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Computational Fluid Dynamics (CFD)

This is the study programme for 2020/2021.

Computational fluid dynamics (CFD) lets us solve the governing equations for fluid dynamics for complex engineering problems. CFD is today used in a wide range of industries, some examples are:
  • air resistance for airplanes and cars
  • wind and wave loads on buildings and marine structures
  • heat- and mass transfer in chemical processing plants
  • consequence modelling of fires and explosions in the oil- and gas industry

In this course you will get an introduction to computational fluid dynamics. The first part of the course deals with fundamental theory and numerical methods. The second part of the course introduces use of the practical CFD software OpenFOAM. The course ends with a group project where you select a problem of your own choice to simulate in OpenFOAM.

Learning outcome

The students shall
  • know the governing equations for fluid dynamics, and how these can be described as a general transport equation
  • know the properties of the finite volume method for discretizing transport equations
  • know the fundamental discretization schemes for each term of the transport equation
  • know the most common methods for treating the coupled flow problem
  • know the most common models for turbulent flow
  • be able to discuss advantages and disadvantages of different choices of solution methods and models

The students shall be able to
  • perform the discretization of all the terms in the transport equation with the finite volume method
  • implement numerical methods to solve transport equations in the Python programming language
  • perform simulations in the CFD software OpenFOAM; create simulation mesh, select initial- and boundary conditions, discretization schemes and solution methods and visualize the results
  • compare simulations against analytical and experimental results

General qualifications
The students shall be able to
  • simplify practical problems to make them amenable for analysis with appropriate scientific methods
  • visualize and present data from simulations in a scientific manner
  • interpret results from simulations and evaluate accuracy and uncertainty
  • collaborate in groups to carry out a project work

Required prerequisite knowledge


Recommended previous knowledge

FYS200 Thermo- and Fluid Dynamics, MAT300 Vector Analysis


Written exam and report
Weight Duration Marks Aid
Assignment1/2 A - F
Written exam1/23 hoursA - FNone permitted

Course teacher(s)

Course coordinator
Knut Erik Teigen Giljarhus
Course teacher
Knut Erik Teigen Giljarhus
Head of Department
Tor Henning Hemmingsen

Method of work

8 hours of lectures/tutorials a week in the start of the semester (first 5-6 weeks) and 1-2 hours of project supervision in the rest of the semester. Mandatory project work to be carried out in groups of 2-3 students.

Overlapping courses

Course Reduction (SP)
Heat transfer and CFD (MOM430_1) 5

Open to

Environmental Engineering - Master of Science Degree Programme
Engineering Structures and Materials - Master's Degree Programme
Marine- and Offshore Technology - Master's Degree Programme

Course assessment

Through evaluation form and/or discussion according to current regulations.


Literatur will be published as soon as it has been prepared by the course coordinator/teacher

This is the study programme for 2020/2021.

Sist oppdatert: 05.08.2020