Francois Marechal, Industrial Energy Systems Laboratory, EPFL

Process integration
Teaching in EPFL
Prof. François Marechal
Institute of Mechanical Engineering
School of Engineering
Ecole Polytechnique Fédérale de Lausanne
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
Mech. Eng. curriculum in EPFL
• 3 years Bachelor : 180 ECTS
– Mech eng.
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
• Physics
• Thermo I and Thermo II
• Heat transfer
• Hydraulic and turbo machines
• 2 year Master : 120 ECTS
– Orientation : energy (all lecture optional, at least 34
ECTS in mech. eng. program)
– inc. projects 20 ECTS
– inc. Master thesis : 30 ECTS
• Industrial internship : 2 to 6 months
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
sem I
autumn
sem II
spring
sem III
autumn
sem IV
Master Cursus
Mechanical Eng.
Electrical Eng.
Environment Eng.
Physics Eng.
Chemical Eng.
Material Eng.
60 ECTS
Minor
Cursus
20 ECTS
Eng. Project
10 ECTS
Industrial Internship
Master in Eng. in EPFL - Minor in
Energy Organisation
Bachelor in eng. : 3 years or 180 ECTS
Master Thesis
90 ECTS
30 ECTS
Ph D program : 4 years
1 ECTS = 1h teaching/week/semester + 1h personal work/week/semester
1 semester = 14 weeks
Minor in Energy : the concept
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
• In addition to Major master diploma
– specialisation/complement
– multi disciplinary
• Total 120 credits / 4 semesters
– 90 master + 30 minor
•30 credits = 10 cr. projects + 20 cr. courses
•20 credits to be selected in the proposed study
plan
SEL-SGM-SMT-SMX
Mineur en Énergie
Les enseignants, les crédits et la période des cours sont indiqués sous réserve de modification.
Matières
Période
2
Enseignants
Livret des cours
Crédits
des
cours
http://sti.epfl.ch ->Mech. eng. ->Master -> Minor Energy
Mineur "Énergie"
87
Aménagements hydrauliques II
Schleiss
Barrages et ouvrages hydrauliques annexes
Schleiss
Énergétique du bâtiment
Modélisation des systèmes Energie et Transport
GC
GC
3
3
P
GC/AR
Bierlaire/Gnansounou
GC
GC
3
P
PH
4
A
PH
Plasma physics II
Fasoli
Plasma physics III
Lister
3
A
Gnansounou/Morel N.
Boillat/Haldi
Réseaux hydrauliques et énergétiques
3
A
A
4
P
Électronique industrielle I
Rufer
EL
2
A
Électronique industrielle II
Rufer
EL
2
P
– Pre-requisite to be organised within the
major program
Optimisation des réseaux
vacat
Régimes transitoires des machines électriques
Simond
Systèmes d'électronique de puissance et entraînements
Rufer/Simond
Systèmes hybrides
Simond/Perriard/Rufer
Advanced solid waste treatment
Ludwig
EL
EL
3
3
P
A
EL
2
P
EL/MT
3
A
SIE
4
A
Climate and climate change
Bey
SIE
2
P
Écologie industrielle
Erkmann
SIE
3
A
Chemical engineering of heterogenous reactions
Kiwi L.
CGC
3
A
Génie électrochimique
Comninellis/Foti
Process development I, II
3
P
4
A+P
Favrat/Maréchal/Gafner
GM
4
A
Favrat/van Herle/Chawla
GM/PH
4
P
Zaza
Advanced energetics and engines
1
Advanced energy conversion technologies
1
CGC
CGC
Energy conversion
Favrat / Maréchal / Van Herle
GM
2
P
Introduction aux turbomachines
Avellan/Ott
GM
2
P
Modélisation et optimisation de systèmes énergétiques
Maréchal
GM
2
Thome
GM
4
A
Divers enseignants
STI
12
A ou P
Two-phase flows and heat transfer
P
Projet obligatoire du mineur en Énergie
Projet en Énergie
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
2
1
Ces cours ne peuvent pas être pris simultanément
2
Les professeurs proposant les projets du mineur proposent une liste de cours à option recommandés
ric
i ty
ct
Ele
Emissions
Pollution control
environmental impact
Ph
ys
i cs
al
t
n
e
m
n
ro ering
i
v
En gine
en
Master degree
al
nic
cha ring
Me inee
g
en
Production
Distribution
Conversion
Storage
Turbo-machines
Catalysis
Energy conversion cycles
Process Design project
Combustion/Engines
Fuel cells
Chemistry and
Renewable energy
Chem. eng.
Process System
Engineering
Civil engineering
Plasma,
Nuclear
Fusion
Buildings, Dams, Transportation, infrastructure
Process system engineering in the energy minor
• Master programs / Minor
– Advanced energetics (5 ECTS highly recommended)
•Process integration
– Pinch analysis
– Energy conversion integration
– Heat exchanger network design
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
• Exergy Analysis
– Exergy Losses
– Heat transfer requirement definition
– Energy system modeling and optimisation ( 4 ECTS)
• Energy conversion process modeling
• Stating optimisation problems
• Solving optimisation problems
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
Advanced energetics (5ECTS) : teaching strategy
• Ex cathedra lecture : 2 ECTS
– On-line videos of the session
– Exercice
– Teaching materials => own lecture note
– Other materials => informative
• Project : solve a process integration problem (3 ECTS)
– Similar problem for each group from the food industry
– group work (7 studs max)
– use of simplified web based tools (mainly targeting)
– make a report
• Exam :
– Poster presentation
– 20 min oral examination on theory
• Population :Year 2002 : 15-20,Year 2012 : 70
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
Energy system modeling and optimisation (4 ECTS)
• Ex cathedra lecture : 2 ECTS
– On-line videos of the session (http://klewel.com/conferences/epfl-advancedenergetics/index.php?talkID=6 )
– Exercice
– Teaching materials => reference books + own slides
– Other materials => informative
• Project : solve an energy conversion system design problem (2 ECTS)
– design a hybrid SOFC-GT system for use in a car powertrain
– group work (5 studs max)
– use of matlab based code (OSMOSE) & Belsim-Vali flowsheeting
– make a report and present the results
• Exam :
– Poster presentation
– 20 min oral examination on theory
• Population :Year 2002 : 10,Year 2012 : 60
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
Engineering project : 10 ECTS
• Goal :
– Apply the techniques students have learned to solve a problem
• Project realisation
– state the problem
– apply the methods : solve the problem
– evaluate the results
• Write a report
• Present the results
• Opportunities
– Link with PhD research projects
– Link with the industry
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)
Doctoral school program
[email protected] ©Industrial Energy Systems Laboratory- LENI-IGM-STI-EPFL 2012
• Modeling and optimisation of integrated energy
systems (2 ECTS)
– Application of mathematical programming
techniques
– Process system design
•Thermo-economic optimisation
•Decomposition techniques
•multi-period problems and optimal predictive control
– Application of LCA for environmental
performance assessment
International Process Integration Jubilee conference
Gothenburg, March 18-20, 2013)