Detailed Courses | Department of Chemical & Process Engineering

Course Details

Detailed Description of the Course Units for the stream of Chemical and Process Engineering, with the respective methods of assessment, offered by the Department of Chemical & Process Engineering

CP201 Chemical Engineering Fundamentals (3 credits) Pre-requisites: none
The aim of this course is to provide basic and fundamental knowledge on Chemical and Process Engineering concepts and will enable students to understand how Chemical Engineers contribute to research, design, development and operation of chemical processes involving reactions, heat transfer, and mass transfer (separations) to produce useful and valuable products. Mainly students are trained to apply heat and mass balances for different types of process units, produce relevant engineering drawings.
Aim / Objectives To provide basic and fundamental knowledge on Chemical and Process Engineering concepts. Intended Learning Outcomes Upon successful completion of this course, students should be able to, Explain unit operations of chemical engineering. Draw relevant engineering diagrammes to present process information Perform material and energy balances over common unit operations and processes Apply engineering tools to solve simple process engineering problems Derive and apply thermodynamics concepts such as free energy and chemical equilibria to solve simple problems
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Concept of unit operations. Use of flow charts. Flow-chart representations of industrial processes.	02
Chemical thermodynamics. Prediction of physical properties of substances and mixtures. Phychrometry and its applications.	11	03		04
Mathematical modelling of steady-state and transient-state processes using mass and energy balances. Mass and energy balances over chemical engineering processes such as drying, humidification, distillation, evaporation, cooling towers and chemical reactors.	11	03		10
Flow-charting of industrial processes using computer software. Flow-sheeting of a selected industrial process with complete mass and energy balances.			12
Laboratory exercises on mass & energy balances carried over pilot-plant units.			04
TOTAL	24	06	08 eq. hours	07 eq. hours

Assessment	Percentage Marks
Continuous Assessments Assignments Flow sheeting Laboratory work	25	05 10 10
Mid-semester Examination	25	–
End-semester Examination	50	–

Recommended Literature

1. R. K. Sinnott, Coulson and Richardson’s Chemical Engineering Design, vol. 6, 3 rd ed. Oxford: Butterworth-Heinemann, 1999.

2. C. M. Narayanan and B. C. Bhattacharya, Unit Operations and Unit Processes including Computer Programs, vol. 1. India: CBS Publishers & amp; Distributors, 2006.

CP202 Separation Process Principles (3 credits) Pre-requisites: none
Separation Process Principles is a subject that aims at empowering the learner with the fundamentals of separation processes in Chemical Engineering. This module covers design aspects of separation process equipment such as distillation, absorption, stripping, extraction, leaching and adsorption. It also provide the learner the knowledge and skills to apply heat and mass transfer in gas-liquid contacting and solids drying for real problems and transfer the mathematical concepts of continuous contacting equipment for designing basic configurations of such units.
Intended Learning Outcomes Upon successful completion of this course, students should be able to, Demonstrate knowledge of equilibrium between phases, equilibrium stage concept, cascade of stages, stage efficiency Identify applications in the separation of components by binary distillation, absorption, stripping, extraction and leaching Demonstrate knowledge to apply theory on mass transfer: diffusion, theory of interface mass transfer, mass transfer coefficients, overall coefficients and transfer units for solving engineering problems Demonstrate skills to apply theory behind absorption, extraction and adsorption, simultaneous heat and mass transfer in gas-liquid contacting and solids drying for real problems. Transfer the mathematical concepts of continuous contacting equipment for designing basic configurations of such units Demonstrate laboratory exercises on pilot-plant units and identify how such experiments can be used to design scaled up units for real life applications
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Equilibrium between phases. Equilibrium stage concept, cascades of stages, stage efficiency, and applications in the separation of components by binary distillation, absorption, stripping, extraction and leaching.	12	03	–	08
Mass transfer: Diffusion. Theory of interface mass transfer. Mass transfer coefficients, overall coefficients, and transfer units. Application in absorption, extraction and adsorption. Simultaneous heat and mass transfer in gas-liquid contacting, and solids drying. Concept of continuous contacting equipment.	12	03	–	10
Laboratory exercises carried out with pilot-plant units.	–	–	12	–
Total	24	06	06 eq.hours	09 eq.hours

Assesment	Percentage Marks
Continuous Assessments Assignments Laboratory work	25	10 15
Mid-semester Examination	25	–
End-semester Examination	50	–

Recommended Literature

1. R. K. Sinnott, Coulson and Richardson’s Chemical Engineering Design, vol. 6, 3 rd ed. Oxford: Butterworth-Heinemann, 1999.

2. S.K. Ghosal, S.K. Sanyal and S. Datta, Introduction to Chemical Engineering. New Delhi: Tata McGraw-Hill Publishing Company Limited, 2006.

CP303 Reaction Engineering (3 credits) Pre-requisites: none
Intended Learning Outcomes Upon successful completion of this course, students should be able to, Determine the parameters in kinetic expressions for different types of reactions (eg. Elementary and non- elementary, reversible, irreversible, series and parallel) Formulate and apply the design equations for the three ideal reactor models (batch, CSTR, and plug flow) in the presence of both single and multiple reactions and analyse single and series reactor systems in terms of space time and volume requirements Determine required heating and cooling loads by applying energy balance to the ideal batch, CSTR (and plug flow) reactors and in the presence of both single and multiple reactions Formulate and apply the design equations and rate laws for catalytic reactors Conduct experiments to generate data, analyse data and obtain information required for the design and scale-up of chemical reactors and simulation of different reactor systems using modern engineering tools
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Kinetics of chemical and biochemical reactions. Kinetics of reversible, series and parallel reactions. Temperature dependence of rate constant.	05	01	–	02
Design of batch, semi-batch, continuous stirred tank and plug flow reactors with isothermal and non-isothermal operations. Reactor networks. Multiple reactions in reactor networks. Design of bioreactors.	14	03	–	08
Design of reactors for catalyst induced reactions, and multiphase reactions.	05	02	–	08
Computer simulation of reactors and reactor systems.	–	–	06	–
Laboratory experiments for basic kinetic data, determination of rate expressions, and scale-up.	–	–	06	–
Total	24	06	06 eq.hours	09 eq.hours

Assesment	Percentage Marks
Continuous Assessments Assignments Computer Simulation Laboratory work	25	05 10 10
Mid-semester Examination	25	–
End-semester Examination	50	–

Recommended Literature

1.G.F. Froment, K.B. Bischoff and J. De Wilde, Chemical Reactor Analysis and Design, 3rd ed. United Kingdom: Wiley, John & Sons, 2010.

2. M.E. Davis and R.J.J. Davis, Fundamentals of Chemical Reaction Engineering, United States: McGraw-Hill Science/Engineering/Maths, 2003.

3. R.W. Missen, C.Mims and B.A. Saville, Introduction to Chemical Kinetics and Chemical Reaction Engineering. New York: John Wiley and Sons (WIE), 1999.

4. O. Levenspiel, Chemical Reaction Engineering, 3rd ed. New York: John Wiley and Sons (WIE), 1998.

5. J. F. Richardson and J. H. Harker, Coulson and Richardson’s Chemical Engineering Design, vol. 2, 5th ed. Oxford, Butterworth-Heinemann, 2002.

CP304 Process Equipment Design (3 credits) Pre-requisites: CH301, CH302
Process Equipment Design is a subject that aims at empowering the learner with the fundamental engineering skill set required in chemical engineering equipment design. This module covers design aspects of process equipment such as dryers, stripping columns, multi- component distillation columns, adsorption columns, extractors, crystallisers, cooling towers, mixers, settlers, plate, packed and spray columns with an in depth analysis of associated design procedures.
Intended Learning Outcomes Upon successful completion of this course, students should be able to, Apply fundamental chemical and Process Engineering theories to design various process units Estimate energy requirements and efficiency of process units Use computational packages to design process equipment
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Design of dryers, absorption and stripping columns, binary and multi-component distillation columns, adsorption columns, extractors, crystallisers, cooling towers, mixers, settlers, plate, packed and spray columns, and their operations. Energy requirements. Capacity and efficiency of contacting devices.	24	06	–	06
Computational approaches in design. Design of a multi-component distillation column using spreadsheet. Use of packages for design of process equipment.	–	–	24	–
Total	24	06	12 eq.hours	03 eq.hours

Assesment	Percentage Marks
Continuous Assessments Assignments Design	25	05 20
Mid-semester Examination	25	–
End-semester Examination	50	–

Recommended Literature

1.R. K. Sinnott, Coulson and Richardson’s Chemical Engineering Design, vol. 6, 3 rd ed. Oxford: Butterworth-Heinemann, 1999.

2. Harker, J.H, backhurst, J.R Richrdson J.F, Coulson and Richardson’s Chemical Engineering: Particle Technology and Separation Processes, 5th ed. Oxford: Butterworth-Heinemann, 2002.

3. Seader, J.D, Henley, E.J, Roper, D.K, Seperation Process Principals: Chemical and Biochemical Operations.

CP305 Energy Systems Design (3 credits) Pre-requisites: ME303
The course has been designed to give students the knowledge required to design selected heat transfer equipment and to estimate the heat load in a sample building for air conditioning purposes.
Intended Learning Outcomes Upon successful completion of this course, students should be able to, Design or formulate specifications of heat transfer equipment such as boilers, condensers, evaporators, furnaces Use psychometric charts to depict property changes during various processes involving air/water vapor systems and to do necessary calculations Calculate the heat load for a given air conditioning or refrigeration applications
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Boiling and condensation with industrial applications. Review of heat exchanger design and operations. Design of boilers, condensers, evaporators, burners and furnaces, and their operations.	16	04	15	–
Reviewing the use of psychometric charts. Theory of air-conditioning. Design of refrigerators and air-conditioners.	08	02	15	–
Total	24	06	15 eq.hours	–

Assesment	Percentage Marks
Continuous Assessments Design	25	25
Mid-semester Examination	25	–
End-semester Examination	50	–

Recommended Literature

1.J. F. Richardson and J. H. Harker, Coulson and Richardson’s Chemical Engineering Design, vol. 2, 5 th ed. Oxford, Butterworth-Heinemann, 2002.

2. R. K. Sinnott, Coulson and Richardson’s Chemical Engineering Design, vol. 6, 3 rd ed. Oxford, Butterworth-Heinemann, 1999.

3. J. F. Kreider, P. S. Curtiss and A. Rabl, Heating and Cooling of Buildings, 2 nd ed. McGraw Hill, 2002.

4. Sri Lanka Energy Audit Manual, Module 1-4 Jointly published by Sri Lanka Sustainable Energy Authority and Sri Lanka Energy Managers Association.

CP308 Process Engineering Project & Seminar (3 credits) Pre-requisites: none
Aim/Objectives/Intended learning outcomes Upon successful completion of this course, students should be able to, use appropriate mathematical and other tools and techniques / equipment / pertinent software / appropriate programming language to formulate and solve challenging problems arising in the chemical & process engineering and related fields self-acquire new knowledge and skills manage time effectively and use available resources efficiently search and extract information from different sources and apply participate in scientific and technical communications effectively with confidence
Course Description	Time allocated / hours
Course Description	L&T¹	A&P²
Problem identification and project formulation; search for, and retrieval of, information required such as literature survey; identification and optimum utilisation of available resources; project execution; cost analysis, socio-economic and ethical evaluations of the project, analysis of political and environmental consequences, and safety evaluations (when applicable); elements of technical report writing; communicating the results of the project study with the outside world via a report, a web-page, etc.	–	60
Seminars by industrialists and/or industrial visits by students or student groups in relation to the projects undertaken.	–	30
Total (equivalent hours)	–	45

Assessment	Percentage Marks
Stage 1: Project proposal, work-plan and the literature survey via presentation	20
Stage 2: Project progress via presentation	30
Stage 3: Project progress via presentation	20
Stage 4: Final project report / paper	30

CP406 Industrial Safety and Health (3 credits) Pre-requisites: none
Intended learning outcomes Upon successful completion of this course, students should be able to, Explain the need and the importance of paying due attention to safety in industry Describe Sri Lankan legislations pertaining to industrial safety Discuss the causes of industrial accidents Size relief and vent valves Discuss the different types of strategies and procedures adopted in industry to reduce and mitigation of risks Perform risk assessment on a given process using different risk identification and analysis tools Describe the components of safety management systems
Course Description	Time allocated / hours
Course Description	L	T	P	A
Legislation. Industrial health and hygiene considerations. Personal safety. Toxicity and toxic release.	05			02
Chemical hazards. Fire hazards. Explosion hazards. Chemical reaction hazards. Industrial hazards: confined entry, heat stress, etc.	08			04
Storage and transport of hazardous materials.	04			02
OSHAS 18001- Occupational Health and Safety Management Systems,Near miss management. Inherent-Passive-Active-Procedural (including work permits) risk management strategies. Accident investigation. Job safety analysis. Emergency response planning.	10	01		02
Risk Analysis such as HAZOP, Fault tree diagrams, Event tree diagrams, interaction matrix and risk matrix.	10	02
Total (equivalent hours)	37	03		05 eq. hours

Assesment	Percentage Marks
Continuous Assessments	30
Quizzes and Assignments	30
Mid-semester Examinations	30
End-semester Examinations	40

Recommended Literature

1. J. F. Richardson and J. H. Harker, Coulson and Richardson’s Chemical Engineer

CP407 Independent Study (3 credits) Pre-requisites: Prior approval of the Head of the Department for the selected project.
This course will enable students to understand and practice how to design a chemical related industrial plant from the fundamentals learnt throughout. It also involves teamwork as well as individual contribution towards preliminary process calculation on social and economic feasibility study. This course also incorporates sustainable concepts in their designs.
Intended learning outcomes Upon successful completion of this course, students should be able to, Identify/predict the market availability for a given product/s Select a location for setting up a production facility and justify (raw material availability, infrastructure, social, environment and safety issues) the selection Analyze literature and choose/synthesize a processing-path for the given product/s Describe and justify unit operations selected for the production process Apply material and energy balances (conservation laws) and determine material and energy flow rates Develop appropriate engineering drawings (Block diagrammes, PFDs, etc) Manage time and resources efficiently and effectively to successfully complete the design project
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Study in depth of a topic not available through other course work. Student works with supervising faculty member on carefully planned, student initiated project. Co-supervision of the project by a non-faculty member is highly recommended.			90
Total			45 eq.hours

Assessment	Percentage Marks
Stage 1: Assessment of the work carried out on the study via presentation of the study results by the student during the 3rd week.	20
Stage 2: Assessment of the performance in a viva during the 6th week.	30
Stage 3: Assessment of the work carried out via presentation of the study results by the student during the 11th week.	20
Stage 4: Assessment of the final study report submitted during the 14th week or a written examination, as may be necessary.	30

CP408 Basics in Process Engineering Design Project (3 credits) Pre-requisites: CP304, CP305
Aim/Objectives/Intended learning outcomes Upon successful completion of this course, students should be able to, analyze the available market for the given product analyze the available information in the literature to select and synthesize the best production process for the given product describe and explain process steps involved in the selected manufacturing process apply material and energy balances (conservation laws) and determine material and energy flows prepare appropriate engineering drawings
Course Description	Time allocated / hours
	L&T	A&P
Statement of the design of a chemical, food or other process industry; Market survey including an investigation to determine whether the product serves its functional purpose; Review of alternative process; Literature survey; Review of available physical and chemical data; Plant location and site selection; Creation and synthesis of the final flow sheet; Overall material balance and thermal balances; Flow sheeting; Pictorial presentations; Presentation of stream flow rates; Layout drawing; Piping and instrumentation; P&I diagrams; valve selection; pump selection; blower selection; alarm and safety tips and mechanical design of piping systems.	08	74
Total (equivalent hours)	08	37 equ hours

Assessment	Percentage Marks
Stage 1: Market survey, literature survey and final flow sheet via presentation	20
Stage 2: Report on material and thermal balances	30
Stage 3: VIVA voce examination	20
Stage 4: Final design project report	30

CP409 Advanced Process Engineering Design Project (3 credits) Pre-requisite: CP408
Aim/Objectives/Intended learning outcomes Upon successful completion of this course, students should be able to, Select appropriate equipments for process industries Apply knowledge of mathematics, science, and engineering codes and standards to size process equipment Use modern engineering tools necessary for engineering design practice Incorporate engineering practice and regulatory frameworks (esp. environmental and safety) in the design of processes and equipments Use appropriate engineering drawings to present essential information Perform material selection and cost estimation
Course Description	Time allocated / hours
Course Description	L&T	A&P
Process engineering design of a chemical, food or other process industry; Mechanical engineering outline design; Optimisation of process design; Outline of control system design; Operability study including start-up and shut-down; Material selection; Design codes; Determination of capital and operating costs; Study of environmental and other hazards; Process equipment selection, specification and design; Safety and loss prevention; Mechanical design of process equipment; Costing and project evaluation; Utilities; Environmental considerations (waste management; noise; visual impact; legislation; environmental auditing)		80
Selection of auxiliary equipment: conveyors, mixers and agitators, and process vessels	04	02
Total (equivalent hours)	04	41

Assessment	Percentage Marks
Stage 1: Process engineering design	20
Stage 2: Mechanical engineering and control system outline design and optimisation of process design via report and presentation	30
Stage 3: VIVA voce examination	20
Stage 4: Final design project report	30

Recommended Literature

1. J. F. Richardson and J. H. Harker, Coulson and Richardson’s Chemical Engineering Design, vol. 2, 5 th ed. Oxford, Butterworth-Heinemann, 2002.

2. R. K. Sinnott, Coulson and Richardson’s Chemical Engineering Design, vol. 6, 3 rd ed. Oxford, Butterworth-Heinemann, 1999.

3. Don W. Green and Robert H. Perry, Perry’s Chemical Engineers’ Handbook, 8 th ed. McGraw-Hill, 2007.

4. Ullmann’s Encyclopedia of Industrial Chemistry, 7 th ed. Wiley-VCH, 2011.

CP502 Advanced Fluid Mechanics (3 credits) Pre-requisites: CE202
Course Description	Time allocated / hours
Course Description	L	T	P	A
Flow of Viscous Fluids and Boundary Layer Flow	10	03
Compressible Fluid Flow	10	02
Computational Fluid Dynamics (CFD)	05		30
Total	25	05	15 eq.hours

Assessment	Percentage Marks
Continuous Assessments CFD Project	25	25
Mid-semester Examinations	25
End-semester Examinations	50

CP503 Industrial Process Technology (3 credits) Pre-requisites: none
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Industrial process technologies such as agro-processing technologies, manufacturing technologies for food, consumer products, chemicals and pharmaceuticals, petroleum refining technology, petroleum products, polymer and plastic manufacturing technologies, mineral and metallurgical processing technologies, and other appropriate industrial process technologies with special emphasis to Sri Lankan industries.	24	06
Industrial visits, report writing and assessment.				30
Total	24	06		15 eq.hours

Assessment	Percentage Marks
Continuous Assessments Assignments	25	25
Mid-semester Examinations	25
End-semester Examinations	50

CP504 Biological Process Engineering (3 credits) Pre-requisites: CH303
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Biological systems for the production of commercial goods and services: foods, drugs, chemicals, fuels, equipment, diagnostics, and waste treatment. Properties of microbial, plant and animal cells, and of enzymes used in bioprocess applications. Elementary aspects of molecular biology, biochemistry, and microbiology.	06			30
Enzyme kinetics and associated reactor design. Cellular kinetics and associated reactor design. Sterilization. Downstream processing. Biochemical and biological constraints on mass transfer, heat transfer, mixing and rheology. Control of bioreactors.	18	06
Total	24	06		15 eq.hours

Assesment	Percentage Marks
Continuous Assessments Assignments	25	25
Mid-semester Examinations	25
End-semester Examinations	50

CP505 Instrumentation and Measurement (3 credits) Pre-requisites: none
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Introduction to the fundamental concepts of instrumentation and measurement. The components of instrumentation such as transducers, amplifiers and filters. Specific measurement techniques including mass spectrometry, spectroscopy, chromatography (gas, ion exchange, HPLC), electro-chemical probes (membrane electrodes), biosensors and remote sensor devices are covered. Process Instrumentation. Data analysis and statistical treatment of data.	24	06		22
Laboratory exercises			08
Total	24	06	04 eq.hours	11 eq.hours

Assessment	Percentage Marks
Continuous Assessments Assignments Laboratory Work	25	25 10
Mid-semester Examinations	25
End-semester Examinations	50

CP506 Industrial Pollution Control System Design (3 credits) Pre-requisites: none
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Air pollution control system design: Application of physical and chemical processes in the design of air pollution control systems such as mechanical collectors, filters, scrubbers, cyclone separators, explosion vents, relief valves, electrostatic precipitators, and others. Implication for design.	10	03
Biological treatment processes for industrial effluent: Stabilisation ponds. Aerated lagoons. Activated-sludge processes. Trickling filters. Rotating biological contactors. Anaerobic reactors. Facultative ponds. Others. Implication for design.	10	03
An overview of the physiochemical treatment methods.	04
Design of selected air pollution control equipment			15
Design of selected water pollution control equipment			15
Total	24	06	15 eq.hours

Assessment	Percentage Marks
Continuous Assessments Design	25	25
Mid-semester Examinations	25
End-semester Examinations	50

CP507 Process Engineering Research Project (3 credits) Pre-requisites: A project proposal with the work plan and prior approval of the Head of the Department for the selected project proposal and the work plan.
Course Description	Time allocated / hours
Course Description	L	T	P	A*
The objective of the process engineering research project is to mathematically model a process, such as drying, heat exchanging or bio-digesting, and to experimentally verify the mathematical model.			90
Total			45 eq.hours

Assessment	Percentage Marks
Stage 1: Assessment on the project proposal, work-plan, and the literature survey submitted before the 4th week via presentation by the student or student group during the 4th week.	20
Stage 2: Assessment of the project work carried out via presentation of the results of the project by the student or student group in a seminar during the 7th week.	30
Stage 3: Assessment of the performance in a viva during the 11th week, and assessment of the final project report submitted during or before the 14th week.	50

CP508 Energy Technology for the Process Industry (3 credits) Pre-requisites: ME303
Course Description	Time allocated / hours
Course Description	L	T	P	A
Review of combustion, theory of thermal explosions, explosion limits. Premixed and diffusion flames; properties, theory, laminar flame structure, stability limits, flame propagation, shock waves, detonation. Spray combustion; properties, atomization, combustion of droplets.	08	02		04
Fuels; solid, liquid, gaseous. classification, oxidation characteristics of fuels. Coal; characteristics, physical and chemical properties. Combustion of coal; particle ignition, flames, gasification of coal. Boilers, furnaces, burners, efficiency of combustion.	12	02	14
Renewable and alternative sources of energy, applications in Sri Lankan rural industry, solar drying. Biomass; biomass conversion, synthetic fuels. Energy conservation, cogeneration. Pollutants formation and control.	10			04
Total	30	04	7 eq.hours	4 eq.hours

Assessment	Percentage Marks
Continuous Assessments Assignments Design	25	5 20
Mid-semester Examinations	25
End-semester Examinations	50

CP509 Petroleum Engineering (3 credits) Pre-requisites: none
Aim/Objectives/Intended learning outcomes Upon successful completion of this course, students should be able to, describe petroleum geology, exploration, drilling and production techniques describe transportation and storage methods of petroleum products describe petroleum refining processes describe and characterize refined petroleum products such as petrol, diesel, fuel oils, LPG and lubrication oils describe environmental health impacts of petroleum processing and petroleum products
Course Description	Time allocated / hours
Course Description	L	T	P	A
Petroleum geology, exploration, drilling operations and production. Crude oil classification; properties of petroleum products and their respective uses. Transportation of crude oil and gas. Storage of petroleum products.	10			10
Refining and processing; different refining operations, preliminary processing of petroleum, thermal and catalytic processes, cracking, reforming and hydrogenation.	10			10
Petroleum gases; properties, composition, separation and purification. Gas liquefaction, storage and transportation. Purification of petroleum products; lubrication oil refining. Petrochemical industry.	10			10
Environmental health concerns.	10			10
Total	30			15 eq.hours

Assesment	Percentage Marks
Continuous Assessments Assignments	25	25
Mid-semester Examinations	25
End-semester Examinations	50

CP511 Food Process Engineering (3 credits) Pre-requisites: none
Course Description	Time allocated / hours
Course Description	L	T	P	A
Introduction to food process technology; properties of liquids and solids, chemical and physical properties. Fluid flow in food processing; liquid handling, pumping equipment, pump selection and performance evaluation, flow and pressure measurements. Energy for food processing; fuels, fuel utilization, boilers, generation of steam, electric power utilization. Heat transfer in food processing; heat transfer modes, steady state heat transfer, thermal properties of food, systems for heating and cooling of food products. Principles of food process design.	12			04
Thermal processing; microbial survivor curves, thermal death time, spoilage probability, thermal process calculations, canning, thermal process equipment. Refrigeration; components of a refrigeration system, vapour compression refrigeration, refrigerants selection, cooling and cold storage of foods.Freezing; freezing systems, freezing of foods, freezing time, frozen food storage, thawing. Food dehydration, evaporation.	10		15
Raw material preparation, materials handling, mixing, separation. Size reduction; introduction, mechanisms, size reduction equipment. Food packaging, controlled or modified atmosphere storage. Water supply and waste disposal; water quality, water purification, waste treatment and disposal.	8			11
Hygiene and quality control in food processing industry. ISO22000 (Food safety management system). HACCP (Hazard Analysis and Critical Control Points).	8			11
Total	30		7.5 eq.hours	7.5 eq.hours

Assessment	Percentage Marks
Continuous Assessments Quizzes and Assignments Design and Lab work	25	10 15
Mid-semester Examinations	25
End-semester Examinations	50

CP512 Environmental Management Systems (3 credits) Pre-requisites: none
Course Description	Time allocated / hours
Course Description	L	T	P	A
Industry environmental interactions. Industrial pollution with examples. Impact of pollution on ecosystems. The need for pollution prevention. Environmental standards for emission of pollutants. Industrial effluent pollution in major process and chemical industries with special emphasis on Sri Lankan industries.	06			04
Introduction to Cleaner Production (CP) and Green Productivity (GP) concepts. CP and GP methodologies. CP and GP tools such as product modification, raw material substitution, good housekeeping, process control, brain-storming, eco mapping, fishbone diagram and Pareto diagram.	15			06
Introduction to Life Cycle Assessment (LCA) and methods. Eco design concept. Tools for eco design.	06			04
ISO 14000: components of ISO 14000, Implementation aspects and procedures.	10			02
Total	37			7.5 eq.hours

Assessment	Percentage Marks
Continuous Assessments Quizzes and Assignments	25	25
Mid-semester Examinations	25
End-semester Examinations	50

CP513 Industrial Fluid Mechanics (3 credits) Pre-requisite: none
Aim/Objectives/Intended learning outcomes Upon successful completion of this course, students should be able to, describe industrial applications related to flow through porous media derive governing equations of processes such as fluidisation, filtration from basic equations in fluid mechanics design process units such as fluidised beds, filters, and pneumatic and slurry transport systems describe the operational principles of selected hydraulic machines
Course Description	Time allocated / hours
Course Description	L&T	A&P
Flow through porous media: particle fluid mechanics, fluidisation, and filtration.	14	04
Pneumatic transportation, transport of slurries	07
Design of fluidised beds, packed beds, filters, and pneumatic transport systems		18
Basic Hydraulic/Pneumatic power principles, fluid power symbols and diagrams, actuators, control valves, fluid preparation systems, contamination control, directional and pressure controls and applications.	11	04
Total (equivalent hours)	32	13

Assessment	Percentage Marks
Continuous Assessments Design Laboratory work Tutorials Mid-semester Examinations	15 10 10 25
End-semester Examinations	40

CP551 Sustainable Development (3 credits) Pre-requisites: none
Course Description	Time allocated / hours
Course Description	L	T	P	A*
Components of sustainable development: environment, economy and society. Games and group discussions to introduce the need for sustainable development in today’s world.	03
Concepts of economic development and human development. Economic development indices and their critique. Human development index and its critique. Discussion on sustainable development indices.	03
Group discussion on economic development, and the impact on public health and environment.	03
Group discussion on climate change and development, and other environmental and ecological related issues in today’s world.	03
Science, technology, innovations and sustainable development.	03
Energy and transport for economic development and human development, and their impact on sustainable development.	03
Industrial and service sector and their impact on sustainable development.	03
Use of fertilizers and pesticides, green revolution and agricultural biotechnology in the agricultural sector, and their impact on sustainable development.	03
Globalization and its impact on sustainable development.	03
Information and communication technology and its impact on sustainable development.	03
Sustainable development project execution, report writing and assessment.			30
Total	30		15 eq.hours

Assesment	Percentage Marks
Continuous Assessments Project	50	50
Mid-semester Examinations	50

A* :
It is the assignment component of the course unit, which involves a student working out unassisted one or more of the following components: a problem, a design, a computer simulation or a literature search, assigned to him/her by the lecturer concerned. The assessment of the student’s performance in the assignment is carryout out by one or more of the following components: report, interview, viva or presentation.

EM203 Numerical Methods in Chemical & Process Engineering (3 credits) Pre-requisite: none
Anticipated learning outcomes: Use of modern computational and mathematical techniques in chemical and process engineering Acquiring the knowledge, understanding and skills required for the use of pertinent software and appropriate programming language Ability to solve sets of linear and nonlinear algebraic equations, ordinary differential equations, and differential-algebraic (DAE) systems in chemical and process engineering Ability to solve partial differential equations obtained from transport phenomena in chemical and process engineering
Course Description	Time allocated / hours
Course Description	L&T	A&P
Introduction to computing software		08
Introduction to numerical methods: Error analysis	02
Numerical solutions to systems of linear equations: Gaussian elimination, Iterative methods, Relaxation methods	04
Numerical solutions to non-linear equations: Fixed point iteration, Newton-Raphson method, System of non-linear equations	04
Numerical calculus: Differentiation, Interpolation method, Finite difference integration, Newton-Cotes methods, Gaussian integration methods	06
Numerical solutions to ordinary differential equations: Initial value problems: Euler method, Runge-Kutta methods Boundary value problems: Finite difference Method Solving system of ordinary differential equations and higher order differential equations Adaptive step size mechanisms	06
Numerical solutions to partial differential equations: Explicit and implicit finite difference methods; Basics of finite element methods	10
Assignments / Projects in chemical & process engineering³		18
Total (equivalent hours)	32	13

Assesment	Percentage Marks
Continuous Assessments Mid semester exam Assignments / projects	20 40
End-semester Examinations	40

³ Assignments / Projects component must be coordinated and examined by the Department of Chem & Process Eng. since these components deal with examples from chemical and process engineering.

CP514 Sustainability for Process Industry (S4PI) Work Camp (1 credit) Pre-requisite: none
Intended Learning Outcomes (ILOs): Plan and collect data necessary to carry out materials, energy and water audits in an industry and carry out the said audits Investigate and identify the causes of industrial problems in relation to energy, environmental, materials and occupational health and safety issues Propose solutions to industrial problems in relation to energy, environmental, materials and safety issues by carrying out relevant technical and economical analysis Plan and execute team work to achieve a goal in a resource-limited, time-limited real-life situation Adopt holistic approach to problem identification and problem solving Self-learn new concepts and practices Effectively communicate technical information via oral presentation Effectively express themselves via technical reports
Course Description	Time allocated / hours
	Lecture	Field Study
Concepts and practices of materials, energy, water and waste audits in an industrial environment (self study) Organize and carry out materials, energy, water and waste audits and other studies required to identify the causes of problems in relation to energy, environmental, materials, and safety issues in a chosen industry (Team work) Propose solutions to enhance resource productivity, occupational health and safety, and improve material sustainability by carrying out technical and economic analyses of plausible solutions (Team Work)		2 weeks
Total (equivalent hours)		15

Method of assessment	Marks assigned
Viva-voce examinations	60%
Oral presentations	20%
Final report	20%

Suggested Texts:

A. Thumann, T. Niehus, W.J. Younger (2012). Handbook of Energy Audits, 9th edition. Fairmont Press.
N.P. Cheremisinoff (2009). Handbook of Pollution Prevention and Cleaner Production Vol. 1: Best Practices in the Petroleum Industry. William Andrew.
Sri Lanka Energy Managers Association (2013), Energy Audit Manuals, Vol 1-4.
S. Mannan (2012). Lees’ Loss Prevention in the Process Industries: Hazard Identification, Assessment and Control (3 volumes), 4th edition. Butterworth-Heinemann.
Asian Productivity Organization 2002, Green Productivity Training Manual

CP515 Modelling and Simulation of Simultaneous Transport Phenomena with MATLAB® and COMSOL Multiphysics® (3 credits) Pre-requisite: Prior exposure to mathematical modelling using momentum, energy and mass transport phenomena; EM203 Numerical Methods in Chemical & Process Engineering or equivalent Aim: Chemical & process engineering undergraduates at University of Peradeniya learn the foundations in process modeling in independent course modules dealing with momentum, energy and mass transport phenomena. Successful application of what are learnt in the said independent course modules to deal with practical process engineering systems require the following skills in an undergraduate Modelling of practical process engineering systems in a unified framework where momentum, energy and mass transport phenomena often occur simultaneously. Simulation of such complex systems modelled in a unified framework using advanced simulation packages such as MATLAB® and COMSOL Multiphysics®. The proposed course module is designed to impart the aforementioned skills in the chemical and process engineering undergraduates.
Intended Learning Outcomes (ILOs): Derive mathematical models of practical process engineering systems in a unified framework where momentum, energy and mass transport phenomena occur simultaneously, supplemented by empirical relationships, where necessary Simulate published case studies where the coupling between different mathematical models is implemented using MATLAB® and COMSOL Multiphysics® Critically analyze the simulation results by carrying out error analysis, sensitivity analysis and uncertainty analysis and by benchmarking the solution
Course Description	Time allocated / hours
Course Description	Lecture	Laboratory
Mathematical modeling in a unified framework: Review of momentum, energy and mass transport phenomena; Process modeling using simultaneous momentum, energy and mass transport phenomena.	03	15
Introduction to COMSOL Multiphysics®	06
Analysis of numerical solutions of ODEs and PDEs: Truncation and discretization errors in numerical analysis by the use of approximate functions in the different terms of the PDEs such as the order of a Lagrange polynomial to form a shape function in finite element and the size of the mesh elements; comparisons between analytical solutions and numerical solutions; grid convergence analysis; sensitivity analysis; effect of parameter uncertainty on the simulation results.	03
Computational laboratory sessions with MATLAB® and COMSOL Multiphysics® in solving case studies.	03	45
Total (equivalent hours)	15	30

Oral presentations20%

Method of assessment	Marks assigned
Viva-voce examinations on the laboratory performance	40%
Viva-voce examinations on the interim reports	10%
Final report	30%

CP516 Nanotechnology for Chemical Engineers(3 credits) Pre-requisite: CP203 Aim: To provide knowledge on nanotechnology and its applications Modelling of practical process engineering systems in a unified framework where momentum, energy and mass transport phenomena often occur simultaneously. Simulation of such complex systems modelled in a unified framework using advanced simulation packages such as MATLAB® and COMSOL Multiphysics®. The proposed course module is designed to impart the aforementioned skills in the chemical and process engineering undergraduates.
Intended Learning Outcomes (ILOs): ILO1: Define important properties of nano-materials. ILO2: Explain different types of nanomaterial synthesis and characterization methods. ILO3: Experiment with chemical synthesis of nanomaterials and identify their properties. ILO4: Evaluate relationships between the properties of nanomaterial and their applications.
Course Description	Time allocated / hours
Course Description	L	T	P	A
Introduction Introduction to nanotechnology and nanomaterials, properties of nanomaterials	03		16
Synthesis of nanomaterials Bottom-Up Approaches – Sol-Gel Processing, Chemical Vapor Deposition, Flame Spraying, Synthesis, Self-Assembly Synthesis, Atomic or Molecular Gas Condensation Process, Electrochemical Deposition/Electrodeposition, Nano-casting, homogeneous nucleation.	14			03
Characterization X-Ray Diffraction, Scanning Electron Microscopy, Transmission Electron Microscopy, Scanning Probe Microscopy, TGA, N₂ Adsorption /desorption, FTIR, EDX, NMR.	09
Applications Applications of nanomaterials and nanotechnology in the fields of manufacturing, energy, environment, and pharmaceuticals.	06			03
Environmental and safety consideration.	02
Total (equivalent hours)	34	08		03

Recommended Texts
Kumar, N., Kumbhat, S., Essentials in Nanoscience and Nanotechnology, (1 Ed), John Wiley & Sons, 2016.

Elnashaie, S.S., Danafar, F., Rafsanjani, H. H., Nanotechnology for Chemical Engineers, (1 Ed), Springer Science Business Media Singapore, 2015.

Cao, G., Nanostructures and Nanomaterials, (2 Ed), Imperial College Press, 2010.

Zhang, J., Wang, Z., Liu, J., Chen, S., Liu, G., Self-Assembled Nanostructures, Series: Nanostructure Science and Technology, (Kindle Ed), Springer, 2002.

Ozin, G. A., Arsenault, A. C., Cademartiri, L., Nanochemistry, A Chemical Approach to Nanomaterials, (2 Ed), Wiley-VCH, 2008.

Rolando, M. A., Malherbe, R., The Physical Chemistry of Materials: Energy and Environmental Applications, (1 Ed), CRC Press, 2009.

Method of assessment	Marks assigned
Tutorials/Assignments/Quizzes/Laboratory work	25%
Mid Semester Examination	25%
End Semester Examination	50%

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