GreEn-ER Living Lab
A Green Building with Energy Aware Occupants
Benoit Delinchant
1
, Frédéric Wurtz
1
, Stéphane Ploix
2
, Jean-Luc Schanen
1
and Yves Marechal
1
1
G2ELab - Grenoble Electrical Engineering Laboratory, Grenoble University Alps, Grenoble, France
2
G-Scop Grenoble Industrial Engineering and Laboratory, Grenoble University Alps, Grenoble, France
Keywords: Green Building, Smart Building, Smart Micro-grid, Energy Efficiency, User Centred Building, Living Lab.
Abstract: In the context of doubling energy use worldwide by 2030, with 80% remaining carbon energy, and in which
buildings account for more than 40% of the total energy consumption, it is appropriate that buildings
contribute "intelligently" to reduce consumption, contribute to the increase of renewable energy production
and become a key node of the energy grid related to energy and transport of the eco-city. Moreover, these
“smart buildings” will be in the near future aggregating a huge amount of data through numerous sensors.
They will be connected to the neighbourhood, to the city and to the territory. Big data analytics and cloud
computing will bring new services to inhabitant and citizen. We are presenting in this paper, the smart building
“GreEn-ER”, which is a new building in the centre of the eco-city in Grenoble, France. It has been designed
with many “green” ideas and is a “living lab” supporting research and teaching in the field of sustainability.
This paper is focusing on the energy field and deals with electrical micro-grid interaction.
1 INTRODUCTION
1.1 The Building System
First of all, a building is composed by:
a skin, which protects inhabitants from bad
external conditions (climatic, pollution, noise,
thieves…)
systems to bring comfort (heating, ventilation,
air conditioning, lighting, cooking, sleeping,
entertainments, health care, security, …)
But we are not studing this building, we are
working on a complex system, the BUILDING
SYSTEM, which is composed by the previous
building in addition with:
the building users (inhabitants, owner, energy
managers…)
the building environment (weather, energy
grids, information network, transportation, …)
This system is really complex since it is subject to
many aspects such as:
human (social, physiologic, phsycologic, etc)
multi-physic (thermal, electric, mechanic, etc)
economic (capex, opex)
environmental (life cycle management, non-
renewable resources …)
These items are ones we have to adress in our
researches in the domain of energy in buildings.
1.2 Smart Building
Smart building is generally associated with home
automation but it is far more complex. One of the
challenges for energy based smart building success,
is to work together with at least three sectors:
The energy sector, which needs to anticipate the
consumptions and load shedding capabilities as well
as decentralized energy resources (DER) potential in
order to better manage production/consumption
correlation.
The building automation industry which must
move from classical BMS (building management
system) that are most coming from the industry
sector, to the city connected buildings and citizens.
The ICT sector which should collect the data of
buildings in order to feed service platforms in the
cloud for citizens, energy operators, and territorial
decision makers.
Heating building correspond in France to the main
consumption part as it can be seen with the strong
correlation of consumption with temperature (Figure
1).
316
Delinchant, B., Wurtz, F., Ploix, S., Schanen, J-L. and Marechal, Y.
GreEn-ER Living Lab - A Green Building with Energy Aware Occupants.
In Proceedings of the 5th International Conference on Smart Cities and Green ICT Systems (SMARTGREENS 2016), pages 316-323
ISBN: 978-989-758-184-7
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
Figure 1: Correlation between temperature and electrical
consumption in France – Gradient of daily consumption in
France in GWh/day as a function of the average temperature
in France (in °C).
Figure 2: Evolution tendency of residential energy
consumption /m² in France.
In Figure 2, while consumption reductions have
been obtainded for heating thanks insulation
improvement, the specific electricity is increasing a
lot. This part is nowadays a big challenge for passive
building where summer comfort becomes critical.
In Figure 3, we have put main topics around smart
building in a single picture and it is clear that smart
building is a complex system which has to deals with
many challenges.
1.3 Smart Building Challenges
It is possible to define several objectives for smart
buildings, according to social, environmental and
economical aspects.
Sobriety, efficiency and energy optimization
User comfort and services through internet of
things
DER (Decentralized Energy Resource),
renewable energy produced
Main contributor node of the city micro grid
multi-fluid energy management
Mobility: link between Building – Transport
New services associated with the Big Data
Analytics / Cloud computing
In Figure 3, we are defining several research
topics related to these challenges:
Load management: load scheduling / adjusting
/ shedding, uncontrolled load prediction
Figure 3: What a smart building has to manage.
GWh/day
~50 GWh/day increase
per °C decrease
GreEn-ER Living Lab - A Green Building with Energy Aware Occupants
317
Local or distributed multi energy sources and
storage management: arbitration between
generators, scheduling production / storage.
Uncertainties management: regarding users
(equipment usage, comfort requierment),
regarding weather (heating/cooling needs,
renwable production), regarding energy price
Local and distributed intelligence: energy and
comfort monitoring for inhabitants and service
providers, system actuation and control, data
mining, cloud computing.
Life cycle management: adaptative modelling,
robust optimization, plug & play predictive
control…
Some of these challenges have been already
adressed by researchers and there is already a lot of
work in the litterature. For instance, starting from the
smart grid context, smart meter have been widelly
considered enought to make the grid smart but
Sharma has shown metering vulnerability and has
defined what is smart metrology meter (Sharma,
2015). In order to improve the knowledge about end-
users, load curve dissagregation must be applied on
the non-intrusive load-monitoring techniques.
Rowlands published recently a review and
recommendations on the end-user monitoring in order
to increase the measurments to loads, production and
storage. Numerous data are requiered to model load
demand at the level of the day. Torriti has made a
review of data and methods of time use studies such
as Markov chain technics (Torriti, 2015), while Fumo
has widelly use linear regressions but is claiming that
the increase of sensors will lead to individual models
instead of statistical ones (Fumo, 2015). Home energy
management systems (HEMS), based on such
modelling, enabled demand response in electricity
market, Khan review demand response programs in
various scenarios as well as incorporates various
architectures and models (Khan, 2015). Multi-agent
strategies are especially well suited in this building-
grid interaction or negociation (Labeodan, 2015).
Building energy management is not enough, users
comfort is critical to ensure sustainability engagment
of people. Shaikh conducted a state-of-the-art
intelligent control systems for energy and comfort
management in smart energy buildings (Shaikh,
2014).
Now, smart grid is dealing with ubiquitous
computing of smart building in which the home
environment is monitored by ambient intelligence to
provide context-aware services and facilitate remote
home control (Alam, 2012). A general trend for new
building is the nearly net zero energy buildings (Task
40/Annex 52, 2011). In Europe, the directive on
energy performance of buildings establishes the goal
of ‘nearly net zero energy buildings’ for all the new
buildings from 2020.
In France, all new buildings should comply with
energy positive by 2020. We are involved in
COMEPOS Project (www.comepos.fr) aiming at
constructing twenty five positive energy buildings in
France by 2018 in order to prepare this new
regulation. When energy generation is available in the
building neighbourhood it may become smarter since
it is possible to use more degrees of freedom. Lu et al.
has recently made a review on design optimization
and optimal control of grid-connected and standalone
nearly/net zero energy buildings (Lu, 2015).
In our team, our main challenges are to find
methodologies and to develop software for energetic
systems design and operation in their environment,
and during life cycle. This includes:
the optimal design with operating costs (Capex
+ Opex).
the optimal operation of consumption/
production/storage.
“human in the loop”, to define comfort/cost
trade-off, to give sobriety advices…
In the following parts of this paper, it will be
presented through our experimental platform how we
are dealing with these challenges through the
following activities:
Modeling: systemic approach, multicriteria
tradeoff, scalability and uncertainty
Optimization: dedicated algorithms and
strategies
Smart Ubiquity: information network, local
and distributed computing
Transdisciplinary Approaches : working with:
sociologist, economists, computer scientists
2 ENERGY EFFICIENCY
2.1 GreEn-ER Building
GreEn-ER is a new building in Grenoble, dedicated
to develop creativity, entrepreneurial spirit, and
sustainability popularization in an environment
combining training students, researchers, and end
users. GreEn-ER is hosting master level training, for
students of “Energy, Water and Environmental
Engineering School” (Grenoble INP ENSE3).
Some figures:
A 6 floors building with 4500 m² space per
floor for platforms teaching / research
SMARTGREENS 2016 - 5th International Conference on Smart Cities and Green ICT Systems
318
2000 people welcomed in the building,
including 1,500 students.
1 research laboratory
2 restaurants (a brasserie and a university
restaurant)
500m
2
of space at the Library
Figure 4: GreEn-ER: a building for energy learning and
research.
2.2 Designed with Green Ideas
Many green ideas are in experiment, such as energy
recovery. Data server room calories are reused to heat
an atrium (Figure 5). Free cooling strategies using
natural convection through the atrium (Figure 6), and
forced convection in offices.
Figure 5: Server room calories recovery for atrium heating.
Figure 6: Natural ventilation through the atrium.
Dual flow ventilation with high efficiency
recovery and low temperature supply (Figure 7):
heating: 30/25°C (occupation/inoccupation)
cooling: 19/23°C (occupation/inoccupation)
Figure 7: HVAC system.
And some other sustainable solutions:
Automation: HVAC, lighting and blinding are
based on local sensors of temperature,
luminosity, CO2, and occupancy.
Energy Sobriety: limited air conditioning, no
hot water in toilets. Power supply switching
Water Sobriety: 40% of the water consumption
is from rainwater.
Green Roof: free spaces on the roof are covered
by vegetal plants.
Total primary energy consumption will be less
than 2200 MWh / year which correspond to 110
kWh/m
2
.
2.3 Energy Autonomy and Micro Grid
In GreEn-ER, PREDIS-MHI is 600 m² platform
energy systems (
Figure 8
), has been specifically
designed to reach zero energy building, and to study
building or neighbourhood autonomy.
Figure 8: PREDIS MHI, production and storage.
20kW of photovoltaic panels installed on vehicles
roof, and other are planned to be installed on the
building roof. Other electrical productions are
available in PREDIS platform such as a fuel cell and
combined heat & power (CHP) which is also able to
heat our platform. Storage capabilities have also been
GreEn-ER Living Lab - A Green Building with Energy Aware Occupants
319
installed with electrical vehicles, and laptop rooms. A
50kWh stationary battery will be added.
Figure 9: PREDIS MHI micro grid structure.
LC: Local Controller, CC : Central Controller, LM : Local
Monitor.
Optimal control solutions based on predictive
models will be tested in this platform. Solving the
problem of demand response requires determining a
generation and a controllable load demand policy that
minimizes, over a planning horizon, an objective
function subject to economic and technical
constraints. This policy is used as reference for the
voltage and frequency control in microgrid real-time
operation.
Load demand can be classified by priority and
type as critical:
Critical Load Demand: has to be full supplied
all the time, otherwise, it will cause deficit in
the system.
Reschedulable Load Demand: has a particular
characteristic of being able to be allocated
across a range of time.
Curtailable (shedable) Load Demand: may
have the power supply cut, as a non-priority
load, if necessary.
Diffuse Load Demand: is a new concept made
to deal with a thermic load demand, having the
diffuse effect or the pre-diffuse behavior.
We are solving such an energy management using
a deterministic mixed-integer linear programming
problem, where the planning horizon is 24 hours with
one-minute time steps (Tenfen 2014).
2.4 Real Time Energy Management
In our platform, several hundred measuring points
and control have been set up such as HVAC,
dimmable lighting, blind, electrical plug consumption
measure and switch…
These measures and commands are accessible
through the building network infrastructure and the
internet. Its communication protocol is web service
based enabling interoperability.
Many devices are added from the delivered
building such as wireless sensors (433MHz, ZigBee,
EnOcean, DeltaDore). In SmartGreen 2014, Abras
has presented the interoperability framework that we
have developed in order to manage this
interoperability through web-services (Figure 10,
Abras, 2014)
Figure 10: Sensor/actuators interoperability framework.
In 2013, Dang has presented the optimal control
of laptops charging/discharging to fit photovoltaic
production (Figure 11, Dang, 2013). This experiment
was done in our previous building and will be
deployed in the new one since it allows load shedding
and photovoltaic energy storage.
Figure 11: Real time control of 15 laptops
charging/discharging for demand response.
In this automation of energy management, users /
occupants are integrated in the loop. At this moment,
occupants are able to define set points such as
temperature, CO2 concentration, luminosity, heating
mode. Moreover, their feedback is required and
individual comfort will be learned progressively.
SMARTGREENS 2016 - 5th International Conference on Smart Cities and Green ICT Systems
320
Beside this automation, many things can be done
to help users to understand their own consumption
and to let him acting on the system in order to learn
about it. It will be discussed further in the part 3.
2.5 Multi-flow Energy Optimization
Both electric and thermal energy flow must be taken
into account in smart buildings since one of the main
consumption in building is HVAC (heating,
ventilation and air conditioning). Predictive models
for both electrical and thermal equipments are then
required for the optimal operation.
Regarding thermal behaviour of buildings,
dynamic simulation are done based on thermal
properties of the skin (Figure 12), depending on
weather conditions, occupancy and control set points.
The results are the energy consumption with peak
power, and occupant comfort criteria.
Figure 12: Thermal dynamic simulation of GreEn-ER
(COMFIE software).
The previous software (COMFIE) is mainly used
for design stage (not in control), since occupancy is
predefined by scenario. In order to make a control
depending on the occupant behaviour, we are able to
make a co-simulation with this software and agent
based modelling occupants (Gaaloul, 2013). This co-
simulation is allowed thanks to our interoperability
framework based on software component
(ICAr/MUSE, http://muse-component.org).
Moreover, predictive control is done using
optimization algorithms and requires dedicated
modelling. The electric equivalent circuit method is
recognized to be a good compromise between pure
physical modelling which are too expensive and
require too many information, and black box model
based on mathematics which are not enough robust
regarding prediction uncertainties. Robust self
learning technics of physical equivalent circuit have
been developed (Le Mounier, 2014).
There are Optimization technics using mixed
linear integer programming (MILP) which needs
linear modelling. These technics are especially
efficient for smart grid and microgrid (Tenfen, 2014)
but have limitation for non linear models which have
to be discretized (Le Mounier, 2014). The difficulty
in using non-linear model is to compute partial
derivatives in order to couple it with gradient based
optimization algorithms. We are using two different
technics, the automatic differentiation (Dinh, 2015),
and the adjoin method (Artiges, 2015), depending on
the nature of the model.
Energy optimization is also strongly related to
measurements. In (Artiges, 2015), we are able to
control energy system but also to determine which
sensors are best suited to perform this control.
3 GREEN-ER: A LIVING LAB
3.1 The Living Lab Concept
A definition is given by the European Network of
Living Labs (ENoLL: www.openlivinglabs.eu),
which is “a real-life test and experimentation
environment where users and producers co-create
innovations”.
Academic institutions such as Harvard, Yale and
Cambridge have adopted this concept within their
strategy for sustainability (Graczyk, 2015). In most
living lab concepts, the key components have been
identified to be the ICT & Infrastructure,
management, partners & users, research.
ENoLL defines four main activities:
Co-creation: co-design by users and producers
Exploration: discovering emerging usages,
behaviours and market opportunities
Experimentation: implementing live scenarios
within communities of users
Evaluation: assessment of concepts, products
and services according to socio-ergonomic,
socio-cognitive and socio-economic criteria.
3.2 AmiQual4Home Project
GreEn-ER and more especially the PREDIS platform
is involved AmiQual4Home project which stands for
Ambiant Intelligence for Quality of Life. It is an
Innovation Factory which is an open research facility
for innovation and experimentation with human-
centred services based on the use of large-scale
deployment of interconnected digital devices capable
of perception, action, interaction and communication.
GreEn-ER Living Lab - A Green Building with Energy Aware Occupants
321
The Amiqual4home Innovation Factory is a
unique combination of three different innovation
instruments:
Workshops for rapid prototyping of devices
that embed perception, action, interaction and
communication in ordinary objects,
Facilities for real-world test and evaluation of
devices and services,
Resources for assisting students, researchers,
entrepreneurs and industrial partners in
creating new economic activities.
3.3 Workshops for Co-creation and
Innovation
We have defined several workshops for users in order
to develop ideas, innovative products & solutions.
Each workshop is a set of tools available in the lab.
Brainstorming: to produce innovative ideas for
the developing of new services.
Role Playing: to test how users are interacting
together or with the system (a person may
simulate the response of the system).
Wizard of OZ Prototyping: to simulate new user-
specialized interfaces to monitor and control
things.
Sensors: to develop and test new sensors
technology, positioning and usefulness.
Interaction of sensors with occupants.
Integration of Industrial Solutions: to test existing
energy and control systems by integration in our
platform in order to study the interaction with
other systems in the whole building.
Data Mining: to discover patterns in large data
sets in order to discover trends and behaviour of
smart buildings usages.
Data Processing: to develop algorithms that use
data and transform it into actions or meaningful
information.
Simulation: software for building simulation
(energy, human behaviour, control …).
Adaptive Modelling: development of algorithm to
fit predictive models and data in order to prevent
uncertainties and improve robustness.
Some workshops can be already targeted such as:
User Monitoring: Analysis of user behaviour and
comfort
Smart Grid Monitoring: Analysis of electricity
exchanges between building and distribution grid.
Demand Side Management: Development of
solution for participating in grid support strategies
such as demand response, load shedding, etc.
These workshops are now in development and
will be sources for future research publications. These
workshops are end-user side view and will merge
smart grid requirements (such as energy peak
reduction, decentralized renewable energy
integration), and end-user requirements (such as
comfort, economy and sustainability).
4 CONCLUSIONS
The energy context and the potential of buildings in
order to improve sustainability are introduced in this
paper. GreEn-ER is then presented and the energy
efficiency of the building is highlight for its design as
well as for its operation. This building is presented as
a support for research in the domain of energy and
sustainability. We have presented scientific results
based on previous publications that have been
realized through this platform, such as energy
autonomy of building or micro-grid, real time energy
management, multi-flow energy optimization.
But GreEn-ER, with the PREDIS MHI platform,
is now becoming a “Living lab”. Building users are
researchers and students and they are able to improve
their own environment through several workshops
which have been presented in this paper. Thanks to
these tools, users can do innovations by themselves.
This interaction between the building and users are
our experimental field for the near future.
ACKNOWLEDGEMENTS
This work was supported by Grenoble-INP ENSE
3
,
IRT Nanoelec, Equipex Amiqual4Home (ANR-11-
EQPX-0002), and research project PRECCISION
(ANR-12-VBDU-0006).
REFERENCES
Sharma, Konark; Saini, Lalit Mohan, “Performance
analysis of smart metering for smart grid: An
overview”, Renewable & Sustainable Energy Reviews,
vol.: 49 pp.720-735, SEP 2015.
Torriti, Jacopo, “A review of time use models of residential
electricity demand“, Renewable & Sustainable Energy
Reviews, Volume: 37 Pages: 265-272, SEP 2014.
Fumo, Nelson; Biswas, M. A. Rafe, “Regression analysis
for prediction of residential energy consumption”,
Renewable & Sustainable Energy Reviews, Volume:
47, Pages: 332-343 JUL 2015.
SMARTGREENS 2016 - 5th International Conference on Smart Cities and Green ICT Systems
322
Khan, Aftab Ahmed; Razzaq, Sohail; Khan, Asadullah; et
al. “HEMSs and enabled demand response in electricity
market: An overview”, Renewable & Sustainable
Energy Reviews, Volume: 42, Pages: 773-785, FEB
2015.
Labeodan, Timilehin; Aduda, Kennedy; Boxem, Gert; et al
“On the application of multi-agent systems in buildings
for improved building operations, performance and
smart grid interaction - A survey”, Renewable &
Sustainable Energy Reviews, vol 50, pp. 1405-1414,
OCT 2015.
Shaikh P.H., Nor N.B.M., Nallagownden P., Elamvazuthi
I., Ibrahim T., “A review on optimized control systems
for building energy and comfort management of smart
sustainable buildings”, Renew Sustain Energy Rev, vol
34, pp. 409–429, 2014.
Alam, Muhammad Raisul; Reaz, Mamun Bin Ibne; Ali,
Mohd Alauddin Mohd, “A Review of Smart Homes-
Past, Present, and Future”, Ieee Transactions On
Systems Man And Cybernetics Part C-Applications And
Reviews, vol. 42, Issue: 6, pp. 1190-1203, NOV 2012.
Task 40/Annex 52, Anna Joanna Marsza, Per Heiselberg,”
Zero Energy Building definition - a literature review”.
A technical report of subtask A, 2011.
Lu, Y.; Wang, S.; Shan, K., “Design optimization and
optimal control of grid-connected and standalone
nearly/net zero energy buildings”, APPLIED
ENERGY, vol.: 155, pp.463-477, OCT 2015.
Tenfen D.; Delinchant B.; Wurtz F.; Finardi E. C.; Rolim
J.; Fernandes Rubipiara C., “Load Demand, Batteries,
and Electric Vehicles Modelling to the Energy
Management of Microgrids”, Workshop ELECON,
Magdeburg, October 2014.
S. Abras T. Calmant S. Ploix D. Donsez F. Wurtz, O. Gattaz
B. Delinchant « Developing Dynamic Heterogeneous
Environments in Smart Building Using iPOPO »
SmartGreen’14, International Conference on Smart
Grids and green IT Systems, Barcelona, Spain, 3:4
April 2014.
Dang H.-A., Delinchant B., and Wurtz F., “Toward
autonomous photovoltaic building energy
management: modeling and control of electrochemical
batteries”, Proceedings of Building Simulation 2013,
IBPSA’13, Chambery, August 2013.
Gaaloul S., Dang H.-A., Kashif A., Delinchant B. and
Wurtz F., “A new co-simulation architecture for mixing
dynamic building simulation and agent oriented
approach for users behaviour modelling”, Proceedings
of Building Simulation 2013: 13th Conference of IBPSA
2013, Chambery, August 2013.
Le Mounier A., Delinchant B., Ploix S., “Determination of
relevant model structures for self-learning energy
management system”, BSO’14, Building Simulation
and Optimization Conference, 23-24 June, London,
England, 2014.
Artiges N, Nassiopoulos A., Vial F., Delinchant B.,
“Optimal Energy Management Using Model Predictive
Control: Application on an Experimental Building”,
Climamed’15.
Dinh V.-B., Delinchant B., and Wurtz F., “Optimal sizing
of a complex energy system integrating management
strategies for a grid-connected building”, Building
Simulation Conference, Hyderabad in December 7-9,
2015.
Graczyk G., “Embedding a Living Lab approach at the
University of Edinburgh,” The University of
Edinburgh, Jun. 2015.
GreEn-ER Living Lab - A Green Building with Energy Aware Occupants
323
