RESEARCH DAY ITALY-SLOVENIA - mizs.gov.si · Prof. Patrizia Simeoni [email protected]....
Transcript of RESEARCH DAY ITALY-SLOVENIA - mizs.gov.si · Prof. Patrizia Simeoni [email protected]....
RESEARCH DAY ITALY-SLOVENIA Bilateral meeting Italy-Slovenia on the role of research in
the society
18 April 2018
Success stories of collaboration: «Smart Campus» project
Prof. Giorgio Sulligoi [email protected]
Prof. Patrizia Simeoni [email protected]
Background
Smart specialization is an innovative approach promoting efficient and targeted use of public investment in research and innovation to
enable countries and regions to capitalize on their strengths and create new competitive advantages.
Smart Specialization Platforms are managed by the European Commission's Joint Research Centre and they provide support to
regions to foster interregional cooperation based on matching smart specialization priorities related to these three areas
1. S3P Agri-Food
2. S3P Energy: http://s3platform.jrc.ec.europa.eu/s3p-energy
3. S3P Industrial Modernization
What is the S3PEnergy about?
The main objectives of the S3PEnergy are:
• support the implementation of S3 Energy strategies of those regions/countries that have chosen energy-related priorities in their
S3
• contribute to the EU energy policy priorities by facilitating partnerships between EU regions that have identified renewable
energy technologies and innovative energy solutions as their smart specialization priorities and by promoting alignment
between local, regional, national and European activities on energy sustainability, competitiveness and security of supply.
• set up "S3 Energy Partnerships" that offer interactive and participatory arenas for interregional cooperation :
Background
Smart specialization is an innovative approach promoting efficient and targeted use of public investment in research and innovation to
enable countries and regions to capitalize on their strengths and create new competitive advantages.
Smart Specialization Platforms are managed by the European Commission's Joint Research Centre and they provide support to
regions to foster interregional cooperation based on matching smart specialization priorities related to these three areas
1. S3P Agri-Food
2. S3P Energy: http://s3platform.jrc.ec.europa.eu/s3p-energy
3. S3P Industrial Modernization
What is the S3PEnergy about?
The main objectives of the S3PEnergy are:
• support the implementation of S3 Energy strategies of those regions/countries that have chosen energy-related priorities in their
S3
• contribute to the EU energy policy priorities by facilitating partnerships between EU regions that have identified renewable
energy technologies and innovative energy solutions as their smart specialization priorities and by promoting alignment
between local, regional, national and European activities on energy sustainability, competitiveness and security of supply.
• set up "S3 Energy Partnerships" that offer interactive and participatory arenas for interregional cooperation :
Support from EC: 200 k€ Lead Partner: Andalusian Energy Agency
Duration: year 2018 Scientific Lead Partner: Friuli Venezia Giulia Region
(with support of Universities of Trieste and Udine)
“Call for Expression of Interest for Thematic Partnerships to Pilot Interregional Innovation Partnerships”:
The pilot action should build on the work already undertaken under the S3 Platforms on learning, connecting and
demonstration, to encourage a more hands-on and tailored approach to support concrete actions during the
commercialization and scale-up phase.
Smart Campus project
The University Campus buildings have different uses and therefore different energy consumptions. It is not always easy to monitor such consumptions in old buildings because the most innovative measurement systems are not always cost-effective.
improve the energy efficiency of University Campus buildings:• symbiosis with regional territory• development of energy saving innovative solutions • use of renewable energy• smart energy generation, use and distribution systems in existing buildings
provide new energy management and control systems built over the IoT paradigm installed at buildings and energy infrastructure level
use University Campuses as new technology demonstrators for electrical and thermal energy distribution and storage.
RATIONALE of Smart Campus Pilot Project
The project will
involve other university partners • in the process of energy innovation • introducing their complementary innovative solutions• replicate the results at their own campus• demonstrate the effectiveness of the measures and tools implemented.
improve the energy efficiency of University Campus buildings:• symbiosis with regional territory• development of energy saving innovative solutions • use of renewable energy• smart energy generation, use and distribution systems in existing buildings
provide new energy management and control systems built over the IoT paradigm installed at buildings and energy infrastructure level
use University Campuses as new technology demonstrators for electrical and thermal energy distribution and storage.
RATIONALE of Smart Campus Pilot Project
involve other university partners • in the process of energy innovation • introducing their complementary innovative solutions• replicate the results at their own campus• demonstrate the effectiveness of the measures and tools implemented.
HKolbe
Rizzi
Cotonificio
Antonini
Tomadini
Florio
Servadei
Petracco
Buildings €uro c/iva KWh
RIZZI 713.182,89 40,74% 3.478.575 43,08%
COTONIFICIO 342.591,06 19,57% 1.586.159 19,64%
KOLBE 163.085,03 9,32% 785.209 9,72%
PETRACCO 98.166,50 5,61% 458.930 5,68%
FLORIO 95.838,51 5,47% 393.929 4,88%
TOMADINI 107.057,26 6,12% 422.517 5,23%sum 1.519.921,25 86,83% 7.125.319,00 88,23%
OTHERS 230.575,16 13,17% 949.593 11,77%
1.750.496,41 8.074.912
UNIVERSITY OF UDINE CAMPUS!
UNIUD Campus is distributed in the City and it has many buildings built
over the years with different energetic performances. Buildings were
connected to the electric distribution grid and they were heated up
through standard boilers powered by methane
1. Campus as Univercity: improve the efficiency of the campus in symbiosis with the availability and needs of the territory.
2. Provide to provide innovative low-cost energy management and control systems installed in units and buildings based on IoT-paradigm.
UNIVERSITY OF UDINESmart Campus
UNIVERSITY OF UDINE
Smart campus Uniud project
Energy and environmental
Efficiency
In University
►District heatingt
INNOVATIVE TRADITIONAL
► Uni-uD-T
IoT in a BOX
Termostat++
► Photovoltaic
► UTA
► lighting
► pumps efficiency
► Sustainable mobility
(throught photovoltaic)►Sustainable mobility
(SmartI€S
project)
Udine NORD
Regional support for energy strategy and
planning(terza mission)
(ATON project)
SMARTCampusUNIUD
(SmarT€R
project)
►Smart data system for monitoring, safety
and maintenance
(SMart€ST project)
Univercity
UNIUD idea: to create e a bottom-up model that integrates fossil, renewable and urban needs.
Energy bi-fuel (bio-oil and methane) trigenerative plant for the hospital with district heating network. The network collects the hospital's waste heat to heat university buildings, public schools and private citizens
Smart campus Uniud:ATON project a UNIVERCITY!
UNIVERSITY OF UDINE
Building
Thermal
power
[MW]University buildings (research
departments, labs, conference hall,
students’ house)
7,2
Palamostre (wimming pool, art gallery and
theatre)2,0
Residential area (4 residential buildings, 2
schools)6,6
School centre (12 schools) 12,3
Residential village (10 buildings, 2 schools) 5,3
Istituto Tomadini (Private school) 3,0
AMGA (Water and natural gas provider) 1,5
ConfigurationPrimary demand of energy
[MWh/yr]Emissions [tCO2/yr]
Old system 251,988 51,372
New synergic system 221,014 34,452
Savings 30,974 16,920
Percent reduction 12,29% 32.94%
The district heating network: red areas mark the early subscribers, while the green ones clients to be connected in the second project stage
Smart campus Uniud:ATON project a UNIVERCITY!
UNIVERSITY OF UDINE
UNIVERSITY OF UDINE
The University of Udine partially realized and will complete a photovoltaic system. After finishing
the system, the plant will be integrated with a power network supplying both Campus and
laboratories. It will also connect the energy storage system, which is already present in the
Campus, and the chargers for electric cars. In the project algorithms will be realized and applied
to examine the photovoltaic potential of buildings’ roofs in urban settings. By using LIDAR data, it
will also specify how to optimize heating/cooling technologies in order to get both design criteria
and reference indicators for monitoring and maximizing the energy and environmental efficiency.
Smart campus Uniud: SmartI€S project (Smart Innovative Energy
System)
546kWp on the roof
2184 photovoltaic modules
Cloud
Machine
Wifi DAQBox
Smartsensor2
Wifi DAQBox
Smartsensor1
Wifi DAQBox
Smartsensor3
Portableserverandrouter
DPEapplicationtouchpanel
The existing units become components
connected to the Internet, visible and
accessible on "cloud" space; this allows for
advanced unit management in order to
implement innovative features such as:
• timed and/or scheduled local and/or remote
timing and/or timer shutdown (via a specific
"app" to be used on a common smartphone)
or automatically when the user (and his /her
smartphone) enters a space well-defined
near the system
• centralized management of the entire
network for monitoring, diagnostics,
optimization
• replacement of the mechanical thermostat
and the "electromechanical" management
system of the seasonality
• Short term monitoring and data logging ofmachinery and environments
The project foresees to make "smart" units and environments through the concept of IOT by
inserting the electronic system designed with the aim of optimizing (reduce) energy consumption of
the heating rooms and units in buildings where the presence of people is occasional and the plants
are centralized.
UNIVERSITY OF UDINE
Smart campus Uniud:
SMART€R project
GOALS: setting up a campus microgrid:
1. Recognition of existing and applicable microgrid infrastructures
2. Analysis and assessment of the current energy infrastructure
3. Identification or design of innovative management technologies and models resulting from the state of the art to the specifications of our Campus
4. Identification of relevant sources of funding both public and private
The Smart Campus project aims at: 1. using the existing electrical energy measurement and communication
infrastructure of the campus (optical fiber ring for communications and measurement transformers for electrical quantities)
2. building an experimental system for the campus electrical grid monitoring and control, based on modern H/W-S/W platforms (real-time open source operating systems and IP-based protocols) that are open, flexible and adaptable to possible future developments.
UNIVERSITY OF TRIESTE CAMPUS
Electrical distribution :data measurement acquisition/communication
UNIVERSITY OF TRIESTE CAMPUS: STATE OF THE ART
?IF
Different possiblesolutions
Server
InternetClients
ABB
Endress+Hauser Energy TeamAcotel
Open Source
Data Communication
UNIVERSITY OF TRIESTE CAMPUS: SOLUTIONS
1. Energy Directorate - RAFVG (Italy)2. Andalusian Energy Agency - AAE (Spain)3. Lappeenranta City – LAP (Finland)4. Energy Directorate – SED (Slovenia)5. Agence des villes et territoires méditerranéens durables -
AVITEM (France) 6. Areal Regional Energy and Environmental Agency – AREEA
(Portugal)
1. ABB - industrial solutions provider2. Blue Energy Group (Italy) - energy trader3. OverIT (Italy) - ICT for energy enterprises4. Technological Corporation of Andalusia (Spain) - PPP5. Green Energy Showroom, cluster (Finland)6. Iskraemeco – energy collector (Slovenia)7. GEN-I – energy supplier (Slovenia)8. Enercoutim, Alcoutim Solar Energy- association (Portugal)
1. Academic :students, professors and staff from the related campus.
2. AEIT (Italian Association of Electrical, Telecommunication, Automation and Computer Engineers) – Network of stakeholders, FVG Section (Italy)
3. REDEJA – Energy Management Network of the Andalusian Regional Government (Spain)
4. Responsible for maintenance of public buildings in the regions involved.
1. University of Trieste (Italy) 2. University of Udine (Italy) 3. University of Ljubljiana (Slovenia) 4. University of Malaga (Spain)5. Lappeenranta University of Technology (Finland)6. University of Algarve (Portugal)
Smart Campus PARTNERS
deliver “University Buildings Energy Efficiency Roadmap for the Development ofSmart Campuses”
carry out an assessment of the actual energy consumption measurements andcontrol systems at university campus buildings in the involved regions, based onthe first guidelines available on “Smart Readiness Indicator”.
develop a road map, selecting promising technologies and smart energymanagement systems (IoT driven)
develop a policy dialogue, leading to specific regional policy commitments that canaccelerate the progress towards EU policy objectives
deliver a portfolio of technical, financial and legislative solutions and services tomeet the challenges locally and regionally
stimulate urban symbiosis approach
improve and develop interoperability of building automation
OUTPUT of Smart Campus Pilot Project
overcome the potential legal and administrative constraints, that different regions andcountries may have towards Energy policies: Public Administrations are not completely able to technically assess and verify the effectiveness of energy services delivered;
guidelines should be structured in order to be usable at different scales and by different Countries and should also integrate actual European policies
results obtained in the Pilot, can be generally applied to Public Administration Buildings.
business and financial plan for the deployment of technologies and innovative solutions should be set up
creating conditions for the involvement of new private actors and for creating PPP to leverage investments for competitive technologies
BOTTLENECKS of Smart Campus Pilot Project
WP
1:
Smar
tne
ss A
sse
ssm
en
t o
f U
niv
ers
ity
Cam
pu
ses
• Survey amongUniversityCampuses
• Survey amongIndustrial Stakeholders
WP
2:
Inte
rre
gio
nal
In
no
vati
ve P
ilot
Cas
es
• Business Plan of selected Pilot Cases
• Commercialization and scale up of selected Interregional Innovative Pilot Cases
• Technical and legislative solutions to Pilot Cases bottlenecks
• Blending of funds to support the Pilot Cases realization
WP
3:
Def
init
ion
of
Smar
t C
amp
us
req
uir
em
en
ts
• Policy dialogueamong Regions
• University Buildings Energy Efficiency Roadmap for the Development of Smart Campuses
OVERVIEW of the TECHNICAL WPs and EC SUPPORT
specialized expertise on
blending of funds
protocols on the combination of
different public and private funding
instruments
specialized expertise on legal
issues/IPR
business plan development
support
energy/green certification procedures
Support from the EC:
RESEARCH DAY ITALY-SLOVENIA Bilateral meeting Italy-Slovenia on the role of research in
the society
18 April 2018
Thank you for your attention!
Prof. Giorgio Sulligoi
Prof. Patrizia Simeoni
[1] https://smartreadinessindicator.eu/
SRI would give recognition for smarter building technologies and
functionalities which enhance the energy efficiency and other pertinent
performance characteristics
SRI: Smart Readiness Indicator
DOMAINS:
1. Heating/Cooling
2. Domestic Hot Water
3. Mechanical Ventilation
4. Lighting
5. Dynamic Building Envelope
6. Monitoring and Control
(Energy)
7. Energy Generation
8. Demand Side Management
9. Electric Vehicle Charging
IMPACT FIELDS
1. Energy savings on site
2. Flexibility for the grid and
storage
3. Self generation
4. Comfort
5. Convenience
6. Health
7. Maintenance & fault prediction
8. Information to occupants
“Smartness” refers to the capability of a
• single building,
• a system of buildings/districts
• distribution infrastructures
to sense, interpret, communicate and
actively respond in an efficient manner
to the changing conditions, which are
introduced by
• demands of occupants
• operation of technical building
systems/districts
• the territory
• operation conditions
• the external environment (including
energy grids)
“Smart Ready Technologies” are considered to
be active components which could potentially:
• raise energy efficiency and comfort by
increasing the level of controllability of the
technical building systems
• facilitate the energy management and
maintenance of the building including via
automated fault detections
• automate the reporting of the energy
performance of buildings and their real time
inspections
• use advance methods such as data analytics,
self-learning control systems and model
predictive control to optimize building
performance
• storage systems and energy generators to
become active operators in a
demand/response setting
SRI: Smart Readiness Indicator
Definition of SMARTNESS SMART READY TECHNOLOGIES