ZUT - Krajowe Ramy Kwalifikacji / Rok 2018/2019 / Administracja Centralna Uczelni / Wymiana międzynarodowa (S2) / Sylabus przedmiotu

Administracja Centralna Uczelni - Wymiana międzynarodowa (S2)

Sylabus przedmiotu Computational fluid dynamics:

Informacje podstawowe

Kierunek studiów	Wymiana międzynarodowa
Forma studiów	studia stacjonarne	Poziom	drugiego stopnia
Tytuł zawodowy absolwenta
Obszary studiów	—
Profil
Moduł	—
Przedmiot	Computational fluid dynamics
Specjalność	przedmiot wspólny
Jednostka prowadząca	Instytut Inżynierii Chemicznej i Procesów Ochrony Środowiska
Nauczyciel odpowiedzialny	Halina Murasiewicz <Halina.Murasiewicz@zut.edu.pl>
Inni nauczyciele	Anna Story <Anna.Story@zut.edu.pl>
ECTS (planowane)	4,0	ECTS (formy)	4,0
Forma zaliczenia	zaliczenie	Język	polski
Blok obieralny	—	Grupa obieralna	—

Formy dydaktyczne

Forma dydaktyczna	KOD	Semestr	Godziny	ECTS	Waga	Zaliczenie
wykłady	W	1	30	2,0	0,50	zaliczenie
laboratoria	L	1	30	2,0	0,50	zaliczenie

Wymagania wstępne

KOD	Wymaganie wstępne
W-1	Chemical engineering fundamentals
W-2	Fluid Dynamics
W-3	Applied Mathematics

Cele przedmiotu

KOD	Cel modułu/przedmiotu
C-1	Specific objectives may be summarized as: • To understand mathematical characteristics of partial differential equations. • To understand basic properties of computational methods – accuracy, stability, consistency • To learn computational solution techniques for time integration of ordinary differential equations • To learn computational solution techniques for various types of partial differential equations • To learn how to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB

KOD

Cel modułu/przedmiotu

C-1

Specific objectives may be summarized as: • To understand mathematical characteristics of partial differential equations. • To understand basic properties of computational methods – accuracy, stability, consistency • To learn computational solution techniques for time integration of ordinary differential equations • To learn computational solution techniques for various types of partial differential equations • To learn how to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB

Treści programowe z podziałem na formy zajęć

KOD	Treść programowa	Godziny
laboratoria
T-L-1	Introduction to Computational Fluid Dynamics in ANSYS Workbench. Graphical User Interface	1
T-L-2	Creating the geometry in ANSYS DesignModeler	5
T-L-3	Generation of mesh in ANSYS Mesher	4
T-L-4	Introduction to CFD simulations in ANSYS Fluent. Definition of materials of the object and boundary conditions for fluid flow	2
T-L-5	Postprocessing in ANSYS Fluent	2
T-L-6	Analysis of a laminar flow in ANSYS Fluent	2
T-L-7	Applying turbulence model in ANSYS Fluent	2
T-L-8	Analysis of a heat transfer in ANSYS Fluent	2
T-L-9	Simulation of multiphase flow in ANSYS Fluent	2
T-L-10	Modeling of rotating elements in fluent (e.g. rotating wall, multiple reference frame, sliding mesh)	2
T-L-11	Modeling of a selected issue including creating the geometry, generating the mesh, performing the simulations and postprocessing	6
		30
wykłady
T-W-1	Illustration of the CFD approach; CFD as an engineering analysis tool	2
T-W-2	Introduction to numerical methods for Euler and Navier-Stokes equations with emphasis on error analysis, consistency, accuracy and stability	6
T-W-3	Finite difference methods, finite volume and spectral element methods. Explicit vs. implicit time stepping methods	4
T-W-4	Methodology of solving CFD problems	2
T-W-5	Coupling of velocity and pressure fields	2
T-W-6	Computation of turbulent flows	4
T-W-7	Multiphase flows and their modelling	4
T-W-8	Structured and unstructured grids	1
T-W-9	Structured grid generation methods.	2
T-W-10	Unstructured grid generation methods.	2
T-W-11	Benchmarking and calibration.	1
		30

Obciążenie pracą studenta - formy aktywności

KOD	Forma aktywności	Godziny
laboratoria
A-L-1	Class participation	30
A-L-2	One-on-One Teaching Consultations	30
		60
wykłady
A-W-1	Class participation	30
A-W-2	One-on-One Teaching Consultations	30
		60

Metody nauczania / narzędzia dydaktyczne

KOD	Metoda nauczania / narzędzie dydaktyczne
M-1	activating methods: lecture and didactic discussion
M-2	practical methods - numerical/simulation study

Sposoby oceny

KOD	Sposób oceny
S-1	Ocena formująca: assessment of progress of the work - monthly
S-2	Ocena podsumowująca: written final report
S-3	Ocena podsumowująca: written final test/report

Zamierzone efekty kształcenia - wiedza

Zamierzone efekty kształcenia	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
WM-WTiICh_2-_null_W01 Student understands mathematical characteristics of partial differential equations. Student understands basic properties of computational methods – accuracy, stability, consistency Student learns computational solution techniques for time integration of ordinary differential equations Student learns computational solution techniques for various types of partial differential equations	—	—	C-1	T-W-1, T-W-9, T-W-6, T-W-5, T-W-11, T-L-1, T-W-2, T-W-4, T-W-3, T-W-10, T-W-7, T-W-8	M-1	S-3, S-1

Zamierzone efekty kształcenia - umiejętności

Zamierzone efekty kształcenia	Odniesienie do efektów kształcenia dla kierunku studiów	Odniesienie do efektów zdefiniowanych dla obszaru kształcenia	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
WM-WTiICh_2-_null_U01 Student posseses an abillity to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB Student posseses an abillity to analize, solve problem by using commercial software	—	—	C-1	T-L-9, T-L-7, T-L-11, T-L-1, T-L-10, T-L-3, T-L-8, T-L-6, T-L-5, T-L-2, T-L-4	M-2	S-3, S-1

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	Cel przedmiotu	Treści programowe	Metody nauczania	Sposób oceny
WM-WTiICh_2-_null_K01 Student has ability independently or in group to use of specialized software, solving and analyzing processes of mass transfer, momentum and energy	—	—	C-1	T-W-3, T-L-1, T-L-2, T-W-4, T-L-4, T-W-8, T-L-7, T-W-10, T-L-6, T-L-9, T-W-1, T-L-3, T-W-7, T-W-2, T-L-8, T-W-5, T-L-5, T-L-10, T-W-6, T-W-9, T-L-11, T-W-11	M-1, M-2	S-3, S-1

Kryterium oceny - wiedza

Efekt kształcenia	Ocena	Kryterium oceny
WM-WTiICh_2-_null_W01 Student understands mathematical characteristics of partial differential equations. Student understands basic properties of computational methods – accuracy, stability, consistency Student learns computational solution techniques for time integration of ordinary differential equations Student learns computational solution techniques for various types of partial differential equations	2,0
	3,0	Student is able to formulate a simple transport task of momentum, heat and mass, design and carry out numerical simulations of the selected system geometry in a reproductive way.
	3,5
	4,0
	4,5
	5,0

Kryterium oceny - umiejętności

Efekt kształcenia	Ocena	Kryterium oceny
WM-WTiICh_2-_null_U01 Student posseses an abillity to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB Student posseses an abillity to analize, solve problem by using commercial software	2,0
	3,0	Student is able to formulate a simple transport task of momentum, heat and mass, design and carry out numerical simulations of the selected system geometry in a reproductive way.
	3,5
	4,0
	4,5
	5,0

Kryterium oceny - inne kompetencje społeczne i personalne

Efekt kształcenia	Ocena	Kryterium oceny
WM-WTiICh_2-_null_K01 Student has ability independently or in group to use of specialized software, solving and analyzing processes of mass transfer, momentum and energy	2,0
	3,0	Student is able to formulate a simple transport task of momentum, heat and mass, design and carry out numerical simulations of the selected system geometry in a reproductive way.
	3,5
	4,0
	4,5
	5,0

Literatura podstawowa

Hirsch, C, Numerical Computation of Internal and External Flows, Butterworth Heinemann, 2007
Pletcher, R. H., Tannehill, J. C., Anderson, D., Computational Fluid Mechanics and Heat Transfer, CRC Press, 2011
Moin, P., Fundamentals of Engineering Numerical Analysis, Cambridge University Press, 2010

Literatura dodatkowa

Ferziger, J. H., Numerical Methods for Engineering Application, Wiley, 1998
Ferziger, J. H., Peric, M., Computational Methods for Fluid Dynamics, Springer, 2002

Treści programowe - laboratoria

KOD	Treść programowa	Godziny
T-L-1	Introduction to Computational Fluid Dynamics in ANSYS Workbench. Graphical User Interface	1
T-L-2	Creating the geometry in ANSYS DesignModeler	5
T-L-3	Generation of mesh in ANSYS Mesher	4
T-L-4	Introduction to CFD simulations in ANSYS Fluent. Definition of materials of the object and boundary conditions for fluid flow	2
T-L-5	Postprocessing in ANSYS Fluent	2
T-L-6	Analysis of a laminar flow in ANSYS Fluent	2
T-L-7	Applying turbulence model in ANSYS Fluent	2
T-L-8	Analysis of a heat transfer in ANSYS Fluent	2
T-L-9	Simulation of multiphase flow in ANSYS Fluent	2
T-L-10	Modeling of rotating elements in fluent (e.g. rotating wall, multiple reference frame, sliding mesh)	2
T-L-11	Modeling of a selected issue including creating the geometry, generating the mesh, performing the simulations and postprocessing	6
		30

Treści programowe - wykłady

KOD	Treść programowa	Godziny
T-W-1	Illustration of the CFD approach; CFD as an engineering analysis tool	2
T-W-2	Introduction to numerical methods for Euler and Navier-Stokes equations with emphasis on error analysis, consistency, accuracy and stability	6
T-W-3	Finite difference methods, finite volume and spectral element methods. Explicit vs. implicit time stepping methods	4
T-W-4	Methodology of solving CFD problems	2
T-W-5	Coupling of velocity and pressure fields	2
T-W-6	Computation of turbulent flows	4
T-W-7	Multiphase flows and their modelling	4
T-W-8	Structured and unstructured grids	1
T-W-9	Structured grid generation methods.	2
T-W-10	Unstructured grid generation methods.	2
T-W-11	Benchmarking and calibration.	1
		30

Formy aktywności - laboratoria

KOD	Forma aktywności	Godziny
A-L-1	Class participation	30
A-L-2	One-on-One Teaching Consultations	30
		60

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

Formy aktywności - wykłady

KOD	Forma aktywności	Godziny
A-W-1	Class participation	30
A-W-2	One-on-One Teaching Consultations	30
		60

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

Pole	KOD	Znaczenie kodu
Zamierzone efekty kształcenia	WM-WTiICh_2-_null_W01	Student understands mathematical characteristics of partial differential equations. Student understands basic properties of computational methods – accuracy, stability, consistency Student learns computational solution techniques for time integration of ordinary differential equations Student learns computational solution techniques for various types of partial differential equations
Cel przedmiotu	C-1	Specific objectives may be summarized as: • To understand mathematical characteristics of partial differential equations. • To understand basic properties of computational methods – accuracy, stability, consistency • To learn computational solution techniques for time integration of ordinary differential equations • To learn computational solution techniques for various types of partial differential equations • To learn how to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB
Treści programowe	T-W-1	Illustration of the CFD approach; CFD as an engineering analysis tool
	T-W-9	Structured grid generation methods.
	T-W-6	Computation of turbulent flows
	T-W-5	Coupling of velocity and pressure fields
	T-W-11	Benchmarking and calibration.
	T-L-1	Introduction to Computational Fluid Dynamics in ANSYS Workbench. Graphical User Interface
	T-W-2	Introduction to numerical methods for Euler and Navier-Stokes equations with emphasis on error analysis, consistency, accuracy and stability
	T-W-4	Methodology of solving CFD problems
	T-W-3	Finite difference methods, finite volume and spectral element methods. Explicit vs. implicit time stepping methods
	T-W-10	Unstructured grid generation methods.
	T-W-7	Multiphase flows and their modelling
	T-W-8	Structured and unstructured grids
Metody nauczania	M-1	activating methods: lecture and didactic discussion
Sposób oceny	S-3	Ocena podsumowująca: written final test/report
Sposób oceny	S-1	Ocena formująca: assessment of progress of the work - monthly
Kryteria oceny	Ocena	Kryterium oceny
	2,0
	3,0	Student is able to formulate a simple transport task of momentum, heat and mass, design and carry out numerical simulations of the selected system geometry in a reproductive way.
	3,5
	4,0
	4,5
	5,0

Pole	KOD	Znaczenie kodu
Zamierzone efekty kształcenia	WM-WTiICh_2-_null_U01	Student posseses an abillity to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB Student posseses an abillity to analize, solve problem by using commercial software
Cel przedmiotu	C-1	Specific objectives may be summarized as: • To understand mathematical characteristics of partial differential equations. • To understand basic properties of computational methods – accuracy, stability, consistency • To learn computational solution techniques for time integration of ordinary differential equations • To learn computational solution techniques for various types of partial differential equations • To learn how to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB
Treści programowe	T-L-9	Simulation of multiphase flow in ANSYS Fluent
	T-L-7	Applying turbulence model in ANSYS Fluent
	T-L-11	Modeling of a selected issue including creating the geometry, generating the mesh, performing the simulations and postprocessing
	T-L-1	Introduction to Computational Fluid Dynamics in ANSYS Workbench. Graphical User Interface
	T-L-10	Modeling of rotating elements in fluent (e.g. rotating wall, multiple reference frame, sliding mesh)
	T-L-3	Generation of mesh in ANSYS Mesher
	T-L-8	Analysis of a heat transfer in ANSYS Fluent
	T-L-6	Analysis of a laminar flow in ANSYS Fluent
	T-L-5	Postprocessing in ANSYS Fluent
	T-L-2	Creating the geometry in ANSYS DesignModeler
	T-L-4	Introduction to CFD simulations in ANSYS Fluent. Definition of materials of the object and boundary conditions for fluid flow
Metody nauczania	M-2	practical methods - numerical/simulation study
Sposób oceny	S-3	Ocena podsumowująca: written final test/report
Sposób oceny	S-1	Ocena formująca: assessment of progress of the work - monthly
Kryteria oceny	Ocena	Kryterium oceny
	2,0
	3,0	Student is able to formulate a simple transport task of momentum, heat and mass, design and carry out numerical simulations of the selected system geometry in a reproductive way.
	3,5
	4,0
	4,5
	5,0

Pole	KOD	Znaczenie kodu
Zamierzone efekty kształcenia	WM-WTiICh_2-_null_K01	Student has ability independently or in group to use of specialized software, solving and analyzing processes of mass transfer, momentum and energy
Cel przedmiotu	C-1	Specific objectives may be summarized as: • To understand mathematical characteristics of partial differential equations. • To understand basic properties of computational methods – accuracy, stability, consistency • To learn computational solution techniques for time integration of ordinary differential equations • To learn computational solution techniques for various types of partial differential equations • To learn how to computationally solve Euler and Navier-Stokes equations by using commercial software ANSYS FLUENT, Open Foam, MATLAB
Treści programowe	T-W-3	Finite difference methods, finite volume and spectral element methods. Explicit vs. implicit time stepping methods
	T-L-1	Introduction to Computational Fluid Dynamics in ANSYS Workbench. Graphical User Interface
	T-L-2	Creating the geometry in ANSYS DesignModeler
	T-W-4	Methodology of solving CFD problems
	T-L-4	Introduction to CFD simulations in ANSYS Fluent. Definition of materials of the object and boundary conditions for fluid flow
	T-W-8	Structured and unstructured grids
	T-L-7	Applying turbulence model in ANSYS Fluent
	T-W-10	Unstructured grid generation methods.
	T-L-6	Analysis of a laminar flow in ANSYS Fluent
	T-L-9	Simulation of multiphase flow in ANSYS Fluent
	T-W-1	Illustration of the CFD approach; CFD as an engineering analysis tool
	T-L-3	Generation of mesh in ANSYS Mesher
	T-W-7	Multiphase flows and their modelling
	T-W-2	Introduction to numerical methods for Euler and Navier-Stokes equations with emphasis on error analysis, consistency, accuracy and stability
	T-L-8	Analysis of a heat transfer in ANSYS Fluent
	T-W-5	Coupling of velocity and pressure fields
	T-L-5	Postprocessing in ANSYS Fluent
	T-L-10	Modeling of rotating elements in fluent (e.g. rotating wall, multiple reference frame, sliding mesh)
	T-W-6	Computation of turbulent flows
	T-W-9	Structured grid generation methods.
	T-L-11	Modeling of a selected issue including creating the geometry, generating the mesh, performing the simulations and postprocessing
	T-W-11	Benchmarking and calibration.
Metody nauczania	M-1	activating methods: lecture and didactic discussion
Metody nauczania	M-2	practical methods - numerical/simulation study
Sposób oceny	S-3	Ocena podsumowująca: written final test/report
Sposób oceny	S-1	Ocena formująca: assessment of progress of the work - monthly
Kryteria oceny	Ocena	Kryterium oceny
	2,0
	3,0	Student is able to formulate a simple transport task of momentum, heat and mass, design and carry out numerical simulations of the selected system geometry in a reproductive way.
	3,5
	4,0
	4,5
	5,0