Le 11 octobre dernier, TWEED organisait une visite du centre de recherche Energyville, réunissant les forces de trois institutions de recherche dans l'énergie durable et les systèmes énergétiques intelligents, et de son tout nouveau bâtiment construit à Genk sur un ancien site minier. Découvrez les photos et les présentations de l'événement !

1. Cluster Technology of
Wallonia Energy, Environment
and sustainable Development
11 octobre 2016
@ Genk
Visite d’EnergyVille
→ réseaux intelligents
→ systèmes énergétiques Intelligents
→ systèmes thermiques
→ véhicules électriques
→ futur des marchés de l'énergie

2. PROGRAMME
• 10:00 Accueil & présentation d'Energyville
• 10h45 Le Cluster énergie en Flandre
• 11:30 Visite du bâtiment
• 12:00 Lunch & Networking

3. © EnergyVille
Research
into sustainable energy
and smart energy systems

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226/10/2016
Flemish energy research partnership by
KU Leuven
Electa
Building Physics
Mechanics
imec
Photovoltaic
Research
VITO
Energy Technology
Sustainable Cities

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326/10/2016
Flemish energy research by
EnergyVille

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426/10/2016
EnergyVille
Research – Development – Training – Industrial Innovation
For:
Industry
Public Entities
Expertise in sustainable energy
and intelligent energy systems
in the built environment
With:
Local partners
Regional partners
International
partners

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526/10/2016
EnergyVille: some figures
Employees >700 >6000 >3400
Revenues (Meuro) 146 815 363
PhD’s 70 >5000 250
“Employees” 200
Revenues (Meuro) 34
PhD’s 95

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626/10/2016
EnergyVille – embedded in a broad context

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EnergyVille
Connected in
an interconnected world

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Eindhoven
AkenLeuven
EnergyVille
Driving force behind the transition towards sustainable
energy supply
Stimulus for research, business development and jobs in
Genk
Central position in the European knowledge triangle
ELAt, Eindhoven, Leuven, Aken

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926/10/2016
Campus EnergyVille
Campus EnergyVille Thor Park,
Waterschei, Genk
With the support of:

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1026/10/2016
Campus EnergyVille Thor Park,
Waterschei, Genk
With the support of:
Campus EnergyVille

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1126/10/2016
15.000m² floor area
5.000m² lab infrastructure
200 desks
Parking lot : electrical vehicles
BREEAM excellence
LIVING LAB!
And by extension ‘regulation free area’
The Building

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1226/10/2016
Embedded in a local context

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1326/10/2016
Thor Park

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1426/10/2016
MenThor
An ecosystem:
Bring stakeholders
together
Visions on energy
 roadmaps
 experiments
Integrate research,
education
and entrepreneurship
AcceleraThor
Stimulate start-ups in
energy services and
technology
1. boost
entrepreneurship
2. Idea
 validated business
plan
(KIC InnoEnergy)
3. Upscaling
(LRM, …)
DemonstraThor
Integrate technology
and research
Offer a Living Lab
RegulationFreeArea
Thor Park Programme
Host teams @Thor
IncubaThor
Develop your
business
@Thor
MoThor
Host teams
@Thor
EnergyVille:
• Home Lab
• Battery Lab
• Matrix Lab
• Thermal Lab
• EV Lab
• Solar Lab
Thor:
• Buildings
• Smart Grid
• 4G Heat Network

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1526/10/2016
IncubaThor
Innovation in Energy
Business Incubator
Target: start-up companies
Building next
to Campus EnergyVille

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1626/10/2016

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1726/10/2016
IncubaThor
Innovation in Energy
Business Incubator
Target: start-up companies
Building next
to Campus EnergyVille

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1826/10/2016
Research into

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1926/10/2016
Energy Storage

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2026/10/2016
Interfaces for electrical storage
Battery Management
Technologies
Integration of Storage
Devices
Battery and storage
management evaluation
Related End Applications
Long Term Storage and
Conversion

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2126/10/2016
Charging
Economic models
Battery Research
Smart Grid Services
Electric vehicles

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2226/10/2016
Battery Management Technology
Insulation resistance
monitoring
Dynamic balancing
State of charge calculation
State of health calculation

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2326/10/2016
Research into

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Thermal Energy

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2526/10/2016
Carrier Application: 4th Generation Thermal Networks

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2626/10/2016
Main Objectives
Optimisation of Thermal Energy Systems
Advanced
Thermal Energy
Storage
Smart Control
Optimal Energy
Demand
Integration of
Energy
Conversion
Technologies
Create
Flexibility
Dynamic
Behaviour
Energy
Efficiency
RES
Integration
Storage
Solutions
Optimal
Interaction
Integrated
System
Cost
Efficiency

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2726/10/2016
Research Focus
Generic control systems for high and low temperature
district heating networks
Advanced control strategies, including forecasting &
self-learning
Creation of an IT platform suitable for analysis, sizing
and exploitation of thermal networks
(expanding IDEAS)
Cooling networks and
hybrid networks (interaction
with electric grid, gas, …)
Smart Control

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2826/10/2016
Research Focus
Intelligent substations
(smart) and bi-directional
Intelligent Substations for
low temperature
networks
Intelligent cladding
systems
Methodologies for
building characterisation.
Optimal Energy Demand

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2926/10/2016
Advanced Thermal Energy Storage
Research Focus
System integration: balancing / matching need,
location, size, design and type of thermal energy
storage in any specific system
State Of Charge (SOC) estimation methodologies
(water, PCM, BTES, building mass, cladding systems,
UTES, geothermal wells)
Compact/free form concepts for
thermal energy storage
Scouting long term thermal
storage solution

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3026/10/2016
Research Focus
Optimised design for
ORC/HP with increased
(electric and thermal)
efficiency
Characterisation of
dynamic behaviour of the
improved concepts to
define interaction with
the thermal network
Integration of Energy Conversion Technologies

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3126/10/2016
Project examples, living labs and demonstrators:
IWT SMART GEOTHERM:
optimal control of geothermal
systems in buildings
H2020 GEOTECH:
optimal control of hybrid
geothermal systems in buildings
KIC Energy Storage:
Development of an intelligent
control for UTES
IDEAS

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3226/10/2016
PhD portfolio
Characterization of energy usage on building level
Glenn Reynders (prof. Dirk Saelens, Johan Van Bael)
Improved ORC rankine cycles
Daniel Walraven (prof. William D'haeseleer, Ben Laenen)
Sarah Van Erdeweghe (prof. William D'haeseleer, Ben Laenen)
Interaction between grids / Hybrid networks
Wiet Mazairac (Johan Desmedt)
Integration of Thermal Storage in Distrcit Heating Networks
Bram VanderHeijden (prof. Lieve Helsen, Robbe Salenbien)
Options for long-term storage
Luca Scapino (Jan Diriken)
Topologies for storage integrated heat exchangers
Bart Peremans (prof. Tine Baelmans)
Thermochemical conversion of waste into high-quality synthesis gas: investigation
of plasma for tar cracking
(Prof. Lieve Helsen)

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3326/10/2016
Demos & Living Labs
Minewater, Heerlen
IWT Proeftuin project
‘De Schipjes’
small-scale thermal network
on THOR site, connected to
our Thermo Technical Lab
Concrete house, Olen
Eandis, BTES controller
Waste-to-Energy: Plasma Reactor
(KU Leuven), demo-site enhanced landfill mining (Group
Machiels)
Demonstration of ORC concepts on the geothermal power plant
on Balmatt-site of VITO, co-generating heat and electricity

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Research into
Electrical Systems

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Physical Integration of Renewable Energy Sources
HVDC
Technologies for
net services
Energy yield forecasting
Building Integrated
Photovoltaics
DC micro- and
nanogrids

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3626/10/2016
Large scale integration of RES (transmission)
Grid investments
Generation unit commitment
New operational modes for
systems
Grid code compliance
Control of RES to participate
in ancillary services
Maintaining system reliability
under uncertainty

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3726/10/2016
Distribution system support from distributed
generation
Unbalanced injections
Distributed and centralised control algorithms
Optimal grid configuration
Virtual Power Plants and storage integration
Protection
Smart(er) components
Asset management (ageing prediction)
Local integration of RES (distribution)

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3826/10/2016
Distribution system support from distributed
generation
Unbalanced injections
Distributed and centralised control algorithms
Optimal grid configuration
Virtual Power Plants and storage integration
Protection
Smart(er) components
Asset management (ageing prediction)
Local integration of RES (distribution)
Intraday Wind Balancing
Deviations between predicted and effectively produced
wind energy. Can demand response correct the
intraday imbalances in the energy supplier’s portfolio?
Transformer Ageing
Can demand response elongate the life span of the
distribution grid transformers?
Can we postpone investments in bigger transformers?
Line Voltage Control
Can demand response help to reduce over- and
undervoltages in the distribution grid?

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3926/10/2016
HVDC as enabling technology
New revival
Additional controllability in the power system
Offshore grid development
Long distance underground connections
Towards an HVDC supergrid

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4026/10/2016
Enhancing the value of photovoltaic energy
Short-term energy forecasting
Errors > 10%
Implications for producer, grid operator, …
Meteo
forecast
errors
Imperfect
PV plant
energy yield
models
PV plant
production
forecast
error

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4126/10/2016
PV System – resolution in 15 minutes
Proposed Model – resolution in 1 second
Enhancing the value of photovoltaic energy
Short-term energy forecasting

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4226/10/2016
≈
Power Electronic conversion
Storage
DC bus
(+380V/-380V)
DC/DC micro-converter (～ 300W)
DC/AC bidirectional inverter
with grid support
GRID
The DC nanogrid approach
Why DC nanogrids?
DC loads ↗: electronics, LED, electric vehicles, …
Advantages:
Area
Material cost
Reliability
Conversion losses
Emerging industrial
interest

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4326/10/2016
DC Nanogrids for PV
DC/DC micro-converters with high conversion ratio
DC/AC bidirectional conversion
Coordinated operation
Power Electronic conversion
The DC nanogrid approach

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4426/10/2016
Roof integration
(opaque
or semi-transparent)
Façade integration
(warm / cold)
Integration as
parapets and balconies
Sun shading elements
Towards Building-Integrated PV (BIPV)
Today: PV modules
‘added’ to buildings
typically on the roof
BIPV = multifunctional use
building component
generates electricity
Highly application-specific
solutions

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4526/10/2016
Drivers for façade-
integrated PV
Tall nearly zero energy
buildings
potential market 10x
GW/yr
Aesthetics
Lower overall cost:
building + PV
Towards Building-Integrated PV (BIPV)

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4626/10/2016
Back-contact (MWT) Si-PV
modules
Rooftop & rooftile
Improved aesthetics
Higher efficiency
Cost-effective Si-PV
Towards Building-Integrated PV (BIPV)
Demonstrators & facilities

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Towards Building-Integrated PV (BIPV)
Demonstrators & facilities
Organic PV
Façades
Semi-transparent
Color-on demand

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4826/10/2016
Testing and modelling
interation PV vs. Building
Hygrothermal & mechanical
Model validation
Lab validation
Towards Building-Integrated PV (BIPV)
Demonstrators & facilities

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PV Integration in the Built Environment
Integrated District Energy Assessment by Simulation
Modelica Library
Interaction with electrical or thermal loads & generators
Interaction with low-voltage distribution grid

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5026/10/2016
Research into
Market & Strategy

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5126/10/2016
Interoperability for future electricity markets
New concepts for
electricity markets
Interoperability
Communication
IT
Virtual Power Plants
Energy System Analysis
Living Labs

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5226/10/2016
Interoperability for future electricity markets
Energy market and business
modelling
Techno-economic assessment
of energy technology solutions
Smart grids/cities
Retailer Distribution
grid operator
Aggregator –
VPP – ESCO …
Technology
provider
Distributed
generation
Other
stakeholders
Prosumer
(industrial –
residential)
European Energy Markets

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5326/10/2016
Virtual Power Plants
Interoperability for future electricity markets
5
3
3
1
X
X
X
2
X
X
Westland
greenhouse
area
Rotterdam
district
heating
Hoogvliet
district heating
X
4
X
S
1
3
1
2
2
Shell
A
Energy resources in the port of Rotterdam

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Research into

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Cities in Transition

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Cities in transition
Building renovation
strategies
Energy district design
Sustainable building
concepts

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5726/10/2016
Building renovation strategies
Databases & tools to support retrofit decisions
Costs and effects over the full life cycle
Co-operation models / services

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5826/10/2016
Energy district design
Local energy & climate policy
Tools for innovative district
planning
Integration of renewable
energy : smart grids, district
heating and cooling
Smart city living labs

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5926/10/2016
Sustainable building concepts
Sustainability assessment
of building materials,
buildings and districts
Life cycle analyses and life
cycle costing
Support for innovative
building concepts – flexible
and adaptive design

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Domains of expertise
Control
Systems
Energy
Markets
Power
Electronics
ICT
Thermal
Systems
Power Grids
Building
Physics Photovoltaics
Geothermal
Energy

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6126/10/2016
Labs
Battery Testing Lab
Home Lab
Smart Grid Infrastructure
Lab
Thermo Technical Lab
Medium Voltage Lab
PV Metrology Lab
Matrix Lab

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6226/10/2016
Innovation chain
Early
research
Development Prototyping
Low volume
production
Transfer

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6326/10/2016
Cooperation possibilities
Success-
ful
Mission
Opera-
tions
System
Complete
&
Qualified
Opera-
tional
Demon-
stration
Demon-
stration
Valida-
tion in
Relevant
Environ-
ment
Valida-
tion in
Lab
Proof of
Concept
Techno-
logy
Concept
Basic
Principles
Academic Chair
Cooperation in publicly financed projects
Open Innovation
Mutual R&D project
Spin-off
Technology transfer
Contract Research
Technology Readiness Level

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More info?
Kris Baert kris.baert@energyville.be
Kris Boonen kris.boonen@energyville.be
Erik De Schutter erik.deschutter@energyville.be
Arnoud Lust arnoud.lust@energyville.be
Steven Van Deun steven.vandeun@energyville.be
Tatiana Pasquel Garcia tatiana.pasquelgarcia@vito.be
Philip Pieters philip.pieters@energyville.be

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SmarThor
Connecting Visions, Technology and Knowledge
Tweed
11 October 2016

68. confidential
2
SALK/ EFRO 936 : Towards a sustainable energy supply in cities
SolSThore
Building Integrated PV Systems
(BIPV)
Local battery storage
GeoWatt
4th generation thermal networks
Efficient use of deep geothermal
energy in thermal networks
SmarThor
Integrated Energy Networks &
Market Models
Communication

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2009 2011
2018 2025
Innovative Concepts
Simulation
Prototype in Lab
Demonstration
Technology
Smart Energy
Interactions
Interoperability
Eco-system
Users
Real life conditions
Interactions
Value <> effort
SmarThor … Smart + Thor: playground for research

70. confidential
Experiments in Living Labs
Join Forces:
Collect concerns
Combine strengths
Build an eco-system
Residential Demand Response
Technology integration System integration
value chain: 20 partners 250 participating families

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Experiments in Living Labs
Join Forces:
Collect concerns
Combine strengths
Build an eco-system
Gain insight:
Business opportunities
Residential Demand Response
©
Eandis
Line Voltage Control Transformer Ageing
Portfolio Management Intraday (Wind) Balancing

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Experiments in Living Labs
Join Forces:
Collect concerns
Combine strengths
Build an eco-system
Gain insight:
Business opportunities
Technical performance
User acceptance
Residential Demand Response
Time of Use Tariffs Smart Start
Technical Performance Business Potential

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7
SmarThor: connecting ideas and systems
Envisioning
bring stakeholders together
translate visions on energy,
to roadmaps and experiments
System approach?

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8
SmarThor: connecting ideas and systems
Envisioning
bring stakeholders together
translate visions on energy,
to roadmaps and experiments
Low Regulated Site (regelluwe zone)

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9
SmarThor: connecting ideas and systems
Envisioning
bring stakeholders together
translate visions on energy,
to roadmaps and experiments
Low Regulated Site (regelluwe zone)
Multi-commodity market models
Electricity, heat/cold, gas
Simulation platform
ICT system for living labs
Central system offering RealTime + Historic data
and interfaces for appliances, model and algorithms
Use of international frameworks (OpenADR, USEF,
EEBUS, …)

76. confidential
Implementing ICT Tools to support Research and Projects
Increase Technology Readiness Level of Algorithms
improve development cycle
improve valorization (cfr MatLab)
Be prepared for future Demonstration Projects (cfr Linear)
smaller budgets + shorter lead times
Linear: 2+2+1,5 // scoping/research + integration/deployment + executing
Integrated platform:
Simulations
Lab experiments and prototypes
Demonstration in real life with partners

77. confidential
2020 20%
renewables
Low Regulation Zones
Avoid ‘Multi’ Optimization
Test users make their own
business case
Instructive
Contaminating results
Create business models:
Total system cost
Share costs / benefits
Define boundary conditions
2016 20272021
South: yearly yield
East-West: daily spread
SUMMER
downward regulation
Winter
upward regulation
Flex consumption to
absorb surplus over the
noon, during weekends
Flex consumption to
disconnect from the grid
Opposite behavior needed
Which investments can
serve both cases?
Which regulation can
support these investments?
Closure Nuclear
System Approach

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New models in real life:
E.g.
Universal Smart Energy Framework
Open Automated Demand Response
New Market Interactions
E.g. Aggregator <–> DSO
Flexibility services
Customer –> services for TSO
Not enabled in current regulation
Frameworks for Smart Grid Interactions

79. Cluster Technology of
Wallonia Energy, Environment
and sustainable Development
TWEED Asbl
Rue Natalis 2 – 4020 Liège – Belgium
Bricout Paul
Project engineer
pbricout@clustertweed.be
Olivier Ulrici
Project engineer
oulrici@clustertweed.be
Cédric Brüll
Director
cbrull@clustertweed.be
www.clustertweed.be