Subject Datasheet

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Budapest University of Technology and Economics
Faculty of Transportation Engineering and Vehicle Engineering
1. Subject name Numerical Methods for Fluid Flows II.
2. Subject name in Hungarian Numerikus módszerek az áramlástanban II.
3. Code BMEKORHD002 4. Evaluation type exam grade 5. Credits 2
6. Weekly contact hours 2 (0) Lecture 0 (0) Practice 0 (0) Lab
7. Curriculum
PhD Programme
 8. Role
Specific course
9. Working hours for fulfilling the requirements of the subject 28
Contact hours 28 Preparation for seminars 0 Homework 0
Reading written materials 0 Midterm preparation 0 Exam preparation 0
10. Department Department of Aeronautics and Naval Architectures
11. Responsible lecturer Dr. Veress Árpád
12. Lecturers Dr. Veress Árpád
13. Prerequisites strong: BMEKORHD006 - Numerical Methods for Fluid Flows I.
14. Description of lectures
Introduction to CFD (Computational Fluid Dynamics) via scientific and industrial applications, Numerical solution of the system of the Euler equations, Numerical solution of the system of the Navier-Stokes equations. (book by Hirsch II.)
15. Description of practices
 
16. Description of labortory practices
 
17. Learning outcomes
A. Knowledge
  • The student knows the different forms of the system of the Euler and Navier-Stokes equations, their numerical solutions and the developments of the Euler equations based inverse design method.
B. Skills
  • The student can perform and develop numerical discretizations and solutions of the Euler and Navier-Stokes equations. The student can complete Euler equation based inverse design method.
C. Attitudes
  • The student aims to complete his/her studies at the highest level, under the shortest time, by providing his/her knowledge and capacity at the best to obtain knowledge for deep and independent professional work.
  • The student has strong professional commitment, has developed expectations for finding new, better solutions and has agreement on doing hard work.
D. Autonomy and Responsibility
  • The student takes responsibility for guiding mates by the quality of his/her work and by keeping ethic norms.
  • The student takes responsibility for applying the knowledge in line with the studied conditions, limitations and constraints.
  • The student can friendly accept the well-established constructive criticism and can utilize that in future.
  • The student is a creative constructor, proactive, and has leadership skills and argument techniques, capabilities with responsibility during the studies, research work.
18. Requirements, way to determine a grade (obtain a signature)
The criterion of the acceptance of the semester and so getting the signature is the completeness of the solution of a defined problem in a specific area in the agreed time and quality. The exam is oral. The final mark of the exam is the mathematical average of the results for the own task and the exam.
19. Opportunity for repeat/retake and delayed completion
 
20. Learning materials
1. The presentation about the lectures, simulation guide lines and tutorials provided by the professor,
2. Hirsch, Charles: Numerical Computation of Internal and External Flows, Volume 1 and 2, ISBN-10: 0471923850, ISBN-13: 978-0471923855, John Wiley and Sons (2001), 3. Veress, Á.: Introduction to CFD, BME, Department of Aeronautics, Naval Architecture and Railway Vehicles, Lecture notes, (2002), 4. ANSYS, Inc., ANSYS CFX-Solver Theory Guide, Release 2019 R1, ANSYS, Inc. Southpointe, 2600 ANSYS Derive Canonsburg, PA15317, ansysinfo@ansys.com, http://www.ansys.com, USA, 2019. 5. Veress, Á. and Rohács, J.: Application of Finite Volume Method in Fluid Dynamics and Inverse Design Based Optimization, DOI: 10.5772/38786, ISBN 978-953-51-0445-2 (2012)
http://www.intechopen.com/books/finite-volume-method-powerful-means-of-engineering-design/application-of-finite-volume-method-in-fluid-dynamics-and-inverse-design-based-optimization
Effective date 27 November 2019 This Subject Datasheet is valid for Inactive courses