Practical Applications of CFD (FSI-K20)

Academic year 2021/2022
Supervisor: doc. Ing. Vojtěch Turek, Ph.D.  
Supervising institute: ÚPI all courses guaranted by this institute
Teaching language: Czech
Aims of the course unit:
The objective of the course is to provide hands-on experience in solution of various types of problems that are typical of CFD and its industrial application.
Learning outcomes and competences:
The students will get acquainted with the complete process of setting up and solving fluid flow problems using commercial software ANSYS Fluent. They will learn about various methods and ways to construct the geometry, create computational grids, define boundary conditions, and choose appropriate models for specific CFD problems. They will gain experience in computational modelling of various types of problems encountered in engineering practice, including the overlap with multiphysics problems.
Prerequisites:
It is recommended that the students have passed the “CFD modelling I (K10)” course.
Course contents:
The course provides an introduction to the usage of a commercial CFD software and a brief introduction to solving various types of computational problems in engineering. During the course, the students will learn about the creation of flow domain geometry and computational grid, the ways to set boundary conditions and select appropriate computational models, as well as about setting up various parameters in a simulation, monitoring and running computation, and evaluating the results. The problems discussed in the course include 2D and 3D cases, convection, heat transfer, and transient computations. The seminars are held in a computer laboratory and a main part of the course consists of independent work on practical problems. The students will learn to use the ANSYS software suite, namely SpaceClaim for geometry modelling, ANSYS Meshing and Fluent Meshing for grid generation, ANSYS Fluent for the solution, and CFD-Post for the analysis of results.
Teaching methods and criteria:
The course is taught via seminars focused on acquiring practical skills.
Assesment methods and criteria linked to learning outcomes:
Credits will be awarded upon successful completion of a technical report on the solution of a specific computational problem. The report must contain the description of the problem, overview of the employed methods and solution steps (including the settings of boundary conditions), as well as the summary and analysis of results in both graphical and alphanumeric form.
Controlled participation in lessons:
Credits will be awarded only to students who have regularly participated in the seminars, i.e., in at least two thirds of them (9 out of the total 13).
Type of course unit:
    Computer-assisted exercise  13 × 3 hrs. compulsory                  
Course curriculum:
    Computer-assisted exercise 1. Creation of geometry and grid generation for 2D problems.
2. Setting up boundary conditions, selection of appropriate models for 2D flow computations (laminar and turbulent), carrying out computation and analysis of results.
3. Creation of geometry and grid generation for 3D problems.
4. Setting up boundary conditions and models for 3D flow problems, carrying out computation and analysis of results.
5. Assignment of individual project – simulation of a 3D tubular heat exchanger, advanced geometry manipulations for CFD problems.
6. Grid generation for the computation of a 3D heat exchanger.
7. Setting up and carrying out flow simulation including heat transfer in the 3D heat exchanger.
8. Creation of geometry and grid generation for 2D transient problem of flow around a cylinder.
9. Carrying out transient simulation of turbulent flow around a cylinder, generating von Karman vortex street.
10. Analysis of results of the transient flow around cylinder, frequency analysis
11. Parametrisation of problems, optimisation in CFD computations.
12. Fluid-structure interaction (FSI) – setting up and transfer of data between ANSYS Fluent and ANSYS Mechanical.
13. Course summary, overview of the models recommended for engineering CFD applications.
Literature - fundamental:
2. Wilcox, D. C.: Turbulence Modeling for CFD, 3rd ed. DCW Industries, Inc., La Cañada, CA, USA (2006)
3. Menter, F. R.; Lechner, R.; Matyushenko, A.: Best Practice: RANS Turbulence Modeling in Ansys CFD. ANSYS, Inc., Canonsburg, PA, USA (2022)
Literature - recommended:
2. Dahlquist, G.; Björck, Å.: Numerical Methods. Dover Publications, Mineola, NY, USA (2003)
The study programmes with the given course:
Programme Study form Branch Spec. Final classification   Course-unit credits     Obligation     Level     Year     Semester  
N-PRI-P full-time study --- no specialisation -- Cr 3 Compulsory-optional 2 2 W