visite du centre de recherche energyville

Cluster TechnologyofWalloniaEnergy,EnvironmentandsustainableDevelopment

11octobre2016@Genk

Visite d’EnergyVille→ réseauxintelligents→ systèmesénergétiques Intelligents→ systèmesthermiques→ véhiculesélectriques→ futurdesmarchésdel'énergie

PROGRAMME

• 10:00Accueil&présentationd'Energyville

• 10h45LeClusterénergieenFlandre

• 11:30Visitedubâtiment

• 12:00Lunch&Networking

© EnergyVille

Research

into sustainable energy

and smart energy systems

© EnergyVille

226/10/2016

Flemish energy research partnership by

KU LeuvenElectaBuilding PhysicsMechanics

imecPhotovoltaicResearch

VITOEnergy TechnologySustainable 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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726/10/2016

EnergyVille

Connected inan interconnected world

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826/10/2016

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

Men

Tho

r An ecosystem:

Bring stakeholders together

Visions on energy roadmaps experiments

Integrate research,educationand entrepreneurship

Acc

ele

raTh

or Stimulate start-ups in

energy services andtechnology

1. boost entrepreneurship

2. Idea validated business plan(KIC InnoEnergy)

3. Upscaling(LRM, …)

Dem

on

stra

Tho

r Integrate technologyand research

Offer a Living Lab

Reg

ula

tio

nFr

ee A

rea

Thor Park Programme

Host teams @Thor

Incu

baT

ho

r Develop yourbusiness @Thor

Mo

Tho

r Host teams @Thor

EnergyVille:• Home Lab• Battery Lab• Matrix Lab• Thermal Lab• EV Lab• Solar LabThor:• Buildings• Smart Grid• 4G Heat Network

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1526/10/2016

IncubaThor

Innovation in Energy

Business Incubator

Target: start-up companies

Building nextto Campus EnergyVille

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1626/10/2016

© EnergyVille

1726/10/2016

IncubaThor

Innovation in Energy

Business Incubator

Target: start-up companies

Building nextto 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 andConversion

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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 resistancemonitoring

Dynamic balancing

State of charge calculation

State of health calculation

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2326/10/2016

Research into

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2426/10/2016

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

StorageSmart Control

Optimal Energy Demand

Integration of Energy

Conversion Technologies

Create Flexibility

Dynamic Behaviour

Energy Efficiency

RES Integration

Storage Solutions

Optimal Interaction

Integrated System

CostEfficiency

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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 andhybrid networks (interactionwith 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 forthermal energy storage

Scouting long term thermalstorage 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 networkon THOR site, connected toour 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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3426/10/2016

Research into

Electrical Systems

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3526/10/2016

Physical Integration of Renewable Energy Sources

HVDC

Technologies fornet services

Energy yield forecasting

Building IntegratedPhotovoltaics

DC micro- andnanogrids

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3626/10/2016

Large scale integration of RES (transmission)

Grid investments

Generation unit commitment

New operational modes forsystems

Grid code compliance

Control of RES to participatein ancillary services

Maintaining system reliabilityunder uncertainty

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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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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 yieldmodels

PV plant production

forecast error

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4126/10/2016

PV System – resolution in 15 minutesProposed Model – resolution in 1 second

Enhancing the value of photovoltaic energy

Short-term energy forecasting

© EnergyVille

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 industrialinterest

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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 buildingstypically on the roof

BIPV = multifunctional use

building component

generates electricity

Highly application-specificsolutions

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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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4726/10/2016

Towards Building-Integrated PV (BIPV)

Demonstrators & facilities

Organic PV

Façades

Semi-transparent

Color-on demand

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4826/10/2016

Testing and modellinginteration PV vs. Building

Hygrothermal & mechanical

Model validation

Lab validation

Towards Building-Integrated PV (BIPV)

Demonstrators & facilities

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4926/10/2016

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 forelectricity markets

Interoperability

Communication

IT

Virtual Power Plants

Energy System Analysis

Living Labs

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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 …

Technologyprovider

Distributedgeneration

Otherstakeholders

Prosumer(industrial –residential)

European Energy Markets

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5326/10/2016

Virtual Power Plants

Interoperability for future electricity markets

5 3

31

X

X

X2

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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5426/10/2016

Research into

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5526/10/2016

Cities in Transition

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5626/10/2016

Cities in transition

Building renovationstrategies

Energy district design

Sustainable building concepts

© EnergyVille

5726/10/2016

Building renovation strategies

Databases & tools to support retrofit decisions

Costs and effects over the full life cycle

Co-operation models / services

© EnergyVille

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

© EnergyVille

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

© EnergyVille

6026/10/2016

Domains of expertise

Control Systems

Energy Markets

Power Electronics

ICT

ThermalSystems

Power Grids

Building Physics Photovoltaics

GeothermalEnergy

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6126/10/2016

Labs

Battery Testing Lab

Home Lab

Smart Grid InfrastructureLab

Thermo Technical Lab

Medium Voltage Lab

PV Metrology Lab

Matrix Lab

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6226/10/2016

Innovation chain

Earlyresearch

Development PrototypingLow 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

© EnergyVille

More info?

Kris Baert kris.baert@energyville.beKris Boonen kris.boonen@energyville.beErik De Schutter erik.deschutter@energyville.beArnoud Lust arnoud.lust@energyville.beSteven Van Deun steven.vandeun@energyville.beTatiana Pasquel Garcia tatiana.pasquelgarcia@vito.bePhilip Pieters philip.pieters@energyville.be

confidential

SmarThor Connecting Visions, Technology and Knowledge

Tweed

11 October 2016

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

confidential 3 26/10/2016

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

confidential 4 26/10/2016

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

confidential 5 26/10/2016

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

confidential 6 26/10/2016

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

confidential

7

SmarThor: connecting ideas and systems

Envisioning

bring stakeholders together

translate visions on energy,

to roadmaps and experiments

System approach?

confidential

8

SmarThor: connecting ideas and systems

Envisioning

bring stakeholders together

translate visions on energy,

to roadmaps and experiments

Low Regulated Site (regelluwe zone)

confidential

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, …)

confidential 10 26/10/2016

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

confidential 11 26/10/2016

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 2027 2021

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

confidential 12 26/10/2016

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

Cluster TechnologyofWalloniaEnergy,EnvironmentandsustainableDevelopment

TWEEDAsblRueNatalis 2– 4020Liège– Belgium

BricoutPaulProjectengineer

pbricout@clustertweed.be

OlivierUlriciProjectengineer

oulrici@clustertweed.be

CédricBrüllDirector

cbrull@clustertweed.be

www.clustertweed.be