoxide, physical properties, reaction. Carbonylcompounds: General methods of preparation, reactions, nucleophilic addition to carbonyls. Carboxylic acids

and derivatives: preparation, properties and uses.

References:

1. Bhal and Bhal Organic Chemistry.

2. R.T Morrison & R.N. Boyd Organic Chemistry3. F.A Carey Advance Organic chemistry

4. T.W.G. Solomon Organic Chemistry5. I. L. Finer, vol. I & II Organic Chemistry

6. Solomon and Solomon Organic Chemistry.

CEP -201 FLUID MECHANICS (for FTT)3Hours/Week, 3Credits

Fluid Properties: Definition of Fluid, Properties of fluid, Fluid Statics: Pressure measurement, manometer.

Kinetics of Fluid flow: Types of flow, Eulers acceleration formula ,Reynolds transport theorem ,equation of

continuity, momentum balance equation, energy balance equation, Bernoullis equation: equation of motionfor incompressible fluid : Navier -Stokes equations and Euler equation of motion . Steady Incompressible flow

in Pressure conduits : Laminar and Turbulent Flow, Critical Reynolds number, Hydraulic radius ,Entranceconditions ,Velocity profile , Pipe roughness , Major and minor head loss. Fluid flow measurement: Pitot tube,

orifice meter, venturimeter, rotameter. Pumps and compressors: .Introduction and classification of pumps,Pumps performance, Mixed and axial flow pumps, Matching pumps to system characteristics. Different types of

compressors, Positive displacement and Rotary compressors characterization and efficiency. Turbines:Operation and characteristics. Governing systems.

References:

1. Franzini Daugherty Fluid Mechanics with engineering applications.2. Frank M. White Fluid Mechanics

3. Streeter, Wylie, Bedford Fluid Mechanics

4. McCabe Smith Unit operation of chemical Engineering

CEP 202 FLUID MECHANICS SESSIONAL (FOR FTT)

6 Hours/ week, 3.0 CreditsLaboratory Classes based on fluid mechanics theory course

CEP-216* HEAT TRANSFER

3 Hours/Week, 3 credits

Modes of heat transfer: Mechanism of thermal conduction in solids, liquids, and gases, other thermal

properties, steady state heat conduction in one and two dimensions, Heat transfer by convection, connective heattransfer for laminar and turbulent fluid flow in circular pipes. Extended surface, free and forced convection .


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Heat transfer with phase change: Boiling and condensation. Radiation : Black body radiation , exchangebetween infinite and finite surface in different enclosure, radiation shields, radiation from gases, flames, Solar

radiation.Heat Exchangers: LMTD and NTU method for temperature calculation, Double pipe heat exchanger, shell and

tube heat exchangersReferences:

1. Holman. J. P. Heat Transfer2. Kern , Process Heat Transfer

3. Ozisik Heat Transfer.4. Aurora S. C. Heat and Mass Transfer

CEP 218* POLYMER PROPERTIES


Polymer morphology: Lamellar crystals, spherulites, fringed micelle model, extended chain crystal, the effectof crystallinity on mechanical and optical properties, liquid crystal polymers. Polymer thermodynamics:Dissolution behavior of polymers, thermodynamics of polymer solution, Flory-Huggins Theory, Flory-Fox

theory, concepts of theta of temperature, size & shape of polymer molecules in solution, solubility parameter.Study of molecular weights of polymers: principles of determination of molecular weights by viscometry,

osmometry, dynamic and static light scattering techniques, gel permission chomatography, End group analysis.

Polymer rheology: The flow patterns of Newtonian & Non-Newtonian fluids; Bingham plastics, pseudoplastics& dilatant materials under shearing force, power law; Viscoelasticity: creep & relaxation effects, timedependency of flow under constant load & constant strain--understanding in terms of suitable mechanical

models.

References:

1. R,J Young and P.A Lovel Introduction to polymer

2. George Odian Principles of Polymer3. Paul J.Flory Principles of polymer Chemistry

4. Raymond B. Seymour Polymer Chemistry an Introduction5. Fred. Billmeyer A text book of polymer Science

6. Premamoy Ghosh Polymer Science & Technology of Plastics & Rubbers

CEP 219 CHEMICAL PROCESS TECHNOLOGY-I2 Hours/Week, 2 Credits

Sugar and starch industries: Manufacturing and refining of cane sugar, milling operation of the evaporator,

vacuum pan and centrifugal, utilization of by products of sugar industries, sugar specialties, sugar industries in

Bangladesh. Pulp and Paper Industries: Natural source of the cellulose, constituents associated with cellulose,mfg. of different types of pulp paper boards, black lacquer recovery, deinking of waste paper, pulp and paper

industries in Bangladesh. Soap and Detergent Industries: Raw materials, mfg. of different types of soap,recovery of the glycerin, classification of the detergents, industrial processing for the alkyl aryl sulphonates

(AAS), environmental pollution by detergents. Biodegradability of detergents. Glass industries: History ofdevelopment of glass industries composition, properties and uses of different types of glasses, manufacturer of

glass, special glasses. Cement industries: Composition, properties and uses different types of cements,manufacture of cement by different methods, setting and hardening of cement, testing of cement.

References:

1. G.N Pandey, A Text Book of Chemical Technology Vol. I and II2. N. Austin Chemical Process Industries.

4. Anderson and Winzet, Introduction to Chemical Engineering5. Riegls, Industrial Chemistry

6. B. K. Sharma, Industrial Chemistry

CEP 220 HEAT TRANSFER SESSIONAL

6 Hours/Week, 3.0 Credits.

Laboratory Classes based on Heat Transfer and Engineering Mechanics.

CEP 221 Oral

1 Credit

CEP 222* INDUSTRIAL TOUR


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0 Credit

CEP-311 * MASS TRANSFER-I

3 Hours/Week, 3 creditsIntroduction: Molecular diffusion & convective mass transfer, Interphase mass transfer, Absorption:

Mechanism of absorption. Determination of transfer coefficients. Gas absorption in packed column. Plate towersfor gas absorption . Distillation: Flash and Differential distillation, batch and continuous distillation with reflux,

Mc-Cabe Thiel construction, use of enthalpy-concentration diagram for stage calculation, tray efficiency, packed distillation column. Azeotropic and extractive distillation. Liquid-liquid extraction processes:Equilibrium relations in extraction. Single stage equilibrium extraction. Continuous multi-stage counter currentextraction. Evaporation: Single and multiple effect evaporation system. Heat economy of the evaporators,

Special types of the evaporators, heat sensitive materials handling in evaporators, Pressure factors.

References:

1.Geankoplise Transport Process & Unit Operation2. Mc Cabe and Smith, Unit Operation of Chemical Engineering

3. Binoy K. Dutta Principles of Mass Transfer and Separation Processes

4. Coulson and Richardson Chemical Engineering5. Robert E. Treybal Mass-Transfer Operations

CEP 312 CHEMICAL PROCESS TECHNOLOGY II

2 Hours/Week,2 Credits

Introduction of chemical fertilizer: Nitrogenous fertilizer : Raw materials of ammonia production ofsynthesis gas in ammonia plants, ammonia and urea manufacturing; prospects of urea fertilizer industries in

Bangladesh, Ammonium nitrate, ammonium sulfate and ammonium phosphate mfg. Process used in urea mfg.in Bangladesh. Development of Urea mfg. Potash fertilizer : source of potassium; production and use of

Murata of potash and other potassium fertilizers. Compounds, complex and mixed fertilizers, bio fertilizers.

Phosphate fertilizer : Raw materials; Chemistry and technology of phosphates and super phosphates, triple

superphosphate, prospects of phosphate fertilizer industries in Bangladesh. Ceramic industries: Types ofceramic products, Basic raw materials, White wares, manufacturer of porcelain, types of clay, clay preparation,

firing, different stages of firing, Chemical conversion including basic ceramic industry, different types of kiln,temperature recording in the kiln, heavy clay products, manufacture of refractories, varieties of enameled metalceramic industries of Bangladesh. Coating process: paint Varnish, and lacquer, constituents and their functions,

factor influencing satisfactory performance of surface coating, properties of pigments, binders and volatile

solvent s pigments of different colors, paint application, causes of paint failure, emulsion paints, manufacture ofpaints, varnish and lacquer, heat resistant and acid proof paints, enamels. Introduction to textile industry:

Textile fibres, Methods of investigating fibre structure, Dyeing. The chloro-alkali industry; General conceptsof brine electrolysis, modern technological developments, chlorine cell technologies, production of KOH,

equipments.

References:

1. G.N Pandey, A Text Book of Chemical Technology Vol. I and II

2. N. Austin Chemical Process Industries.

3. Anderson and Winzet, Introduction to Chemical Engineering4. Riegls, Industrial Chemistry5. B. K. Sharma, Industrial Chemistry

6. S.S. Dara, A text book of Engineering Chemistry

CEP 313* POLYMER PROCESSING TECHNOLOGY


Plastics Processing: Extrusion, Injection molding, Blow molding, Compression molding, plastics compounding;compounding ingredients, their types & functions; Transfer molding, Thermoforming.

Rubber processing: Principles & chemistry involved in mastication & compounding ingredients--accelerators,

accelerator activators, antioxidants, fillers & other additives; Vulcanization & various types of vulcanizationsystems; Rubber processing machineries-open mills & internal mixers, rubber extruders, calendars of different

types. Radiation processing techniques of polymers. Thin film preparation, gel content, properties

characterization (Tensile test, compression test, different types of hardness test, adhesion test, abrasion test,impact test, bend test), swelling ratio. Surface coating: Polymercuring of different substances (wood, leather,


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metal, paper, ceramics etc), Grafting on natural polymers (wood, jute, cotton, cellulose, silk etc) and onsynthetic polymer (polyethylene, polypropylene etc); Polymer loading, degree of grafting. Radiation effect on

synthetic polymers - degradability and stability. Processing of textile fiber: preparation and modification

References:

1. F.W. Billmeyer, A text book of polymer Science

2. V.R. Gowariker, Polymer Science3. Fread, W, A text book of polymer Science.

4. William, A text Book of Polymer Science and Technology.5.D.H.Morton-Jones PolymerPprocessing

6.Tamdor Gogos Principles of Polymer Processing

CEP 314 INSTRUMENTAL ANALYSES


Infrared spectroscopy: Introduction, Principle of IR spectroscopy, basic theory and vibrational energy of a

diatomic molecule, rotational structure in vibrational bands, instrumentation, interpretation and applications ofIR spectroscopy. Nuclear magnetic resonance (NMR) spectroscopy: introduction basic theory of NMR

spectroscopy, instrumentation, information from NMR spectra, chemical shift, spin coupling Elucidation ofstructure, structure elucidation. Mass spectroscopy: introduction, principle, instrumentation, interpretation;

introduction, principle instrumentation, interpretation and application of mass spectroscopy. Combinedmethods (NMR. MS, IR) for structure elucidation. Atomic Absorption Spectrometry (AAS): Absorption of

characteristic radiation, instrumentation, sample vaporization, quantitative measurements atomic fluorescencespectrometry, applications of AAS; ICP; Flame less AAS (Graphite furnace) interfaces. Sampling and

sampling pretreatment; Examples of analytical problems and procedures, The automation of analyticalprocedures. Chromatographic Techniques: PC, TLC, GLC, HPLC, SFC.

References:

1. B. Christan Analytical chemistry.2. Balen and Ewing Instrumental Methods of Chemical Analysis.

3. D.A. Skoog and West Fundamentals of Analytical Chemistry.4. Stock and Rice Chromatographic methods

5. William Flemming Spectroscopic Methods in Organic chemistry.

6. Y.R. Sharma Elementary organic spectroscopy.7. Pavia, D Spectroscopic Method.

CEP 315 FUEL AND ENERGY


Sources and reserve of fossil and nuclear fuel, renewable energy source. Origin and composition of fossilfuel, petroleum, natural gas, oil shales and tar sands, principal classes of organic compounds present in liquidfuels. conversion of petrochemicals. Properties and test methods for fuel classification, proximate and

ultimate analysis of solid fuel, Boiling point ranges, densities and Flash point ,Aniline points of liquid fuels.

Octane and cetane number of petrol and diesel. Determination of gross and net caloric values for solid, liquidand gaseous fuels. Carbonization of coals and heavy petroleum. High Tem. and Low Tem. Carbonization

,coke and pitch as feed for carbon. Steam gasification, conversion of synthesis gas, methane, water gas, alcoholand higher hydrocarbons. Combustion of solids in grates, pulverized fuel burners and fluidized beds Calculation

of Air/Fuel ratio, Excess Air . Fuel cells. Power generation efficiency, overall energy balance, advantage ofcombined cycles. Nuclear Fuel:Nuclear fission, Uraniumisotopes, characteristics of nuclear reactors. Nuclear

fusion,Light water nuclear power plant Hydroelectric,wind and solar power.

References:

1. Nelson Farrer Petrolium Refining Engineering

2. Francis Fuel and Fuel Technology3. L.D Smoot P.J Smith. Coal Combustion and Gasification

4. Goldstein Petroleum Chemical Industry.5. Huntinglon Natural Gas and Natural Gasoline

CEP 316 CHEMICAL PROCESS PRINCIPLES SESSIONAL4 Hours/ Week, 2.0 Credits


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Laboratory classes based on Chemical Kinetics and Spectrophotometric and Instrumental Analysis.

CEP 317 POLYMER CHEMISTRY SESSIONAL

4Hours/Week, 2.0 Credits.

Laboratory classes based on polymer Chemistry theory courses.

CEP 318* CHEMICAL REACTION ENGINEERING3 Hours/Week, 3 Credits

Basic concepts of reactor design: mole balance, basic kinetics, reaction types, conversion, reactor sizing, anddesign equation for batch system and flow system. Isothermal Reactor Design : design structure ,tubular

reactors, pressure drop in reactors. Interpretation of Reactor Data: batch reactor data, differential and integralmethods, method of initial rates, method of half lives, least square analysis, differential reactors, evaluation of

laboratory reactors. Catalytic Reactors: catalysts and steps in a catalytic reactions, heterogeneous reaction data

analysis for reactor design, catalyst deactivation, moving bed reactors, diffusion and reaction porous catalysts.

Distribution of Residence Time (DRT) for Chemical Reactors: general characteristic, measurement of DRT,

DRT in ideal reactor, reactor modeling with DRT, zero parameter models. Bioreactors: cell growth, rate law,

design equations and unit reactor design.

References:

1. Coulson & Richardson Chemical Engineering. Vol-32. Octave Levenspiel Chemical Reaction Engineering.3. H.Scott Fogler Elements of Chemical Reaction Engineering.

4. J.M. Smith Chemical Engineering Kinetics

CEP 319 SCIENCE AND ENGINEERING OF MATERIALS


Introduction to materials Science and Engineering : materials and engineering ,types of materials; Crystal

structure and Crystal geometry: the space lattice and unit cells, crystal systems and bravais lattices , principal

metallic crystal structures ,atom positions in cubic unit cells, directions in cubic unit cells, miller indices forcrystallographic planes, crystallographic planes and directions in hexagonal unit cells, comparison of FCC,

HCP, and BCC crystal structures , volume ,planar and linear density unit cell. Solidification, crystallineimperfections and diffusion in solids: solidification of metals, solidification of single crystals, metallic solid

solutions, crystalline imperfections, rate processes in solids, atomic diffusion in solids, and industrialapplications of diffusion processes. Mechanical Properties of metals: recovery and recrystallization ofplastically deformed metals, fracture of metals, fatigue of metals, fatigue crack propagation rate, creep and stress

rupture of metals , graphical representation of creep- and stress -rupture time -temperature data using the

Larsen-Miller Parameter. Ceramic Materials: introduction, simple ceramic crystal structures, silicate structures, processing of ceramics, traditional and technical ceramics, electrical properties of ceramics mechanical

properties of ceramics, thermal properties of ceramics, glasses. Metals and Ores: Occurrence and orepreparation. Production of Steel and Wrought Iron: Cement steel and crucible steel, alloying addition and

steel ingots, influence of minor elements in carbon steel and high alloy steel. General principle of phasediagram of alloys and solid solution: study of binary alloys, Iron-Iron constitutional diagram

References:

1. Askeland. D. The Science & Engineering of Materials.2. L.H.Van Black Elements of Material Science and Engineering.3. William Introduction to Science & Engineering of Materials.

4. Melvin Nord Science of Engineering Materials.5. William F. Smith Foundations of Materials Science and Engineering

CEP 321 ELECTROCHEMICAL ENGNEERING

2 Hours/week, 2 credit

Introduction: Nernst equation. Standard electrode potentials; reference electrode, primary and secondary,

Measurement of thermodynamic parameters, equilibrium constants, DG, DH, DS, solubility products,susceptibility to corrosion. Principles Of Electrochemical Engineering; General consideration, principle of cell

design Electrolysis and electrodialysis-principles, processes and equipments. The chloro-alkali industry;

General concepts of brine electrolysis, modern technological developments, chlorine cell technologies, production of KOH, equipments. The extraction, refining and production of metal Electrowining,


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cementation, electrorefining, electrodeposition of metal powders. Metal finishing: electroplating, electroplating,conversion, coatings, electrophoretic painting, other related surface finishing techniques. Anodization of

Aluminium: Pretreatment, oxide film formation, electro coloring, post treatments. Water purification, effluenttreatment and recycling of industrial process streams, Metal ion removal of metal recovery, hypochloride and

low chloric electrohyper electrodialysis, electrolytic methods of phase separation flue gas desulpherisation.other electrochemical processes. Batteries: Characteristics, specifications, battery components, present battery

systems.

References:

1. C. L. Mantell Electrochemical Engineering.

2. Pletcher and Walsh Industrial Electrochemistry.

CEP 322*MASS TRANSFER - II

3 Hours/Week, 3 Credit

Adsorption: Introduction to adsorption processes, Equilibrium relations for adsorbents Absorption at gas solid

interface. Physical adsorption and chemisorption Langmuir and BET theory and surface area determination,

Adsorption from solution Gibbs adsorption isotherm. Design of fixed bed adsorption. Processing variables andadsorption cycle. Ion Exchange: Ion exchange resins, Exchange kinetics, Ion exchange equipments. Filtration:

Introduction to filtration. Basic theory of filtration Types of filtration equipment.. Engineering operation and

calculation of different types of filters. Membrane Separation Processes: classification of membrane processes.Liquid permeation membrane processes. Gas permeation membrane processes: Types of membrane. Types ofequipments. Basic equations. Effects of process variables. Reverse-osmosis: Types of membranes. Flux

equations for reverse-osmosis. Ultrafiltration membrane Processes: Types of equipments. Effect of processingin ultra-filtration Drying: Theory of drying of solids. Types of Drying equipment.. Engineering operation and

calculation of different types of Dryer.

References:

1. Geankoplis C.J. Transport Process and Unit Operation

2. Mc Cabe and Smith, Unit Operation of Chemical Engineering3. Binoy K. Dutta Principles of Mass Transfer and Separation Processes

4. Coulson and Rechardson Chemical Engineering Vol-25. Trybal Mass Transfer Operations

CEP 323 PROCESS EQUIPMENT DESIGN SESSIONAL6 Hours/Week, 3.0 CreditsBased onHeat Transfer Equipment, Mass Transfer Equipment, Reactors, Fluid Flow Equipment

References:

1. J.M. Coulson, J.F. Rechardson and R.K. Sinnott, "Chemical Engineering Vol. 6 - Design", Pergamon, 1983.

CEP 325 FUELS AND ENERGY SESSIONAL

4 Hours/Week, 2.0 CreditsLaboratory Classes Based On Fuel and Energy Theory Course.

CEP 326 POLYMER CHARACTERIZATIONS SESSIONAL

4 Hours/Week, 2.0 Credits

Laboratory Classes Based On Polymer Properties and Processing Technology Courses.

CEP- 327 MASS TRANSFER SESSIONAL

6 Hours/ Week, 3.0 creditsLaboratory classes based on Unit Operations of Chemical Engineering

CEP-328 FIELD WORK/IN-PLANT TRAINING-I

2.0 CreditIndustrial Visits.

CEP- 329 ORAL

1.0 Credit


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CEP 401 ELEMENTS OF CHEMICAL ENGINEERING AND TECHNIQUES OF ENVIRONMENTAL

ANALYSES (for CEE)

2 Hours/Week ,2 CreditsMechanical separation; gravity settlers, impingement separators; centrifugal separators and scrubbers. Crushing

and grinding : solid handling machinery, Fluid moving machinery, ejectors and vacuum systems, pressurerelieving devices, Mixing and agitation, Crystallization, drying and evaporation. Scope of chemical engineering,

Principles of chemical engineering calculations, system of units, basic concepts of dimensional analysis, processvariables, basis of calculation, conversion of mass and energy material balance, overall component balance,

recycle and bypass, simple reactive systems and combustion reactions, Energy balance, forms of energy andfirst law of thermodynamics, thermodynamics data and tables, energy balances on open closed systems.

Application of mass and energy balance to real process, Measurement of process variables; fluid static's andmanometer, temperature measurement and flow measurement.

1. Introduction to instrumental analysis; introduction to analytical spectrometry; absorption laws; spectral

interfaces,2. UV-VIS spectroscopy; introduction, electronic transitions, instrumentation, qualitative and quantitative

analysis.

3. Atomic spectroscopy : (a) Frame emission spectroscopy. (b) Atomic absorption spectroscopy. (c) Inductivelycoupled plasma emission spectroscopy.

4. X- ray spectroscopy: Introduction, general theory and instrumentation. X-ray absorption and emission

methods. X-ray diffraction methods; X-ray flume scheme.5. Neutron activation analysis: Anionic stripping voltametry.6. Chromatography : Principles and classification of chromatographic techniques; paper chromatography TLC;

column chromatography; Gas chromatography, high performance liquid chromatography.

References:

1.Geankopolise Unit Operation2.Mc Cabe and Smith Unit Operation of Chemical Engineering

3. Faoust, A. S. Principles of Unit Operations.4. Coulson and Rechardson Chemical Engineering

5. B. Christian Analytical chemistry.

CEP 411 CORROSION ENGINEERING


Corrosion : general, electrochemical corrosion of metals , galvanic cells, corrosion rates (kinetics), types ofcorrosion with properties and phenomenon, oxidation metals. Corrosion Testing: importance, classification

materials and specimens , surface preparation , measuring and weighing, exposure techniques, duration, plannedinterval tests. Corrosion Prevention : Material selection, modification of metal, alternate of environment,

design , cathodic and anodic protection, coatings (metallic ,inorganic ,non metallic and organic). Corrosion inIndustries : Boiler plant, Double pipe heat exchangers, Shell and tub heat exchangers, Distillation Column

References:

1. C. L. Mantell Electrochemical Engineering.

2. Pletcher and Walsh Industrial Electrochemistry.3. Fontana. G. Corrosion Engineering4. Uligue , Introduction to Corrosion Engineering and its prevention

5. Banergy S. N. Corrosion Engineering

CEP 412* PROCESS CONTROL


Laplace Transforms, transfer, functions for first order systems, physical examples of first order systems,response of first order systems in series, higher order systems, transportation lag. closed loop systems,

controllers and final control/ elements, block diagrams, closed loop transfer functions, transient response of

simple control systems, concepts of stability, stability craters, Routh test for stability.

Frequency response methods, control systems design by frequency response, closed loop frequency by

frequency response methods, Nyquist stability criterion. Controller mechanism, measuring instruments,

transducers and transmitters. Control of complex processes, experimental dynamics of complex processes.theoretical analysis of complex processes.


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References:

1. Hougen and Watson Chemical Process Principles I & II2. Levenspiel Chemical reaction engineering.

3. George Stephanopolos Chemical process control4. Donald R.Coughanowr Process System Analysis and Control

CEP 414*PROCESS DESIGN


Introduction to process design: Scope, flow sheet, materials and energy balance. Piping andinstrumentation: P&I diagram, valve selection, pumping of liquids, pipe size selection. Control and

instrumentation: instrumentation and control objectives, typical control systems. Separation System design:Distillation column sequencing for liquid mixtures Heat Exchanger Network design: Pinch Technology.

Materials of construction: properties and selection of materials. Equipments selection and Specification andDesign: Heat exchanger, separation process. Process safety and pressure reliving devices: Fire, explosion,

toxic release, types of pressure reliving devices and calculation.

References:

1. Peters and Timerhaus Plant Design and Economics for Chemical Engineers.2. Douglas Conceptual Design of Chemical Process3. Ludwig E. Applied process design for chemical and petrochemical

4 Coulson & Richardson Chemical Engineering. Vol-65. Chopey N.P. Handbook of Chemical Engg. Calculation

CEP 415 INDUSTRIAL ECONOMICS AND MANAGEMENT

3hours/Week, 3 Credits

Interest and Investment cost: Simple interest, compound interest, continuous interest, applications of different

types of interest, present worth & discount, Annuity, relation annuity and periodic payment, perpetuities andcapitalized costs. Cost estimation: Economic feasibility of project, capital investments, estimation of capital

investment, cost indices, power factor, cost factors in capital investment, turn-over ratio, Types of taxes,insurances and insurance requirements for manufacturing concern. Depreciation: Types and methods of

determining depreciation, depletion, evaluation of depreciation methods. Profitability analysis: GDP, GNP,Rate of return, payback period, pay out period, discounted cash flow, net present worth, Alternativeinvestments, replacements. Management: Management functions, Principles of management, Production

management: Concept, scope and functions of production management, Production planning and control,

continuous and intermittent products, Functions & scope of quality control, responsibilities of quality,Inspection, Zero defects. Marketing management: Concept, evolution, functions & importance of marketing,

marketing mix. Financial management: Evolution, objectives & functions of financial management, financialanalysis & control, Break-even analysis and profit planning, capital budgeting. Motivation: Needs, theories of

motivation (Maslows, Herzbergs McGregors theories) Optimizing techniques: Linear programming(Simplex and graphical methods)

References:

1. Peters and Timerhaus Plant Design and Economics for Chemical Engineers.

2. Aurora Industrial and Production management.

CEP 417 CHEMICAL REACTION ENGINEERING SESSIONAL

4Hours/Week, 2.0Credits

Laboratory classes based on Chemical Reaction Engineering Courses

CEP 418 PLANT DESIGN

6 Hours/Week, 3.0 Credits

Students should design a chemical plant (Includes all type of equipments ) independently based on the course

no. CEP 414.

CEP 419 INPLANT TRAINING-II/FIELDS WORK

2.0 CreditsIndustrial visits and training.


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CEP 420 TRANSPORT PHENOMENA

2 Hours/Week, 2 CreditsViscosity and the Mechanism of Momentum Transport:Newtons Law of Viscosity, Non-Newtonian Fluids,

Pressure and Temperature Dependence of Viscosity, Theory of Viscosity of Gases at low Density, Theory ofViscosity of liquids. Velocity Distributions in laminar flow: Shell Momentum Balances: Boundary Condition,

Flow of a Falling Fill, Flow through a Circular Tube, Flow through an Annulus ,Adjacent Flow of TwoImmiscible Flow , Creeping Flow Around a Solid Sphere, The Equations of Change for Isothermal Systems:The Equation of Continuity, The Equation of Motion, The Equation of Mechanical Energy, The Equation ofChange in Curvilinear Coordinates, Use of the equations of change to set Up Steady flow Problems, The

equations of change for Incompressible Non-Newtonian Flow, Dimensional Analysis of the Equations ofChange.

References:

1. Bird. R .B. Transport Phenomena, Wiley Inter Science Singapore

CEP 421 ENVIRONMENTAL ENGINEERING


Environmental Chemistry: Stoichiometry, Enthalpy in Chemical Systems, Chemical Equilibria. Mathematics

of Growth: Exponential growth, Resource consumption, Population growth, Human population growth. Airpollution: Definition, sources of air pollution, major air pollutants and their effects, impacts of air pollution,depletion of the ozone layer and its implications, ozone depleting substances (ODS) and their substitutes,

Recovery and reuses of ODS, Destruction technologies for ODS, the Montreal Protocol and its amendments,ozone layer depletion threat to ecosystem, green house effect. Water pollution: water resources. the hydrologic

cycle, water pollutants, Biochemical Oxygen Demand, Water quality management in Lakes and Reservoirs.Water Treatment: Introduction, Coagulation, Softening, Reactors, Mixing and Flocculation, Sedimentation,

Filtration, Disinfection, Adsorption. Wastewater Treatment: Wastewater Microbiology, Characteristics ofwastewater, On-site Disposal Systems, Unit operations of pretreatment, Primary treatment, Unit processes of

secondary treatment, Disinfection, Advanced wastewater treatment, Land treatment, Sludge treatment, Sludgedisposal. Wastewater Treatment by Membrane Technology. Solid Waste Management: Perspective,

collection, interroute transfer, disposal by sanitary landfill, waste to energy, resource conservation and recovery.

Environmental problems in Bangladesh

References:1. Gilbert M. Masters Introduction to Environmental Engg. & Science

2. Gerard Kiely Environmental Engineering

3. Davis & Cornwell Introduction to Environmental Engineering

4. Peavy, Rowe & Tchobanoglous Environmental Engineering

5. W. Strauss, Air pollution.

6. A.S.Stoker, Air and Water pollution7. Bailey and Clark, Chemistry of the Environment.

8. J.N. Duffus, Environmental Toxicology.

CEP 422 NATURAL GAS AND PETROLEUM RESERVOIR ENGINEERING.


Natural Gas Technology and Earth Sciences: Branches of Petroleum Industry. Sources of Information for

natural gas engineering and its applications. Petroleum reservoirs, Earth temperatures & pressure Properties of

rocks: Types of rocks. Porosity, Permeability: Measurement of permeability. Drilling and completion of wells:Types of Well, Drilling, Drilling Fluid, Directional Drilling, Processing in drilling, Stimulation of well

productivity, Gas fracturing, Acidizing operations, Well logging. Flow in Reservoir & Adjacent Aquifer:Pressure drop from reservoir to wellbore -A simplified steady state approach. Basic fluid flow equations-

General flow equation in dimensionless forms, Boundary conditions. Partial penetrated wells, Superpositionprinciple. Gas Well Testing: Deliverability tests- Back pressure test, Isochronal test, Test for determining

reservoir parameters-drawdown test, Oil & gas reserves- volumetric method. Gas Hydrates & TheirPrevention: Natural gas hydrates, Conditions promoting hydrate formation, Use of methanol to prevent

hydrates, Importance of dehydration of natural gas. Natural Gas Processing: Objectives, Types of plants, Basic

processes, Process description, Byproducts, Condensate, NGL. Gas for the Fuel Market: Pipe line quality gas,CNG, LNG, LPG.

References:

Katz D. L. et al. Natural Gas Engineering (production & storage), McGraw-Hill, Singapore


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CEP 429** THESIS

3.0 credits

CEP 431**Project

3.0 Credits

CEP 430 ORAL

1.0 Credit

ELECTIVES

(Courses would be offered as per availability of respective teachers)

ELECTIVE-I

CEP 423 POLYMERS IN APPLICATION


Commercial polymers: Polymerization techniques, properties, and application of polyethylene, polypropylene,

polyvinyl chloride, polystyrene, polyamide, polyesters, UF-resin, MF-resin, PF-resin, polyurethanes, epoxyresin, polycarbonates, silicon polymer. Natural rubbers: properties of rubber, latex, preservation of latex, rubberplants, and rubber vulcanization. Synthetic rubbers: Buna S, Buna N, Neoprene rubber, Thiokol, Butyl rubber,

urethane rubber. Polymer blends: Definition and classification of polymer blends, thermodynamics of polymerblends, spinodal and bimodal curve, application of polymer blends. Polymer Composites: Introduction, fiber

reinforced composite, predicting properties of fiber reinforced composite, characteristics of fiber reinforcedcomposite, mfg. of fiber and composite Glass fiber reinforced plastics. Polymer alloys

CEP 441 INDUSTRIAL HAZARDS AND SAFETY MANAGEMENT2 Hours/Week, 2 Credits

Hazards in Chemical Industries- Introduction to risk management, Principle and issues in risk analysis, Acts

and regulation. Hazard Management-Quantitative risk assessment, Hazard identification, Hazard and

operability studies. Hazard Analysis-Event tree and fault tree analysis, frequency analysis, consequenceanalysis.

Safety Management: Evaluation of modern safety concepts. Industrial hazard, safety and risk management,industrial injuries, Types of injuries and accidents occurred in industries, health rules, workers safety, accident

investigation, protective management techniques for safety management, safety devices, safety standards andregulations for engineering works.

CEP 436 POLYMER COMPOSITES

2 Hours/Week, 2 CreditsIntroduction: Fundamental Characteristics of composites; classification of composites; laminae and laminates;load sharing between reinforcement and matrix- rule of mixture; advantages, design and application ofcomposites. Reinforcements: Basic characteristics of fibers and fibrous reinforcements, fiber packing, fiber

strength, fiber orientation and length distribution, different types of fibers for composites, modification of fibersfor composite, design of fabrics for reinforcement of composite, particulate reinforcement. Matrices: Main

polymer matrices-thermoplastic and thermosetting polymers, High temperature polymeric matrices, metalmatrix composites (MMC), ceramic matrix composites (CMC) Elastic and Thermal Properties of Composites:Stress-strain relationship and elastic constants for unidirectional lamina(UD) , planar random fibercomposites(PRFC) and short fiber composites; Classical Laminate theory(CLT), selected laminate

configurations, interlaminar stress and edge effect, thermal behavior of composite. Interface Region:

Complexity in the near fiber region, bonding mechanisms- adsorption and wetting, interduffusion, chemicalreaction, electrostatic attraction and mechanical keying; experimental measurements of interfacial strength,

coatings of fiber, coupling agents. Polymer Nano-composites: Carbon nanotube composite, structure,

properties, purification, characterization and functionalisation of carbon nanotubes, interaction of carbonnanotubes with polymer matrix; layered silicate nanocomposites- structure, manufacture and application.


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CEP437 POLYMER KINETIC THEORY

2 Hours/Week, 2 CreditsFlow Phenomena in Polymeric Liquids.

The chemical nature of polymeric liquids; Non-Newtonian viscosity, Normal stress. effects, other elastic effects;Material functions for Polymeric liquids, shear and shear free flows. Basic Concepts from Probability

Theory; Events and probabilities; Random variables; Expectations and moments; Joint distributions andindependence; Gaussian random variables; General discussion of the random walk ; Fokker- Planck equations

References :

1. R.B. Bird, C.F. Curtiss, R.C. Armstrong and O. Hassager, Dynamics of polymeric liquids, Volume 2: Kinetic theory, 2ndEd., John Wiley

ELECTIVE-II

CEP 424 FUNDAMENTALS OF TEXTILE ENGINEERING


Study of textile fibres: classification, production, structure and properties of the main textile fibres-natural andman-made. Short overview of spinning, weaving and knitting technologies. Yarn numbering systems. Basic

characteristics of yarns, woven and knitted fabrics. Pre-treatment processes of textile materials. Classification ofthe dyestuff and its relation with the textile fibres. Study of the main properties of fasteness and its relation with

dyestuff and used fibres. Study of the direct, vat, reactive, sulphureous, dispersed, acid and cationic dyestuff.Study of the dyeing processes of celullosic, polyester, polyamide, acrylic, wool fibres and the mixtures of

polyester with celollusic.

References:

Peters, R.H. Textile Chemistry

CEP 425 BIOCHEMICAL ENGINEERING2 Hours/Week, 2 Credits

Introduction to Biochemical Engineering: Concepts of catalysts, nature of micro-organisms, their requirements

and classification, industrially important, micro-organisms. Principles of biochemical reaction kinetics; Massand energy balance in biological system, Transport phenomena, Enzymes and Enzymatic reaction kinetics; Free

and immobilized enzyme cell systems; Microbial growth and product formation kinetics, classification ofbioreactors, upstream processing - media and air sterilization, Downstream bioprocessing; Physical separation

processes, Chromatography, membrane processes. Biological Industries and their Engineering Problems :

stoichiometry of reactions and heat evolution. Oxygen in the cell and medium formation. Down-Streamprocessing. separation of cells and recovery of useful end products.

References:

1. H.W. Blanch and D.S. Clark Biochemical Engineering, Marcel Dekker, Inc., New York, 1996.

2. J.M.Smith Chemical Engineering. Kinetics3. J.E. Bailey & D.F. Ollis Biochemical Engineering Fundamentals

4. S.N. Mukhopadhyay Process Biotechnology Fundamentals5. Octave Levenspiel Chemical Reaction Engineering

CEP426 MATHEMATICAL MODELING IN CHEMICAL ENGINEERING PROCESSES

2 Hours/Week, 2CreditsIntroduction., classification of mathematical models, summary of model building processes, fundamental laws,

fitting function to empirical data, factorial experimental designs & regression analysis, optimization methods,solution techniques for models, application to the problems: mass transfer, heat transfer, chemical reactor

design, mathematical modeling for steady & unsteady state of chemical processes.

References:

1. T.F, Edgar, D.M. Himmelblau Optimization of Chemical Processes.2. J. Miller Statistics for Advanced Models.


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3.D.D.Joshi , Linear Estimation & Design Of Experiments.4.R,B.Bird, W.E, Stewart Transport Phenomena.

5.G. Stephanopolas Chemical Process Control.6.Luyben W. L. Process Modeling, Simulation & Control For Chemical Engineers

CEP 432 PETROLEUM REFINING PROCESSES

2 Hours/Week, 2 CreditsOrigin Formation and Composition of Petroleum: origin and formation of petroleum ,reserves and deposits of

world ,composition of petroleum. Petroleum Processing Data: evaluation of petroleum ,thermal properties ofpetroleum, fractions , important product properties and test methods. Fractionation of Petroleum :dehydration

and desalting of crudes ,heating of crude-pipe still heaters, distillation of petroleum, blending of gasoline.

Treatment Techniques: fraction-impurities ,treatment of gasoline, treatment of kerosene, treatment of lubes,

wax and purification. Thermal and Catalytical Process: cracking, catalytic cracking, catalytic reforming,

naphtha cracking, cooking, hydrogen processes, alkylation processes isomerisation processes polymer gasolines.

Asphalt Technology :source of asphalt , air blowing of bitumen, upgradation of heavy crudes.

References:

1. B.K. Bhaskara Rao Modern Petroleum Refining Process.

2. G.N. Sarkar. Petroleum Refining

CEP435 RENEWABLE ENERGY


Potential for renewable energy sources, energy conservation, Solar Energy - thermal and photoelectrical - Oceanthermal energy sources - Geothermal energy utilization - Wind energy - Bio-gas principles, reactors.

Hydrogen source of energy, Solar and Chemical production of hydrogen, Metal Hydrides, Microhydelsystems, Hybrid systems, Heat pump applications in process engineering.

References:

1. J. Twidell and T. Weir Renewable energy sources, Cambridge University Press, 1986.2. S.P. Sukhatme Solar energy, 2nd Ed., Tata McGraw Hill, 1996.

3. T. Ohta Solar - hydrogen energy system, Pergamon Press, 1979.

CEP 438 CONTEMPORARY INDUSTRIAL PROCESS IN BANGLADESH2 Hours/Week, 2 Credits

CEP 440 PRINCIPLES OF CATALYSIS


Catalysis in Solutions: Introduction, acid-base, catalysis in the gas phase, catalysis in dilute aqueous solutiongeneral and specific acid and base catalysis, catalysis in concentrated strong acid solutions, catalysis by bases,

stepwise and concerted reactions, catalysis by metal ions, hydrocarbon conversion. Catalysis by Polymers: thenature of polymers, attachment of catalytic groups to polymer supports, catalysis in polymer gels, adsorption

and the kinetics of polymer-catalyzed reactions, interactions of catalytic groups, the role of the support, bifunctional and multifunctional catalysis. Catalysis on Surfaces: Introduction, adsorption, adsorption

isotherms, structure of adsorbed species on single crystal metal surfaces, adsorption on complex surfaces,

functionalied surfaces, olefin polymerization catalysis on titanium trichloride surfaces, catalysis on metalsurfaces, catalysis on metal oxide surfaces, catalysis by supported metals, catalysis by metal sulphides

SOC***INDUSTRIAL SOCIOLOGYTheory: 3 Hours/Week, 3 Credits

Introduction: Scope and rise of Industrial Sociology, History of Industrialization, ancient and modern, early

industrialization in India, arts and crafts, Renaissance, Industrial revolution in Europe, the development ofindustry and industrial Sociology in Bangladesh. The Concept of work: work and arts, nature of industrial

work, work ideology, work values, Role o work in human life, work and mental health, work attitudes, work

involvement, the motivation of work, work satisfaction, commitment to industrial work, development andcommitment of industrial labor force in Bangladesh. The Workers and the Factory: The factory system, its

characteristic, the formal relation of production in factory system. The Industrial Bureaucracy: The executive

in the industrial bureaucracy, the role of worker, the social relations at work, Management as social elite.Industry and the community: Industry and family, Industry and social change, shifting values, influence of


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convections, religion and industrial development, place of industrial worker in society, industry and socialsatisfaction. Industrial conflicts: Nature and causes of industrial conflict, role and function of trade unionism,

resolution of industrial conflict, collective bargaining. Industrialization and development: pattern of industrialdevelopment in developing countries, role of foreign capital and borrowed technology, technology and social

structure, Classification of industries, role of cottage industries, labor intensive vs. heavy industries,modernization

bsc syllabus 2009

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