ZUT - Krajowe Ramy Kwalifikacji / Rok 2018/2019 / Wydział Technologii i Inżynierii Chemicznej / Chemical Engineering (S1) / Sylabus przedmiotu - Introduction to Modeling, Simulation and Numerical Methods Applied to Chemical Engineering

Wydział Technologii i Inżynierii Chemicznej - Chemical Engineering (S1)

Sylabus przedmiotu Introduction to Modeling, Simulation and Numerical Methods Applied to Chemical Engineering:

Informacje podstawowe

Kierunek studiów	Chemical Engineering
Forma studiów	studia stacjonarne	Poziom	pierwszego stopnia
Tytuł zawodowy absolwenta	inżynier
Obszary studiów	nauki techniczne, studia inżynierskie
Profil	ogólnoakademicki
Moduł	—
Przedmiot	Introduction to Modeling, Simulation and Numerical Methods Applied to Chemical Engineering
Specjalność	przedmiot wspólny
Jednostka prowadząca	Instytut Inżynierii Chemicznej i Procesów Ochrony Środowiska
Nauczyciel odpowiedzialny	Paulina Pianko-Oprych <Paulina.Pianko@zut.edu.pl>
Inni nauczyciele	Tomasz Aleksandrzak <Tomasz.Aleksandrzak@zut.edu.pl>, Bogdan Ambrożek <Bogdan.Ambrozek@zut.edu.pl>, Paulina Pianko-Oprych <Paulina.Pianko@zut.edu.pl>, Anna Story <Anna.Story@zut.edu.pl>, Konrad Witkiewicz <Konrad.Witkiewicz@zut.edu.pl>, Katarzyna Ziętarska <kzietarska@zut.edu.pl>
ECTS (planowane)	5,0	ECTS (formy)	5,0
Forma zaliczenia	zaliczenie	Język	angielski
Blok obieralny	3	Grupa obieralna	1

Formy dydaktyczne

Forma dydaktyczna	KOD	Semestr	Godziny	ECTS	Waga	Zaliczenie
laboratoria	L	4	45	3,0	0,50	zaliczenie
wykłady	W	4	30	2,0	0,50	zaliczenie

Wymagania wstępne

KOD	Wymaganie wstępne
W-1	Mathematics
W-2	Physics
W-3	Thermodynamics

Cele przedmiotu

KOD	Cel modułu/przedmiotu
C-1	This course focuses on the use of modern computational and mathematical techniques in chemical engineering. Starting from a discussion of linear systems as the basic computational unit in scientific computing, methods for solving sets of nonlinear algebraic equations, ordinary differential equations, and differential-algebraic (DAE) systems are presented. Mathematical modelling of steady-state and dynamic chemical engineering systems is discussed. Basic optimization theory and algorithms with applications to chemical engineering problems are discussed. Process simulation techniques are presented. Utilization of mass, energy and momentum balances and rate processes to describe the behaviour of chemical engineering systems will be shown. The use of these techniques will be demonstrated throughout the course in the MATLAB and Aspen TECH computing environments.

KOD

Cel modułu/przedmiotu

C-1

This course focuses on the use of modern computational and mathematical techniques in chemical engineering. Starting from a discussion of linear systems as the basic computational unit in scientific computing, methods for solving sets of nonlinear algebraic equations, ordinary differential equations, and differential-algebraic (DAE) systems are presented. Mathematical modelling of steady-state and dynamic chemical engineering systems is discussed. Basic optimization theory and algorithms with applications to chemical engineering problems are discussed. Process simulation techniques are presented. Utilization of mass, energy and momentum balances and rate processes to describe the behaviour of chemical engineering systems will be shown. The use of these techniques will be demonstrated throughout the course in the MATLAB and Aspen TECH computing environments.

Treści programowe z podziałem na formy zajęć

KOD	Treść programowa	Godziny
laboratoria
T-L-1	MATLAB Basics (AT, AB, WK, ZK)	3
T-L-2	Curve-Fitting (AT, AB, WK, ZK)	3
T-L-3	Numerical Integration (AT, AB, WK, ZK)	3
T-L-4	A System of Algebraic Equations (AT, AB, WK, ZK)	3
T-L-5	Solving Differential Equations (AT, AB, PPO, SA, WK, ZK)	6
T-L-6	Solving selected problems from chemical engineering in Matlab (AT, AB, PPO, SA, WK, ZK)	9
T-L-7	Introducing Aspen Plus (PPO, SA)	3
T-L-8	Aspen Plus Flowsheet Features (PPO, SA)	6
T-L-9	Simulation of selected problems from chemical engineering in Aspen Plus (PPO, SA)	9
		45
wykłady
T-W-1	Formulation of physicochemical problems (AT, AB, WK)	3
T-W-2	Classification of mathematical models (AT, AB, WK)	3
T-W-3	Reducing mathematical models (AT, AB, WK)	3
T-W-4	Error estimations (AT, AB, WK)	3
T-W-5	Numerical methods for ordinary differential equations, ODEs (AT, AB, PPO, SA, WK)	6
T-W-6	Methods for boundary value problems (AT, AB, PPO, SA, WK)	3
T-W-7	Numerical methods for partial differential equations, PDEs (AT, AB, PPO, SA, WK)	3
T-W-8	Statistical analysis of mathematical models (AT, AB, PPO, SA, WK)	6
		30

Obciążenie pracą studenta - formy aktywności

KOD	Forma aktywności	Godziny
laboratoria
A-L-1	Classroom participation	45
A-L-2	Preparation of reports in MATLAB	20
A-L-3	Preparation of reports in Aspen Plus	10
A-L-4	One-on-one teaching consultations	6
A-L-5	Literature studies	10
		91
wykłady
A-W-1	Lecture participation	30
A-W-2	Individual literature studies	20
A-W-3	One-on-one teaching consultations	5
A-W-4	Repetition of the lecture content to the written test	5
		60

Metody nauczania / narzędzia dydaktyczne

KOD	Metoda nauczania / narzędzie dydaktyczne
M-1	Preparation of a multimedia for of lecture presentation
M-2	Numerical analysis by solving chemical engineering problems using MATLAB.
M-3	Numerical analysis by solving chemical engineering problems using Aspen TECH.

Sposoby oceny

KOD	Sposób oceny
S-1	Ocena podsumowująca: Written final exam based on the lecture contents.
S-2	Ocena formująca: Mid-term exam 1 - MATLAB.
S-3	Ocena formująca: Mid-term exam 2 - Aspen TECH

Zamierzone efekty kształcenia - wiedza

Zamierzone efekty kształcenia	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Odniesienie do efektów kształcenia prowadzących do uzyskania tytułu zawodowego inżyniera	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
ChEn_1A_C08a_W01 Students can formulate mathematical models and translate them into forms appropriate for computation. Students can identify problem structure, scale and complexity.	ChEn_1A_W15, ChEn_1A_W08, ChEn_1A_W07, ChEn_1A_W06	—	—	C-1	T-W-5, T-W-7, T-W-8, T-W-2, T-W-4, T-W-6, T-W-3, T-W-1	M-1	S-1

Zamierzone efekty kształcenia - umiejętności

Zamierzone efekty kształcenia	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Odniesienie do efektów kształcenia prowadzących do uzyskania tytułu zawodowego inżyniera	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
ChEn_1A_C08a_U01 Students have a working knowledge of MATLAB and AspenTech. Students can produce working code to solve com- mon chemical engineering problems including steady-state and dynamic simulatin. Students can readily interpret results and output.	ChEn_1A_U03, ChEn_1A_U05, ChEn_1A_U09, ChEn_1A_U16, ChEn_1A_U07, ChEn_1A_U01, ChEn_1A_U08	—	—	C-1	T-L-6, T-L-4, T-L-9, T-L-7, T-L-1, T-L-5, T-L-8, T-L-2, T-L-3	M-2, M-3	S-3, S-2

Zamierzone efekty kształcenia - inne kompetencje społeczne i personalne

Zamierzone efekty kształcenia	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Odniesienie do efektów kształcenia prowadzących do uzyskania tytułu zawodowego inżyniera	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
ChEn_1A_C08a_K01 Students can select methods and software based on problem types. Students can defend the selection of methods and software based on characteristics such as convergence properties, time complexity, storage complexity, accuracy, and limitations with respect to specific problems.	ChEn_1A_K04, ChEn_1A_K05, ChEn_1A_K03, ChEn_1A_K01	—	—	C-1	T-L-9, T-L-8, T-L-4, T-L-1, T-L-2, T-L-5, T-L-7, T-L-6, T-L-3	M-3, M-2	S-2, S-3

Kryterium oceny - wiedza

Efekt kształcenia	Ocena	Kryterium oceny
ChEn_1A_C08a_W01 Students can formulate mathematical models and translate them into forms appropriate for computation. Students can identify problem structure, scale and complexity.	2,0	Unacceptable understanding of course material.
	3,0	Serious deficiencies in understanding the core subject material.
	3,5	Some deficiencies in understanding the subject material.
	4,0	Some deficiencies in understanding the core subject material.
	4,5	Some mild deficiencies in Mastery of subject material.
	5,0	Complete Mastery of subject material.

Kryterium oceny - umiejętności

Efekt kształcenia	Ocena	Kryterium oceny
ChEn_1A_C08a_U01 Students have a working knowledge of MATLAB and AspenTech. Students can produce working code to solve com- mon chemical engineering problems including steady-state and dynamic simulatin. Students can readily interpret results and output.	2,0	Unacceptable understanding of course material.
	3,0	Serious deficiencies in understanding the core subject material.
	3,5	Some deficiencies in understanding the subject material.
	4,0	Some deficiencies in understanding the core subject material.
	4,5	Some mild deficiencies in Mastery of subject material.
	5,0	Complete Mastery of subject material.

Kryterium oceny - inne kompetencje społeczne i personalne

Efekt kształcenia	Ocena	Kryterium oceny
ChEn_1A_C08a_K01 Students can select methods and software based on problem types. Students can defend the selection of methods and software based on characteristics such as convergence properties, time complexity, storage complexity, accuracy, and limitations with respect to specific problems.	2,0	Unacceptable understanding of course material.
	3,0	Serious deficiencies in understanding the core subject material.
	3,5	Some deficiencies in understanding the subject material.
	4,0	Some deficiencies in understanding the core subject material.
	4,5	Some mild deficiencies in Mastery of subject material.
	5,0	Complete Mastery of subject material.

Literatura podstawowa

R.G. Rice, D.D. Do, Applied mathematics and modeling for chemical engineers, John Wiley & Sons, Inc., New York, 2012
B.A. Finlayson, Introduction to chemical engineering computing, John Wiley & Sons, Inc., New Jersey, 2006
K.I.M. Al-Malah, MATLAB Numerical Methods with Chemical Engineering Applications, McGraw-Hill Education, 2014
K.I.M. Al-Malah, Aspen Plus Chemical Engineering Applications, John Wiley & Sons, Inc., New Jersey, 2017

Literatura dodatkowa

Drfman K. D., Prodromos D., Numerical Methods with Chemical Engineer- ing Applications, Cambridge University Press, 2017, 9781107135116

Treści programowe - laboratoria

KOD	Treść programowa	Godziny
T-L-1	MATLAB Basics (AT, AB, WK, ZK)	3
T-L-2	Curve-Fitting (AT, AB, WK, ZK)	3
T-L-3	Numerical Integration (AT, AB, WK, ZK)	3
T-L-4	A System of Algebraic Equations (AT, AB, WK, ZK)	3
T-L-5	Solving Differential Equations (AT, AB, PPO, SA, WK, ZK)	6
T-L-6	Solving selected problems from chemical engineering in Matlab (AT, AB, PPO, SA, WK, ZK)	9
T-L-7	Introducing Aspen Plus (PPO, SA)	3
T-L-8	Aspen Plus Flowsheet Features (PPO, SA)	6
T-L-9	Simulation of selected problems from chemical engineering in Aspen Plus (PPO, SA)	9
		45

Treści programowe - wykłady

KOD	Treść programowa	Godziny
T-W-1	Formulation of physicochemical problems (AT, AB, WK)	3
T-W-2	Classification of mathematical models (AT, AB, WK)	3
T-W-3	Reducing mathematical models (AT, AB, WK)	3
T-W-4	Error estimations (AT, AB, WK)	3
T-W-5	Numerical methods for ordinary differential equations, ODEs (AT, AB, PPO, SA, WK)	6
T-W-6	Methods for boundary value problems (AT, AB, PPO, SA, WK)	3
T-W-7	Numerical methods for partial differential equations, PDEs (AT, AB, PPO, SA, WK)	3
T-W-8	Statistical analysis of mathematical models (AT, AB, PPO, SA, WK)	6
		30

Formy aktywności - laboratoria

KOD	Forma aktywności	Godziny
A-L-1	Classroom participation	45
A-L-2	Preparation of reports in MATLAB	20
A-L-3	Preparation of reports in Aspen Plus	10
A-L-4	One-on-one teaching consultations	6
A-L-5	Literature studies	10
		91

(*) 1 punkt ECTS, odpowiada około 30 godzinom aktywności studenta

Formy aktywności - wykłady

KOD	Forma aktywności	Godziny
A-W-1	Lecture participation	30
A-W-2	Individual literature studies	20
A-W-3	One-on-one teaching consultations	5
A-W-4	Repetition of the lecture content to the written test	5
		60

(*) 1 punkt ECTS, odpowiada około 30 godzinom aktywności studenta

Pole	KOD	Znaczenie kodu
Zamierzone efekty kształcenia	ChEn_1A_C08a_W01	Students can formulate mathematical models and translate them into forms appropriate for computation. Students can identify problem structure, scale and complexity.
Odniesienie do efektów kształcenia dla kierunku studiów	ChEn_1A_W15	Knows basic methods, techniques, tools and materials used for solving simple engineering tasks within the scope of chemical engineering and technology.
	ChEn_1A_W08	Has systematic, theory-based knowledge of the key issues in chemical engineering and technology connected with the unit operations and processes.
	ChEn_1A_W07	Has systematic, theory-based general knowledge within the scope of chemical engineering and technology.
	ChEn_1A_W06	Has basic knowledge within the scope of product and quality engineering.
Cel przedmiotu	C-1	This course focuses on the use of modern computational and mathematical techniques in chemical engineering. Starting from a discussion of linear systems as the basic computational unit in scientific computing, methods for solving sets of nonlinear algebraic equations, ordinary differential equations, and differential-algebraic (DAE) systems are presented. Mathematical modelling of steady-state and dynamic chemical engineering systems is discussed. Basic optimization theory and algorithms with applications to chemical engineering problems are discussed. Process simulation techniques are presented. Utilization of mass, energy and momentum balances and rate processes to describe the behaviour of chemical engineering systems will be shown. The use of these techniques will be demonstrated throughout the course in the MATLAB and Aspen TECH computing environments.
Treści programowe	T-W-5	Numerical methods for ordinary differential equations, ODEs (AT, AB, PPO, SA, WK)
	T-W-7	Numerical methods for partial differential equations, PDEs (AT, AB, PPO, SA, WK)
	T-W-8	Statistical analysis of mathematical models (AT, AB, PPO, SA, WK)
	T-W-2	Classification of mathematical models (AT, AB, WK)
	T-W-4	Error estimations (AT, AB, WK)
	T-W-6	Methods for boundary value problems (AT, AB, PPO, SA, WK)
	T-W-3	Reducing mathematical models (AT, AB, WK)
	T-W-1	Formulation of physicochemical problems (AT, AB, WK)
Metody nauczania	M-1	Preparation of a multimedia for of lecture presentation
Sposób oceny	S-1	Ocena podsumowująca: Written final exam based on the lecture contents.
Kryteria oceny	Ocena	Kryterium oceny
	2,0	Unacceptable understanding of course material.
	3,0	Serious deficiencies in understanding the core subject material.
	3,5	Some deficiencies in understanding the subject material.
	4,0	Some deficiencies in understanding the core subject material.
	4,5	Some mild deficiencies in Mastery of subject material.
	5,0	Complete Mastery of subject material.

Pole	KOD	Znaczenie kodu
Zamierzone efekty kształcenia	ChEn_1A_C08a_U01	Students have a working knowledge of MATLAB and AspenTech. Students can produce working code to solve com- mon chemical engineering problems including steady-state and dynamic simulatin. Students can readily interpret results and output.
Odniesienie do efektów kształcenia dla kierunku studiów	ChEn_1A_U03	Is able to prepare, in English or another foreign language, a well-documented study of problems within the scope of chemical and process engineering; is able to develop documentation concerning the accomplishment of an engineering task.
	ChEn_1A_U05	Has the ability to learn, e.g. to raise professional competences.
	ChEn_1A_U09	Is able to use analytic, numerical and experimental methods to formulate and solve engineering tasks.
	ChEn_1A_U16	Is able to assess the usefulness of routine methods and tools used for solving a simple engineering task of practical nature characteristic for chemical engineering and technology as well as select and use a proper performance method and tools.
	ChEn_1A_U07	Is able to use computer programs supporting the accomplishment of basic engineering tasks.
	ChEn_1A_U01	Is able to obtain information from literature, data bases and other sources related to chemical engineering and technology as well as related areas; is able to integrate the obtained information, interpret it, draw proper conclusions and formulate opinions with their justification.
	ChEn_1A_U08	Is able to plan and conduct process experiments, including measurements and computer simulations, as well as to interpret the obtained results and draw conclusions.
Cel przedmiotu	C-1	This course focuses on the use of modern computational and mathematical techniques in chemical engineering. Starting from a discussion of linear systems as the basic computational unit in scientific computing, methods for solving sets of nonlinear algebraic equations, ordinary differential equations, and differential-algebraic (DAE) systems are presented. Mathematical modelling of steady-state and dynamic chemical engineering systems is discussed. Basic optimization theory and algorithms with applications to chemical engineering problems are discussed. Process simulation techniques are presented. Utilization of mass, energy and momentum balances and rate processes to describe the behaviour of chemical engineering systems will be shown. The use of these techniques will be demonstrated throughout the course in the MATLAB and Aspen TECH computing environments.
Treści programowe	T-L-6	Solving selected problems from chemical engineering in Matlab (AT, AB, PPO, SA, WK, ZK)
	T-L-4	A System of Algebraic Equations (AT, AB, WK, ZK)
	T-L-9	Simulation of selected problems from chemical engineering in Aspen Plus (PPO, SA)
	T-L-7	Introducing Aspen Plus (PPO, SA)
	T-L-1	MATLAB Basics (AT, AB, WK, ZK)
	T-L-5	Solving Differential Equations (AT, AB, PPO, SA, WK, ZK)
	T-L-8	Aspen Plus Flowsheet Features (PPO, SA)
	T-L-2	Curve-Fitting (AT, AB, WK, ZK)
	T-L-3	Numerical Integration (AT, AB, WK, ZK)
Metody nauczania	M-2	Numerical analysis by solving chemical engineering problems using MATLAB.
Metody nauczania	M-3	Numerical analysis by solving chemical engineering problems using Aspen TECH.
Sposób oceny	S-3	Ocena formująca: Mid-term exam 2 - Aspen TECH
Sposób oceny	S-2	Ocena formująca: Mid-term exam 1 - MATLAB.
Kryteria oceny	Ocena	Kryterium oceny
	2,0	Unacceptable understanding of course material.
	3,0	Serious deficiencies in understanding the core subject material.
	3,5	Some deficiencies in understanding the subject material.
	4,0	Some deficiencies in understanding the core subject material.
	4,5	Some mild deficiencies in Mastery of subject material.
	5,0	Complete Mastery of subject material.

Pole	KOD	Znaczenie kodu
Zamierzone efekty kształcenia	ChEn_1A_C08a_K01	Students can select methods and software based on problem types. Students can defend the selection of methods and software based on characteristics such as convergence properties, time complexity, storage complexity, accuracy, and limitations with respect to specific problems.
Odniesienie do efektów kształcenia dla kierunku studiów	ChEn_1A_K04	Is able to determine the priorities used for performance of the tasks of his/her own or other team members in order to achieve the goal set.
	ChEn_1A_K05	Is able to manage his/her own professional development, taking decisions and solving problems, including interpersonal ones connected with job performance.
	ChEn_1A_K03	Is able to cooperate and work in a group. Is able to perform the function of a team leader; is able to estimate the time necessary to accomplish the assigned task.
	ChEn_1A_K01	Understands the need of learning and raising professional and personal competences, motivating other colleagues.
Cel przedmiotu	C-1	This course focuses on the use of modern computational and mathematical techniques in chemical engineering. Starting from a discussion of linear systems as the basic computational unit in scientific computing, methods for solving sets of nonlinear algebraic equations, ordinary differential equations, and differential-algebraic (DAE) systems are presented. Mathematical modelling of steady-state and dynamic chemical engineering systems is discussed. Basic optimization theory and algorithms with applications to chemical engineering problems are discussed. Process simulation techniques are presented. Utilization of mass, energy and momentum balances and rate processes to describe the behaviour of chemical engineering systems will be shown. The use of these techniques will be demonstrated throughout the course in the MATLAB and Aspen TECH computing environments.
Treści programowe	T-L-9	Simulation of selected problems from chemical engineering in Aspen Plus (PPO, SA)
	T-L-8	Aspen Plus Flowsheet Features (PPO, SA)
	T-L-4	A System of Algebraic Equations (AT, AB, WK, ZK)
	T-L-1	MATLAB Basics (AT, AB, WK, ZK)
	T-L-2	Curve-Fitting (AT, AB, WK, ZK)
	T-L-5	Solving Differential Equations (AT, AB, PPO, SA, WK, ZK)
	T-L-7	Introducing Aspen Plus (PPO, SA)
	T-L-6	Solving selected problems from chemical engineering in Matlab (AT, AB, PPO, SA, WK, ZK)
	T-L-3	Numerical Integration (AT, AB, WK, ZK)
Metody nauczania	M-3	Numerical analysis by solving chemical engineering problems using Aspen TECH.
Metody nauczania	M-2	Numerical analysis by solving chemical engineering problems using MATLAB.
Sposób oceny	S-2	Ocena formująca: Mid-term exam 1 - MATLAB.
Sposób oceny	S-3	Ocena formująca: Mid-term exam 2 - Aspen TECH
Kryteria oceny	Ocena	Kryterium oceny
	2,0	Unacceptable understanding of course material.
	3,0	Serious deficiencies in understanding the core subject material.
	3,5	Some deficiencies in understanding the subject material.
	4,0	Some deficiencies in understanding the core subject material.
	4,5	Some mild deficiencies in Mastery of subject material.
	5,0	Complete Mastery of subject material.