Module also offered within study programmes:
General information:
Name:
Advanced fluid mechanics
Course of study:
2019/2020
Code:
ZSDA-3-0109-s
Faculty of:
Szkoła Doktorska AGH
Study level:
Third-cycle studies
Specialty:
-
Field of study:
Szkoła Doktorska AGH
Semester:
0
Profile of education:
Academic (A)
Lecture language:
English
Form and type of study:
Full-time studies
Course homepage:
 
Responsible teacher:
dr hab. inż. Fornalik-Wajs Elżbieta (elaf@agh.edu.pl)
Dyscypliny:
inżynieria mechaniczna, inżynieria środowiska, górnictwo i energetyka
Module summary

The module develops and strengthens a knowledge regarding advanced fluid mechanics concepts and their applications in the real systems/processes analysis.

Description of learning outcomes for module
MLO code Student after module completion has the knowledge/ knows how to/is able to Connections with FLO Method of learning outcomes verification (form of completion)
Social competence: is able to
M_K001 understands the need of continuous selflearning and self-development; is able to be critical of own and published research results. SDA3A_K01 Participation in a discussion,
Oral answer,
Activity during classes
Skills: he can
M_U001 utilizes the knowledge to an analysis of the complex research problems. is able to make conclusions in the basis of results, be critical in their evaluation. SDA3A_U01 Participation in a discussion,
Oral answer,
Examination,
Activity during classes
M_U002 utilizes the knowledge in the scientific discussions. SDA3A_U05, SDA3A_U02 Participation in a discussion,
Oral answer,
Activity during classes
Knowledge: he knows and understands
M_W001 posseses extended knowledge, based on the fundamental Fluid Dynamics concepts. Utilizes it to an analysis of the real systems/processes and research problems being the scope of PhD thesis. SDA3A_W01 Participation in a discussion,
Oral answer,
Examination,
Activity during classes
Number of hours for each form of classes:
Sum (hours)
Lecture
Audit. classes
Lab. classes
Project classes
Conv. seminar
Seminar classes
Pract. classes
Zaj. terenowe
Zaj. warsztatowe
Prace kontr. przejść.
Lektorat
30 30 0 0 0 0 0 0 0 0 0 0
FLO matrix in relation to forms of classes
MLO code Student after module completion has the knowledge/ knows how to/is able to Form of classes
Lecture
Audit. classes
Lab. classes
Project classes
Conv. seminar
Seminar classes
Pract. classes
Zaj. terenowe
Zaj. warsztatowe
Prace kontr. przejść.
Lektorat
Social competence
M_K001 understands the need of continuous selflearning and self-development; is able to be critical of own and published research results. + - - - - - - - - - -
Skills
M_U001 utilizes the knowledge to an analysis of the complex research problems. is able to make conclusions in the basis of results, be critical in their evaluation. + - - - - - - - - - -
M_U002 utilizes the knowledge in the scientific discussions. + - - - - - - - - - -
Knowledge
M_W001 posseses extended knowledge, based on the fundamental Fluid Dynamics concepts. Utilizes it to an analysis of the real systems/processes and research problems being the scope of PhD thesis. + - - - - - - - - - -
Student workload (ECTS credits balance)
Student activity form Student workload
Summary student workload 97 h
Module ECTS credits 4 ECTS
Udział w zajęciach dydaktycznych/praktyka 30 h
Preparation for classes 30 h
Examination or Final test 2 h
Contact hours 5 h
Inne 30 h
Module content
Lectures (30h):

Fundamental concepts and definitions of Fluid Dynamics
Integral and differential forms of the mass, momentum and energy conservation laws
Approximate solutions of Navier-Stokes Equation
Boundary layer and its significance
Dimensional analysis
Compressible Flow
Elements of Computational Fluid Dynamics

Additional information
Teaching methods and techniques:
  • Lectures: The lecture contents is presented in the form of multimedial presentation in connection with the classical board lecture enriched with the display regarding particular problem. The knowledge is also transferred during the discussions moderated by the lecturer. Discussion is very important element of the classes.
Warunki i sposób zaliczenia poszczególnych form zajęć, w tym zasady zaliczeń poprawkowych, a także warunki dopuszczenia do egzaminu:

The participation in the written exam is allowed after getting the confirmed participation in the lectures (the exception is discussed in other section). There will be three terms of written exams after the classes. The positive grade is regulated by the AGH rules.

Participation rules in classes:
  • Lectures:
    – Attendance is mandatory: Yes
    – Participation rules in classes: Knowledge and understanding of previously realized material. Participation in the discussions. Asking the questions. Following the rules of PhD School regulations regarding the rights and obligations.
Method of calculating the final grade:

Weighted average rating =0.7· E ·w+0.3· A
where: E – exam rate, A – activity rate;
w – weight, w = 1 first term, w = 0.9 second term, w = 0.8 third term

Sposób i tryb wyrównywania zaległości powstałych wskutek nieobecności studenta na zajęciach:

One excused absence is allowed. The student is obliged to analyzed and understand realized content by himself/herself. If there is a special case it will be considered individually.

Prerequisites and additional requirements:

Knowledge regarding the fundamental Fluid Dynamics, differential and integral calculus, basics of Computational Fluid Dynamics.

Recommended literature and teaching resources:

1. Jeżowiecka-Kabsch K., Szewczyk H., Mechanika płynów, Oficyna Wydawnicza Politechniki
Wrocławskiej, Wrocław 2001
2. Duckworth R.A., Mechanika płynów, WNT, Warszawa 1983
3. Prosnak W., Mechanika płynów, PWN, Warszawa 1970
4. Gryboś R., Mechanika płynów, Politechnika Śląska, Gliwice 1991
5. White F.W. Fluid mechanics, Mc Graw Hill, 1985
6. Kundu K.P., Cohen I.M., Fluid mechanics, Elsevier, 2002
7. Elsner J.W., Turbulencja przepływów, PWN, 1987
8. Hinze J.O., Turbulence, Mc Graw-Hill, 1975
9. Cengel Y.A., Cimbala J.M., Fluid Mechanics, Fundamentals and Applications, Mc Graw-Hill, 2006

Scientific publications of module course instructors related to the topic of the module:

E. Fornalik-Wajs, Thermo-magnetic convection – method of the fluid flow and heat transfer control,
Paliwa i energia XXI wieku, Wydawnictwo Naukowe „Akapit”, Kraków, 199–224, 2014.
S. Kenjeres, L. Pyrda, E. Fornalik-Wajs, J.S. Szmyd, Numerical and experimental study of Rayleigh-
Bénard-Kelvin convection, Flow, Turbulence and Combustion, 92, 371–393, 2014.
S. Kenjeres, L. Pyrda, W. Wrobel, E. Fornalik-Wajs, J.S. Szmyd, Oscillatory states in thermal convection of
a paramagnetic fluid in a cubical enclosure subjected to a magnetic field gradient, Physical Review E;
85, pp. 046312-1–046312-8, 2012.
E. Fornalik, J. S. Szmyd (2007), Experimental investigations of jet flows, Journal of Theoretical and
Applied Mechanics, ISSN 1429-2955, Indeks 365238, no. 3, vol. 45, pp. 569-586.
E. Fornalik (2007), Flow patterns generated by a strong magnetic field, Journal of Theoretical and
Applied Mechanics, ISSN 1429-2955, Indeks 365238, no. 3, vol. 45, pp. 557-568.
E. Fornalik, J. S. Szmyd (2005), Turbulent heat transfer in a confined jet, Progress in Computational Fluid
Dynamics, vol. 5, Nos. 3/4/5, pp.136–143.
K. Nakabe, E. Fornalik, J. F. Eschenbacher, Y. Yamamoto, T. Ohta and K. Suzuki (2001), Interactions of
longitudinal vortices generated by twin inclined jets and enhancement of impingement heat transfer,
Int. J. Heat and Fluid Flow, vol. 22, pp. 287-292.

Additional information:

Listed topics represent only the scope of lecture, forming its basis. They shouldn’t be treated as the titles of particular classes.
Detailed rules for getting the credit of lecture are presented during the first class.
Other forms of student’s activity mean a self-studies on the topics analyzed during the lectures.