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This is the study programme for 2019/2020. It is subject to change.

The course gives an advanced mathematical description and analysis of fluid flow. The main emphasis will be on analytical solution methods.

### Learning outcome

The student shall have knowledge of the physics and the mathematical formalism for the description of fluids in order to be able to read and understand the technical literature in the field, and shall be able to make simple calculations of velocity, pressure, temperature and shear stress for incompressible viscous flow. Furthermore, the student shall have knowledge of important phenomena of advanced fluid dynamics, like flow regimes, boundary layers, instabilities and the transition to turbulent flow as well as basic CFD.

### Contents

Mathematical description of fluid motion, Navier-Stoke's and energy equations and their solutions, flow regimes: Stokes' flow and potential flow. Lift and drag. Laminar boundary layers. Flow separation and attachment, Instability and the transition to turbulent flow. Turbulent boundary layers. Short introduction to CFD.

None.

### Recommended previous knowledge

FYS200 Thermo- and Fluid Dynamics, MAT300 Vector Analysis

### Exam

Weight Duration Marks Aid
Written exam1/13 hoursA - FCompilation of mathematical formulae (Rottmann).

### Course teacher(s)

Course coordinator
Knut Erik Teigen Giljarhus
Tor Henning Hemmingsen

### Method of work

Four hours of lectures/problem solving weekly. Language of teaching and exam is English.

### Overlapping courses

Course Reduction (SP)
Fluid dynamics (MPT130_1) 4

### Open to

Master studies at the Faculty of Science and Technology

### Course assessment

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

### Literature

Y.A. Cengel, J.M. Cimbala: Fluid mechanics: Fundamentals and applications, Third Edition in SI units, McGraw Hill, 2014. Chapters 1,2,4,9,10,15. Lecture notes.

This is the study programme for 2019/2020. It is subject to change.

Sist oppdatert: 20.08.2019