5.00 credits
Q1
Language
English
Prerequisites
A relevant course about introduction to nuclear energy
Fundamental of fluid mechanics, heat transfer, thermodynamic
Fundamental of fluid mechanics, heat transfer, thermodynamic
Learning outcomes
At the end of this learning unit, the student is able to : | |
1 |
|
Content
- Thermal design principles/reactor heat generation
- Reminders about single phase transport equations (prerequisite)
- Two-phase flow models, transport equations
- Thermodynamic (vessels/pressurizer) and power conversion cycle (steam)
- Heat transfer analysis in a fuel element
- Reminders about single phase fluid mechanics and heat transfer (prerequisite)
- Two-phase fluid mechanics and pressure drops
- Two-phase heat transfer (pool boiling, flow boiling)
- ·Single heated channel (thermal and flow problems)
- Flow loops (steady state natural convection)
Teaching methods
- 2 t.m.: 40h teaching + seminar and 15h practical works in classroom
- SCK.CEN guidance for demonstrations with codes
- SCK.CEN + UCL TA for practical works
Evaluation methods
The final mark is composed of (i) a written exam(80%, closed book)including an exercise and a theoretical part, and (ii) the mini-project(20%).
Other information
Yann BARTOSIEWICZ yann.bartosiewicz@uclouvain.be
Professor at the Université Catholique de Louvain (UCL, Louvain-la-Neuve)
Master in Turbulence modeling and Transfer Phenomena, Ecole Nationale Polytechnique de Grenoble, France, 1998.
PhD in Mechanical engineering, Université de Sherbrooke, Canada, 2003: Modeling of supersonic plasma jets in non-Local Thermodynamics Equilibrium
Research fields: Fluid mechanics, heat transfer, compressible flows, two-phase flows, thermodynamics, computational fluid dynamics
Teaching duties in BNEN: Nuclear Thermal Hydraulics
Other research activities: scientific leader for UCL in European projects in nuclear thermal-hydraulics:
NURESIM: CFD Simulation of instabilities in a stratified two-phase flows relevant to PTS scenario NURISP: Simulation of two-phase chocked flows during LOCA: implementation of non-equilibrium models in CATHARE 3
THINS: Direct and Large Eddy Simulation (DNS/LES) of convective heat transfer for low Prandtl fluids (Liquid metals)
UCL Promotor of other projects in energy
Other duties: Member of the CFD group at OECD, Member of the European Nuclear Engineering Network (ENEN)
Professor at the Université Catholique de Louvain (UCL, Louvain-la-Neuve)
Master in Turbulence modeling and Transfer Phenomena, Ecole Nationale Polytechnique de Grenoble, France, 1998.
PhD in Mechanical engineering, Université de Sherbrooke, Canada, 2003: Modeling of supersonic plasma jets in non-Local Thermodynamics Equilibrium
Research fields: Fluid mechanics, heat transfer, compressible flows, two-phase flows, thermodynamics, computational fluid dynamics
Teaching duties in BNEN: Nuclear Thermal Hydraulics
Other research activities: scientific leader for UCL in European projects in nuclear thermal-hydraulics:
NURESIM: CFD Simulation of instabilities in a stratified two-phase flows relevant to PTS scenario NURISP: Simulation of two-phase chocked flows during LOCA: implementation of non-equilibrium models in CATHARE 3
THINS: Direct and Large Eddy Simulation (DNS/LES) of convective heat transfer for low Prandtl fluids (Liquid metals)
UCL Promotor of other projects in energy
Other duties: Member of the CFD group at OECD, Member of the European Nuclear Engineering Network (ENEN)
Online resources
Faculty or entity
EPL
Programmes / formations proposant cette unité d'enseignement (UE)
Title of the programme
Sigle
Credits
Prerequisites
Learning outcomes
Advanced Master in Nuclear Engineering