Filters:
NameProjectTypeCompare
Tartu, Estonia V2G-QUESTS PED Relevant Case Study Compare
Utrecht, the Netherlands (District of Kanaleneiland) V2G-QUESTS PED Relevant Case Study Compare
Aveiro, Portugal V2G-QUESTS PED Relevant Case Study Compare
Győr Geothermal District Heating Project PED Relevant Case Study Compare
Jacobs Borchs Gate, Drammen PED Relevant Case Study Compare
Dietenbach, Freiburg im Breisgau PED Relevant Case Study Compare
SmartEnCity, Lecce SmartEnCity – Towards Smart Zero CO2 Cities across Europe PED Relevant Case Study Compare
STARDUST, Trento STARDUST – Holistic and Integrated Urban Model for Smart Cities PED Relevant Case Study / PED Lab Compare
Klimatkontrakt Hyllie, Malmö PED Relevant Case Study Compare
EnStadt:Pfaff, Kaiserslautern PED Relevant Case Study / PED Lab Compare
mySMARTlife, Helsinki PED Relevant Case Study Compare
REPLICATE (pilot action in the Novoli-Cascine district on “le PIagge” buildings), Firenze PED Relevant Case Study Compare
Sinfonia, Bolzano PED Relevant Case Study Compare
Hunziker Areal, Zürich PED Relevant Case Study Compare
Hammarby Sjöstad 2.0, PED Relevant Case Study Compare
Sharing Cities, Milano PED Relevant Case Study Compare
District Heating Pozo Barredo, Mieres PED Relevant Case Study Compare
Cityfied (demo Linero), Lund PED Relevant Case Study Compare
Smart Otaniemi, Espoo PED Relevant Case Study / PED Lab Compare
Zukunftsquartier, Vienna PED Case Study Compare
Santa Chiara Open Lab, Trento PED Case Study Compare
Barrio La Pinada, Paterna PED Case Study / PED Lab Compare
Zero Village Bergen (ZVB) ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Case Study Compare
Võru +CityxChange PED Case Study Compare
NTNU Campus within the Knowledge Axis, Trondheim ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Case Study Compare
Furuset project, Oslo ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Case Study Compare
Laser Valley – Land of Lights PED Case Study Compare
Ydalir project ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Case Study Compare
NyBy – Ny Flyplass (New City – New Airport) ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Case Study Compare
Fornebu, Bærum ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Case Study Compare
Fleuraye west, Carquefou PED Case Study Compare
Smart Energy Åland PED Case Study Compare
Romania, Alba Iulia PED ASCEND – Accelerate poSitive Clean ENergy Districts PED Case Study Compare
Romania, Alba Iulia PED InterPED – INTERoperable cloud-based solution for cross-vector planning and management of Positive Energy Districts PED Case Study Compare
Munich, Harthof district PED Case Study Compare
Lublin MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Case Study Compare
Roubaix, MustBe0 – Résidence Philippe le Hardi – 125 Rue d’Oran CULTURAL-E – Climate and cultural-based solutions for Plus Energy Buildings PED Relevant Case Study Compare
Bærum, Eiksveien 116 CULTURAL-E – Climate and cultural-based solutions for Plus Energy Buildings PED Relevant Case Study Compare
Findhorn, the Park InterPED – INTERoperable cloud-based solution for cross-vector planning and management of Positive Energy Districts PED Case Study Compare
Amsterdam, Buiksloterham PED ATELIER – AmsTErdam BiLbao cItizen drivEn smaRt cities PED Case Study Compare
Schönbühel-Aggsbach, Schönbühel an der Donau PED-ACT – Auto characterization of PEDs for digital references towards iterative process optimisation PED Relevant Case Study Uncompare
Umeå, Ålidhem district PED-ACT – Auto characterization of PEDs for digital references towards iterative process optimisation PED Case Study Compare
Aalborg East PED Relevant Case Study / PED Lab Compare
Ankara, Çamlık District PED-ACT – Auto characterization of PEDs for digital references towards iterative process optimisation PED Case Study / PED Relevant Case Study Compare
Trenčín MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Case Study Compare
Luxembourg, Betzdorf LEGOFIT – Adaptable technological solutions based on early design actions for the construction and renovation of Energy Positive Homes PED Relevant Case Study Compare
Vantaa, Aviapolis NEUTRALPATH – Pathway towards Climate-Neutrality through low risky and fully replicable Positive Clean Energy Districts PED Case Study / PED Relevant Case Study / PED Lab Compare
Vidin, Himik and Bononia MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Case Study Compare
Oslo, Verksbyen Syn.ikia – Sustainable Plus Energy Neighbourhoods PED Case Study Compare
Uden, Loopkantstraat Syn.ikia – Sustainable Plus Energy Neighbourhoods PED Relevant Case Study Compare
Zaragoza, Actur NEUTRALPATH – Pathway towards Climate-Neutrality through low risky and fully replicable Positive Clean Energy Districts PED Relevant Case Study Compare
Aarhus, Brabrand BIPED – Building Intelligent Positive Energy Districts PED Case Study / PED Relevant Case Study / PED Lab Compare
Riga, Ķīpsala, RTU smart student city ExPEDite – Enabling Positive Energy Districts through Digital Twins PED Case Study Uncompare
Izmir, District of Karşıyaka PED-ACT – Auto characterization of PEDs for digital references towards iterative process optimisation PED Case Study Uncompare
Istanbul, Ozyegin University Campus LEGOFIT – Adaptable technological solutions based on early design actions for the construction and renovation of Energy Positive Homes PED Relevant Case Study Compare
Espoo, Kera SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Case Study / PED Relevant Case Study Compare
Borlänge, Rymdgatan’s Residential Portfolio PED-ACT – Auto characterization of PEDs for digital references towards iterative process optimisation PED Relevant Case Study Uncompare
Freiburg, Waldsee PED urban – Development of methods and tools for accounting, planning and operation of climate-neutral district PED Case Study Compare
Innsbruck, Campagne-Areal PED Relevant Case Study Compare
Graz, Reininghausgründe PED Case Study Compare
Stor-Elvdal, Campus Evenstad ZEN – Research Centre on Zero Emission Neighbourhoods in Smart Cities PED Relevant Case Study Compare
Oulu, Kaukovainio MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Case Study Compare
Halmstad, Fyllinge PED Relevant Case Study Compare
Lund, Brunnshög district PED Case Study Compare
Vienna, Am Kempelenpark PED Case Study Compare
Évora, Portugal POCITYF – A POsitive Energy CITY Transformation Framework PED Relevant Case Study / PED Lab Compare
Kladno, Sletiště (Sport Area), PED Winter Stadium SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Relevant Case Study Compare
Groningen, PED South MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Lab Compare
Groningen, PED North MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Lab Compare
Maia, Sobreiro Social Housing SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Lab Compare
Lubia (Soria), CEDER-CIEMAT PED Lab Uncompare
Tampere, Ilokkaanpuisto district STARDUST – Holistic and Integrated Urban Model for Smart Cities PED Relevant Case Study Compare
Leon, Former Sugar Factory district MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Case Study Compare
Istanbul, Kadikoy district, Caferaga MAKING-CITY – Energy efficient pathway for the city transformation: enabling a positive future PED Case Study Compare
Espoo, Leppävaara district, Sello center SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Case Study Compare
Espoo, Espoonlahti district, Lippulaiva block SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Case Study Compare
Salzburg, Gneis district Syn.ikia – Sustainable Plus Energy Neighbourhoods PED Case Study Compare
Barcelona, Santa Coloma de Gramenet Syn.ikia – Sustainable Plus Energy Neighbourhoods PED Case Study Compare
Tartu, City centre area SmartEnCity – Towards Smart Zero CO2 Cities across Europe PED Relevant Case Study / PED Lab Compare
Bologna, Pilastro-Roveri district GRETA – GReen Energy Transition Actions PED Relevant Case Study Compare
Barcelona, SEILAB & Energy SmartLab PED Lab Uncompare
Leipzig, Baumwollspinnerei district SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Case Study Compare
Kifissia, Energy community SPARCS – Sustainable energy Positive & zero cARbon CommunitieS PED Relevant Case Study
TitleKifissia, Energy community
Riga, Ķīpsala, RTU smart student city
Borlänge, Rymdgatan’s Residential Portfolio
Lubia (Soria), CEDER-CIEMAT
Barcelona, SEILAB & Energy SmartLab
Schönbühel-Aggsbach, Schönbühel an der Donau
Izmir, District of Karşıyaka
A1P001: Name of the PED case study / PED Lab
A1P001: Name of the PED case study / PED LabKifissia, Energy communityRiga, Ķīpsala, RTU smart student cityBorlänge, Rymdgatan’s Residential PortfolioLubia (Soria), CEDER-CIEMATBarcelona, SEILAB & Energy SmartLabSchönbühel-Aggsbach, Schönbühel an der DonauIzmir, District of Karşıyaka
A1P002: Map / aerial view / photos / graphic details / leaflet
A1P002: Map / aerial view / photos / graphic details / leaflet
A1P003: Categorisation of the PED site
PED case studynoyesnonononoyes
PED relevant case studyyesnoyesnonoyesno
PED Lab.nononoyesyesnono
A1P004: Targets of the PED case study / PED Lab
Climate neutralitynoyesyesnonoyesyes
Annual energy surplusnonoyesnononoyes
Energy communityyesyesyesnoyesyesno
Circularitynonononononono
Air quality and urban comfortyesnonoyesnonoyes
Electrificationyesnoyesnoyesnono
Net-zero energy costnononononoyesyes
Net-zero emissionnononoyesyesnono
Self-sufficiency (energy autonomous)noyesnoyesyesnono
Maximise self-sufficiencynoyesyesnonoyesyes
Othernonononoyesnono
Other (A1P004)Green IT
A1P005: Phase of the PED case study / PED Lab
A1P005: Project Phase of your case study/PED LabPlanning PhasePlanning PhasePlanning PhaseImplementation PhaseIn operationImplementation PhasePlanning Phase
A1P006: Start Date
A1P006: Start date01/2411/1901/201110/22
A1P007: End Date
A1P007: End date12/2612/2302/201310/25
A1P008: Reference Project
A1P008: Reference Project
A1P009: Data availability
A1P009: Data availability
  • Monitoring data available within the districts,
  • Meteorological open data,
  • General statistical datasets,
  • GIS open datasets
  • Open data city platform – different dashboards
  • General statistical datasets
  • General statistical datasets
  • Monitoring data available within the districts
  • Monitoring data available within the districts
A1P009: OtherOther
A1P010: Sources
Any publication, link to website, deliverable referring to the PED/PED Lab
      • http://www.ceder.es/redes-inteligentes,
      • O. Izquierdo-Monge, Paula Peña-Carro et al. Conversion of a network section with loads, storage systems and renewable generation sources into a smart microgrid. Appl. Sci. 2021, 11(11), 5012. https://doi.org/10.3390/app11115012,
      • O. Izquierdo-Monge, Paula Peña-Carro et al. A Methodology for the Conversion of a Network Section with Generation Sources, Storage and Loads into an Electrical Microgrid Based on Raspberry Pi and Home Assistant. ICSC-Cities 2020, CCIS 1359 proceedings. Springer. https:// doi.org/10.1007/978-3-030-69136-3_1
        A1P011: Geographic coordinates
        X Coordinate (longitude):23.81458824.0816833915.394495-2.5082.115.396927.110049
        Y Coordinate (latitude):38.07734956.9524595660.48660941.60341.348.275238.496054
        A1P012: Country
        A1P012: CountryGreeceLatviaSwedenSpainSpainAustriaTurkey
        A1P013: City
        A1P013: CityMunicipality of KifissiaRigaBorlängeLubia - SoriaBarcelona and TarragonaSchönbühel an der Donauİzmir
        A1P014: Climate Zone (Köppen Geiger classification)
        A1P014: Climate Zone (Köppen Geiger classification).CsaCfbDsbCfbCsaDfbCsa
        A1P015: District boundary
        A1P015: District boundaryVirtualGeographicGeographicGeographicVirtualGeographicGeographic
        OtherThe energy will be produced by a PV plant installed on the terrace of a municipal building. Members of the energy community (that is under formation) will benefit from the energy produced via virtual net metering. PV instalment and the buildings (owned by the members of the community) will be within the boundaries of the Municipality but not necessary in the same area/district/neighbourhood
        A1P016: Ownership of the case study/PED Lab
        A1P016: Ownership of the case study/PED Lab:PublicMixedPublicPublicPrivatePrivate
        A1P017: Ownership of the land / physical infrastructure
        A1P017: Ownership of the land / physical infrastructure:Multiple OwnersSingle OwnerSingle OwnerSingle OwnerMultiple OwnersMultiple Owners
        A1P018: Number of buildings in PED
        A1P018: Number of buildings in PED151060021
        A1P019: Conditioned space
        A1P019: Conditioned space [m²]1700003700477102795
        A1P020: Total ground area
        A1P020: Total ground area [m²]11926499456400000245032600
        A1P021: Floor area ratio: Conditioned space / total ground area
        A1P021: Floor area ratio: Conditioned space / total ground area0100003
        A1P022: Financial schemes
        A1P022a: Financing - PRIVATE - Real estatenononononoyesno
        A1P022a: Add the value in EUR if available [EUR]
        A1P022b: Financing - PRIVATE - ESCO schemenonononononono
        A1P022b: Add the value in EUR if available [EUR]
        A1P022c: Financing - PRIVATE - Othernonononononono
        A1P022c: Add the value in EUR if available [EUR]
        A1P022d: Financing - PUBLIC - EU structural fundingnonononononono
        A1P022d: Add the value in EUR if available [EUR]
        A1P022e: Financing - PUBLIC - National fundingnononononoyesno
        A1P022e: Add the value in EUR if available [EUR]
        A1P022f: Financing - PUBLIC - Regional fundingnononononoyesno
        A1P022f: Add the value in EUR if available [EUR]
        A1P022g: Financing - PUBLIC - Municipal fundingnonononononono
        A1P022g: Add the value in EUR if available [EUR]
        A1P022h: Financing - PUBLIC - Othernonononononono
        A1P022h: Add the value in EUR if available [EUR]
        A1P022i: Financing - RESEARCH FUNDING - EUnoyesnonononoyes
        A1P022i: Add the value in EUR if available [EUR]75000001193355
        A1P022j: Financing - RESEARCH FUNDING - Nationalnononoyesnonoyes
        A1P022j: Add the value in EUR if available [EUR]
        A1P022k: Financing - RESEARCH FUNDING - Local/regionalnononoyesnonono
        A1P022k: Add the value in EUR if available [EUR]
        A1P022l: Financing - RESEARCH FUNDING - Othernonononononono
        A1P022l: Add the value in EUR if available [EUR]
        A1P022: Other
        A1P023: Economic Targets
        A1P023: Economic Targets
        • Boosting local businesses,
        • Boosting local and sustainable production
        • Positive externalities,
        • Boosting local businesses,
        • Boosting consumption of local and sustainable products
        • Boosting local and sustainable production,
        • Boosting consumption of local and sustainable products
        • Job creation,
        • Boosting local and sustainable production
        • Positive externalities,
        • Boosting local and sustainable production
        A1P023: Other
        A1P024: More comments:
        A1P024: More comments:The Centre for the Development of Renewable Energy (CEDER)is specialized in applied research, development and promotion of renewable energy. Among the facilities of this Centre, the urban laboratory CEDER-CIEMAT assess the performance of different configurations of energy networks at the district level. This PED-Lab infrastructure is an energy district that connects six office buildings with energy generation installations by means of two energy rings: electrical grid (in operation phase) and thermal network (in the implementation phase). The buildings of this PED Lab can act as energy demanders or suppliers depending on the climatic and operational conditions. The majority of these buildings are constructed with conventional technologies but some of them are implemented with efficient and sustainable measures. The thermal network is composed by two biomass boilers, 300 kW power each, and water tanks with 90 kWh of thermal storage. This network will shortly be expanded with a low temperature (90°C) and high temperature (150°-250°C) rings. The low-temperature ring is made up by two Stirling engine cogeneration boilers (one biomass gasification boiler and one gas boiler). The high-temperature ring has a thermal generator made up of Fresnel solar concentrators and an ORC cogeneration system fed directly from the solar concentrator. The high-temperature ring is interconnected with the low-temperature ring through an oil/water heat exchanger. This network has thermal storage systems in the modalities of: aquifers, boreholes, phase change materials, cold storage with geothermal exchange ground recovery and thermal storage at very low temperature with zeolites. The electrical grid incorporates different renewable generation technologies (50 kW wind turbine and eight different photovoltaic systems, a reversible hydraulic system), and engine generator of 100 kVA, electricity storages (batteries) and flexible loads.Semi-Virtual Energy Integration Laboratory (SEILAB) The Energy Smart Lab is an infrastructure conceived as a flexible and versatile platform for innovative technological developments for both industry and competitive R+D projects. The areas of expertise of this laboratory pivot around the following technologies: – Power Electronics for the integration and control of the elements within a building or community: Renewable Energy Sources (RES), Energy Storage Systems and Electric Vehicles (EV) – ICT Platform for smart communications and energy management of systems, building, networks and communities. – Energy System Integration technologies for smart and flexible buildings and grids including RES and EV. The laboratory operation is based on the hardware emulation approach, which allows for real physical equipment to be operated under a broad range of scenarios without depending on the real occurrence of the boundary conditions suitable for the experimental validation. The laboratory is pioneer in addressing the concept and implementation of Microgrids and aims to become a leading experimental facility for improving the optimal development of Flexible Energy Buildings and Flexibility Aggregation.
        A1P025: Estimated PED case study / PED LAB costs
        A1P025: Estimated PED case study / PED LAB costs [mil. EUR]
        Contact person for general enquiries
        A1P026: NameArtemis Giavasoglou, Kleopatra KalampokaJudith StiekemaJingchun ShenDr. Raquel RamosDr. Jaume Salom, Dra. Cristina CorcheroGhazal EtminanOzlem Senyol
        A1P027: OrganizationMunicipality of Kifissia – SPARCS local teamOASCHögskolan DalarnaCentre for the Development of Renewable Energy (CEDER) - Centre for Energy, Environment and Technology Research (CIEMAT)IRECGhazal.Etminan@ait.ac.atKarsiyaka Municipality
        A1P028: AffiliationMunicipality / Public BodiesOtherResearch Center / UniversityResearch Center / UniversityResearch Center / UniversityResearch Center / UniversityMunicipality / Public Bodies
        A1P028: Othernot for profit private organisation
        A1P029: Emailgiavasoglou@kifissia.grjudith@oascities.orgjih@du.seraquel.ramos@ciemat.esJsalom@irec.catGhazal.Etminan@ait.ac.atozlemkocaer2@gmail.com
        Contact person for other special topics
        A1P030: NameStavros Zapantis - vice mayorXingxing ZhangDr. Oscar SecoHasan Burak Cavka
        A1P031: Emailstavros.zapantis@gmail.comxza@du.seoscar.seco@ciemat.eshasancavka@iyte.edu.tr
        Pursuant to the General Data Protection RegulationYesYesYesYesYesYes
        A2P001: Fields of application
        A2P001: Fields of application
        • Energy production
        • Energy efficiency,
        • Energy flexibility,
        • Energy production,
        • E-mobility,
        • Digital technologies
        • Energy efficiency,
        • Energy flexibility,
        • Energy production,
        • E-mobility,
        • Construction materials
        • Energy efficiency,
        • Energy flexibility,
        • Energy production,
        • Digital technologies,
        • Indoor air quality
        • Energy efficiency,
        • Energy flexibility,
        • Energy production,
        • E-mobility,
        • Digital technologies
        • Energy efficiency,
        • Energy flexibility,
        • Energy production,
        • E-mobility
        • Energy efficiency,
        • Energy flexibility,
        • Energy production,
        • Urban comfort (pollution, heat island, noise level etc.)
        A2P001: Other
        A2P002: Tools/strategies/methods applied for each of the above-selected fields
        A2P002: Tools/strategies/methods applied for each of the above-selected fieldsA suite of replicable modeling tools will enable stakeholders to analyze planning actions towards positive energy in a cost-effective fashion, aiding their evidence based decision-making process. The tools will be able to model the district’s energy production and demand, optimize for flexibility and simulate mobility and transport. By employing gamification and co-creation approaches, the project will enhance public awareness and engagement in energy efficiency. The project will culminate in the publication of practical guidelines, reusable models, algorithms, and training materials to aid other cities to replicate the digital twin for their districts, fostering widespread adoption of sustainable energy practices.Load calculation and system optimisation: City Energy Analyst Identification of stranded assets for asset owners and investors to understand the carbon risks: CRREMEnergy efficiency: - Buildings energy retrofit. Energy production: - Biomass Boiler capacity: 0.6 MW. Annual production: 1.2 GWh - Solar thermal collectors: 70 kW, planned extended to: 0.47MW - Geotermal & Absorption Pumps: 100 kW - Share of renewables after extension: 100% (30% solar thermal and 70% biomass) - AOC 50kW wind turbine. Awaiting installation of a two-way AC-AC converter for subsequent connection to the grid - Bornay Inclin 3 kW wind turbine, connected to 24 Vdc batteries, to be connected to the grid by means of Xantrex inverter/charger - 9kW photovoltaic park (66PV panels, brand BP Solar,type BP5140,of 140W) connected to the grid by means of two INGECON SUN 5 inverters - 5kW photovoltaic pergola (24PV panels, brand Solon, type P200, of 210W) connected to the grid by means of one INGECON SUN 5 inverter - 8.28kW photovoltaic roof (36PV panels, Brand LDK, type LDK-230P-20), connected to the grid by means of one INGECONSUN 10 inverter - 12kW photovoltaic roof (80PV panels, brand Gamesa, type GS-1501), connected to the grid. - Reversible hydraulic system connected to a 60 kW electric generator and a pumping system. -Stirling engine with a heat lamp based on natural gas, a helium cool lamp, 10kWe maximum power delivered and global performance of approximately 33%. Energy flexibility: - Thermal storage systems: water tanks 90kW, aquifers, boreholes, phase change materials, cold storage with geothermal exchange ground recovery and thermal storage at very low temperature with zeolites. - Electrical storage systems: batteries (lead-acid and lithium-ion). - Flexible loads. Control systems and Digital technologies: - Full monitoring campaign. - Smart-meters installation to monitor consumption and suggest another energy behaviours. - Dynamic simulation tools to optimize the energy performance. Urban comfort and air quality: - Meteorological stations to monitor the climate evolution. - Microclimatic simulation tools to quantify the thermal behaviour.Energy SmartLab capacities - Building simulation model: thermal inertia and thermal loads of a building or community can be co-simulated with a building model. – System Operator and Aggregator simulation models: the interaction with remote control actions carried out by electricity System Operators or flexibility Aggregators can be simulated as well. – Grid simulation model: the physical interaction of the building with the grid power supply can be simulated enabling the experimental validation of flexibility services to the network. Energy SmartLab systems - SAFT Li-ion battery: maximum stored energy 20000 Wh, rated power 150 kW, rated discharge current 200 A, rated charge current 34 A, operating voltage 189 V – 227 V – 254 V, capacity 82 Ah. – Ultracapacitors: maximum stored energy 57 Wh, rated power 10 kW, rated current 20 A, peak current (<1s) 200 Apk, operating voltage 250 V – 500 V, capacity 1,65 F. – Electric vehicle second life battery: maximum stored energy 23300 Wh, rated power 40 kW, rated current 150 A, operating voltage 240 V – 400 V, capacity 32 Ah - 5 microgrid emulators (emulated power 5.5 kVA, max generation connected 10kVA, max consumption connected 10 kVA) - 1 grid emulator (Rated power: 200 kVA, Rated current per phase: 350 A, Rated current per neutral conductor: 35)Energy modelingMethods involve studying the feasibility of digital PED references for the case cities about their energy, environmental, and economic performance by EnergyPlus tool. In case of insufficient energy data and the need of high resolution data, ‘Gaussian mixture model and expectation-maximization algorithm’ and ‘time-series decomposition-recombination’ method will be used to supplement data to EnergyPlus. The feasibility results will be returned to stakeholders for iterative discussion, and the iterative results will be used to update digital references. Replication plans are developed based on such a cooperation process for strategies to implement PEDs. If a PED is demonstrated during the project period, the measured data will be used to verify the feasibility model to optimize previous results (WP7– R3 & R4). In the MAKING-CITY project, the overall PED design method is developed, which will be further optimised in this project. In addition, PED-ACT will use the methods and knowledge, including how to choose a suitable PED in a city, energy balance calculation, and technologies available for PED. The RUGGEDISED project outputs the governance model into the replication plan in PED-ACT. Its ‘smart city open-data decision platform’ will illustrate an excellent example for the database in PED-ACT. The IEA EBC Annex 83 and Cost Action 19126 create the basis for data collection, developing existing PED databases, characterization of PED, and review of regulations of PED, as well as development of simulation tools. The UBEM project further enables a detailed high-resolution energy balance calculation of PED.
        A2P003: Application of ISO52000
        A2P003: Application of ISO52000NoNoNoNoYes
        A2P004: Appliances included in the calculation of the energy balance
        A2P004: Appliances included in the calculation of the energy balanceYesYesYesYesYesYes
        A2P005: Mobility included in the calculation of the energy balance
        A2P005: Mobility included in the calculation of the energy balanceYesNoNoYesNoNo
        A2P006: Description of how mobility is included (or not included) in the calculation
        A2P006: Description of how mobility is included (or not included) in the calculationThe university operates a fleet of 13 electric vehicles (EV) (61kW power each). There are 5 EV charging stations on campus.– Electric vehicle second life battery: maximum stored energy 23300 Wh, rated power 40 kW, rated current 150 A, operating voltage 240 V – 400 V, capacity 32 AhMobility is not included in the calculations.
        A2P007: Annual energy demand in buildings / Thermal demand
        A2P007: Annual energy demand in buildings / Thermal demand [GWh/annum]80000.67770.0663.862
        A2P008: Annual energy demand in buildings / Electric Demand
        A2P008: Annual energy demand in buildings / Electric Demand [GWh/annum]50000.036560.0121.226
        A2P009: Annual energy demand for e-mobility
        A2P009: Annual energy demand for e-mobility [GWh/annum]0
        A2P010: Annual energy demand for urban infrastructure
        A2P010: Annual energy demand for urban infrastructure [GWh/annum]0
        A2P011: Annual renewable electricity production on-site during target year
        A2P011: PVyesnonoyesyesyesyes
        A2P011: PV - specify production in GWh/annum [GWh/annum]1.028
        A2P011: Windnoyesnoyesnonono
        A2P011: Wind - specify production in GWh/annum [GWh/annum]
        A2P011: Hydronononoyesnonono
        A2P011: Hydro - specify production in GWh/annum [GWh/annum]
        A2P011: Biomass_elnononoyesnonono
        A2P011: Biomass_el - specify production in GWh/annum [GWh/annum]
        A2P011: Biomass_peat_elnonononononono
        A2P011: Biomass_peat_el - specify production in GWh/annum [GWh/annum]
        A2P011: PVT_elnoyesyesnononono
        A2P011: PVT_el - specify production in GWh/annum [GWh/annum]0.01818
        A2P011: Othernonononononono
        A2P011: Other - specify production in GWh/annum [GWh/annum]
        A2P012: Annual renewable thermal production on-site during target year
        A2P012: Geothermalnononoyesnonono
        A2P012 - Geothermal: Please specify production in GWh/annum [GWh/annum]
        A2P012: Solar Thermalnononoyesnonono
        A2P012 - Solar Thermal: Please specify production in GWh/annum [GWh/annum]
        A2P012: Biomass_heatnoyesnoyesnonono
        A2P012 - Biomass_heat: Please specify production in GWh/annum [GWh/annum]
        A2P012: Waste heat+HPnononoyesnonono
        A2P012 - Waste heat+HP: Please specify production in GWh/annum [GWh/annum]
        A2P012: Biomass_peat_heatnonononononono
        A2P012 - Biomass_peat_heat: Please specify production in GWh/annum [GWh/annum]
        A2P012: PVT_thnonoyesnononono
        A2P012 - PVT_th: Please specify production in GWh/annum [GWh/annum]0.0825
        A2P012: Biomass_firewood_thnononoyesnonono
        A2P012 - Biomass_firewood_th: Please specify production in GWh/annum [GWh/annum]
        A2P012: Othernonononononono
        A2P012 - Other: Please specify production in GWh/annum [GWh/annum]
        A2P013: Renewable resources on-site - Additional notes
        A2P013: Renewable resources on-site - Additional notesConventional power generation: The university’s heat supply is designed as a local centralized heat supply system. Electrical power, generated in combined heat and power (CHP) units, is delivered to the distribution network and sold to energy traders as regulated by local legislation and norms. There are two natural gas burners acting as heat sources (3MW and 6MW capacity), and two CHP units (1.6MW and 0.45MW thermal capacity). All heating is supplied from the CHP plants. Renewable Energy Sources (RES): a wind turbine (3.6 kW) and PV panels (11.7 kW) are connected to the faculty microgrid. In the future it is planned to power the campus entirely from local RES.
        A2P014: Annual energy use
        A2P014: Annual energy use [GWh/annum]0.3180.0795.088
        A2P015: Annual energy delivered
        A2P015: Annual energy delivered [GWh/annum]0.20550.0011
        A2P016: Annual non-renewable electricity production on-site during target year
        A2P016: Annual non-renewable electricity production on-site during target year [GWh/annum]0
        A2P017: Annual non-renewable thermal production on-site during target year
        A2P017: Gasnoyesnonoyesnoyes
        A2P017 - Gas: Annual non-renewable thermal production on-site during target year [GWh/annum]
        A2P017: Coalnonononononono
        A2P017 - Coal: Annual non-renewable thermal production on-site during target year [GWh/annum]
        A2P017: Oilnonononononono
        A2P017 - Oil: Annual non-renewable thermal production on-site during target year [GWh/annum]
        A2P017: Othernonoyesnononono
        A2P017 - Other: Annual non-renewable thermal production on-site during target year [GWh/annum]0
        A2P018: Annual renewable electricity imports from outside the boundary during target year
        A2P018: PVnononononoyesyes
        A2P018 - PV: specify production in GWh/annum if available [GWh/annum]0.707
        A2P018: Windnononononoyesno
        A2P018 - Wind: specify production in GWh/annum if available [GWh/annum]
        A2P018: Hydronononononoyesno
        A2P018 - Hydro: specify production in GWh/annum if available [GWh/annum]
        A2P018: Biomass_elnononononoyesno
        A2P018 - Biomass_el: specify production in GWh/annum if available [GWh/annum]
        A2P018: Biomass_peat_elnonononononono
        A2P018 - Biomass_peat_el: specify production in GWh/annum if available [GWh/annum]
        A2P018: PVT_elnonononononono
        A2P018 - PVT_el: specify production in GWh/annum if available [GWh/annum]
        A2P018: Othernonoyesnononono
        A2P018 - Other: specify production in GWh/annum if available [GWh/annum]0.187
        A2P019: Annual renewable thermal imports from outside the boundary during target year
        A2P019: Geothermalnonononononono
        A2P019 Geothermal: Please specify imports in GWh/annum [GWh/annum]
        A2P019: Solar Thermalnonononononono
        A2P019 Solar Thermal: Please specify imports in GWh/annum [GWh/annum]
        A2P019: Biomass_heatnonononononono
        A2P019 Biomass_heat: Please specify imports in GWh/annum [GWh/annum]
        A2P019: Waste heat+HPnonononononono
        A2P019 Waste heat+HP: Please specify imports in GWh/annum [GWh/annum]
        A2P019: Biomass_peat_heatnonononononono
        A2P019 Biomass_peat_heat: Please specify imports in GWh/annum [GWh/annum]
        A2P019: PVT_thnonononononono
        A2P019 PVT_th: Please specify imports in GWh/annum [GWh/annum]
        A2P019: Biomass_firewood_thnononononoyesno
        A2P019 Biomass_firewood_th: Please specify imports in GWh/annum [GWh/annum]
        A2P019: Othernonoyesnononono
        A2P019 Other: Please specify imports in GWh/annum [GWh/annum]0
        A2P020: Share of RES on-site / RES outside the boundary
        A2P020: Share of RES on-site / RES outside the boundary000.538395721925130001.4540311173975
        A2P021: GHG-balance calculated for the PED
        A2P021: GHG-balance calculated for the PED [tCO2/annum]6.934
        A2P022: KPIs related to the PED case study / PED Lab
        A2P022: Safety & Securitynone
        A2P022: Healththermal comfort diagram
        A2P022: Educationnone
        A2P022: Mobilitynone
        A2P022: Energynormalized CO2/GHG & Energy intensity
        A2P022: Water
        A2P022: Economic developmentcost of excess emissions
        A2P022: Housing and CommunitySpecify the associated KPIs
        A2P022: Waste
        A2P022: Other
        A2P023: Technological Solutions / Innovations - Energy Generation
        A2P023: Photovoltaicsnonoyesyesyesyesyes
        A2P023: Solar thermal collectorsnonoyesyesnonono
        A2P023: Wind Turbinesnononoyesnonono
        A2P023: Geothermal energy systemnonoyesyesnonono
        A2P023: Waste heat recoverynonoyesyesnonono
        A2P023: Waste to energynonononononono
        A2P023: Polygenerationnononoyesnonono
        A2P023: Co-generationnononoyesnonono
        A2P023: Heat Pumpnonoyesyesnoyesyes
        A2P023: Hydrogennononoyesnonono
        A2P023: Hydropower plantnononoyesnonono
        A2P023: Biomassnononoyesnonono
        A2P023: Biogasnonononononono
        A2P023: Other
        A2P024: Technological Solutions / Innovations - Energy Flexibility
        A2P024: A2P024: Information and Communication Technologies (ICT)noyesyesyesyesnono
        A2P024: Energy management systemnoyesnoyesyesyesno
        A2P024: Demand-side managementnoyesnoyesnonono
        A2P024: Smart electricity gridnoyesnoyesyesnono
        A2P024: Thermal Storagenoyesyesyesnonono
        A2P024: Electric Storagenoyesnoyesyesnono
        A2P024: District Heating and Coolingnoyesyesyesnonono
        A2P024: Smart metering and demand-responsive control systemsnoyesnoyesnonono
        A2P024: P2P – buildingsnononononoyesno
        A2P024: Other
        A2P025: Technological Solutions / Innovations - Energy Efficiency
        A2P025: Deep Retrofittingnonoyesyesnoyesyes
        A2P025: Energy efficiency measures in historic buildingsnononononoyesno
        A2P025: High-performance new buildingsnonononononono
        A2P025: Smart Public infrastructure (e.g. smart lighting)nonononononono
        A2P025: Urban data platformsnoyesnonononono
        A2P025: Mobile applications for citizensnoyesnonononono
        A2P025: Building services (HVAC & Lighting)noyesyesyesyesnoyes
        A2P025: Smart irrigationnonononononono
        A2P025: Digital tracking for waste disposalnonononononono
        A2P025: Smart surveillancenonononononono
        A2P025: Other
        A2P026: Technological Solutions / Innovations - Mobility
        A2P026: Efficiency of vehicles (public and/or private)nonononoyesnono
        A2P026: Measures to reduce traffic volume (e.g. measure to support public transportation, shared mobility, measure to reduce journeys and distances)nonononononono
        A2P026: e-Mobilitynonononononono
        A2P026: Soft mobility infrastructures and last mile solutionsnonononononono
        A2P026: Car-free areanononoyesnonono
        A2P026: Other
        A2P027: Mobility strategies - Additional notes
        A2P027: Mobility strategies - Additional notes
        A2P028: Energy efficiency certificates
        A2P028: Energy efficiency certificatesNoNoYesYesNo
        A2P028: If yes, please specify and/or enter notesEnergy Performance Certificate - in Greece it is mandatory in order to buy or rent a house or a dwellingIn Spain it is mandatory the Energy Performance Certificate in order to buy or rent a house or a dwelling
        A2P029: Any other building / district certificates
        A2P029: Any other building / district certificatesNoNoNoNoNo
        A2P029: If yes, please specify and/or enter notes
        A3P001: Relevant city /national strategy
        A3P001: Relevant city /national strategy
        • Energy master planning (SECAP, etc.),
        • Promotion of energy communities (REC/CEC)
        • Smart cities strategies,
        • Promotion of energy communities (REC/CEC),
        • Climate change adaption plan/strategy (e.g. Climate City contract),
        • National / international city networks addressing sustainable urban development and climate neutrality
        • Promotion of energy communities (REC/CEC),
        • Climate change adaption plan/strategy (e.g. Climate City contract)
        • Smart cities strategies,
        • New development strategies,
        • Promotion of energy communities (REC/CEC),
        • Climate change adaption plan/strategy (e.g. Climate City contract)
        • Smart cities strategies,
        • New development strategies
        • Promotion of energy communities (REC/CEC)
        • Energy master planning (SECAP, etc.),
        • Climate change adaption plan/strategy (e.g. Climate City contract),
        • National / international city networks addressing sustainable urban development and climate neutrality
        A3P002: Quantitative targets included in the city / national strategy
        A3P002: Quantitative targets included in the city / national strategyThe study aligns closely with the decarbonisation and energy reduction pathways of residential multi family buildings with 1.5°C global warming target in Sweden. This study will also contribute to the achievement of the carbon neturality of whole Borlänge city by 2030.- Testing the combination of renewable technologies at district level. - Optimization of the generation side based on the weather forecasting and demand side. - Optimization of the control system, connected to the central node, to design and perform virtual analyses based on the combination of all the systems and infrastructures. - Optimization of ICT systems. - Design and management of a virtual analysis - Optimization of efficient measures: building performance, user´s behaviour… - Combination of flexible storage systems to operate the global installation.Karşıyaka Municipality is the first local government in Turkey to sign the Covenant of Mayors in 2011. During this period, the greenhouse gas inventory of the district was carried out three times and reduction targets were set for 2020 and 2030. In the 2021 Sustainable Energy and Climate Action Plan prepared as of the end of 2021, Karşıyaka Municipality has targeted a 40% reduction in its emissions for 2030 compared to the base year 2018. In the 2021 Sustainable Energy and Climate Action Plan, Karşıyaka Municipality aims to reduce its greenhouse gas emissions from 3.96 tCO2e / person in 2018 to 2.37 tCO2e / person in 2030. System solutions such as the use of renewable energy sources, air, ground or water source heat pump, cogeneration and microcogeneration are analysed by designers in order to fully or partially meet the energy requirements for heating, cooling, ventilation, hot water, electricity and lighting for all buildings with a floor area of less than 20,000 square metres. If at least 50% of the building's total energy consumption costs are covered by one or more of these applications, the points are taken in the assessment table in the Building and housing estate business certification guide of 2023.
        A3P003: Strategies towards decarbonization of the gas grid
        A3P003: Strategies towards decarbonization of the gas grid
        • Electrification of Heating System based on Heat Pumps,
        • Biogas,
        • Hydrogen
        • Electrification of Heating System based on Heat Pumps
        A3P003: Other
        A3P004: Identification of needs and priorities
        A3P004: Identification of needs and prioritiesIn our project, we carried out a comprehensive exploration of strategies to achieve positive energy districts in a Swedish residential portfolio. The focus on urban energy transitions necessitates a holistic approach that integrates building retrofit, solar technology exploration, and heating supply optimisation. Exploration of Local Solar Sources: The analysis reveals varying solar irradiance resources throughout the year, emphasizing the importance of strategic placement. Integration of combined photovoltaic and thermal panels into building envelopes demonstrates the potential to cover a significant portion of the energy demand even in Sweden. Heating Supply Optimisation with Solar Technologies: Despite the surplus energy production from on-site solar technology, challenges arise due to temporal energy asymmetry. The introduction of heat pumps emerges as a feasible solution to balance energy gaps, utilising both rejected and free heat. Optimisation scenarios, utilising a combination of geothermal heat pumps, water source heat pumps, and PVT, showcase remarkable reductions in emissions and primary energy consumption. Urban Form and Energy Infrastructure Design: We realised the importance of returning to urban form and energy infrastructure design to optimise future residential portfolio potential. Building layout design, influenced by zoning regulations and innovative typologies, plays a crucial role in achieving district level energy efficiency. Future challenges, including demographic shifts, e-mobility, and climate change, necessitate a more holistic approach to energy infrastructure design, addressing not only heating and electricity demands but also cooling requirements.- Create a thermal energy storage tank to be used for air conditioning the buildings. - Some buildings need to be renovated both to increase the energy performance, the seismic behaviour and spaces liveability and comfort. - Optimizing the coupling between technologies. - Guarantee the flexibility to operate the renewable installations to operate in different phases and with different configurations. - CEDER is a public research center and needs to have connected any energy system to the same grid. - CEDER has an industrial develop area where some experimental thermal storage system could be tested.-Allows for real physical equipment to be operated under a broad range of scenarios without depending on the real occurrence of the boundary conditions suitable for the experimental validation -Pioneer in addressing the concept and implementation of Microgrids and aims to become a leading experimental facility for improving the optimal development of Flexible Energy Buildings and Flexibility Aggregation.According to the model developed for the district, the electrification of heating and cooling is necessary.Therefore, there needs to be the implementation of a heat pump. The building-integrated photovoltaic panelsshould follow. Through net-metering practices, the district is expected to reach energy positivity throughthis scenario.
        A3P005: Sustainable behaviour
        A3P005: Sustainable behaviourWhile our investigation primarily centres on technical optimisation within Positive Energy District (PED) development, it is essential to acknowledge the broader scope encompassing social and governance dimensions. Specifically, understanding stakeholders' willingness to embrace technical recommendations upon project completion is important. Several potential influencing factors merit exploration, including economic considerations, technical optimisation-associated embodied carbon balance, the general public's technical perceptions, and operational feasibility. Evaluating these aspects holistically not only enhances the efficacy of PED initiatives but also fosters greater acceptance and participation within the communities they serve.- Minimize the building energy consumption while maintaining indoor comfort levels. - Onsite renewable production with flexible storage elements to fix demand side and generation side. - Flexible control solutions through digitalization systems.-Improving the development of Net Zero Energy Buildings and Flexible Energy buildings.
        A3P006: Economic strategies
        A3P006: Economic strategies
        • Open data business models,
        • Innovative business models,
        • Demand management Living Lab
        • Open data business models,
        • Life Cycle Cost,
        • Circular economy models,
        • Local trading
        • Demand management Living Lab
        • Demand management Living Lab
        • Local trading,
        • Existing incentives
        A3P006: Other
        A3P007: Social models
        A3P007: Social models
        • Strategies towards (local) community-building,
        • Co-creation / Citizen engagement strategies
        • Strategies towards (local) community-building,
        • Behavioural Change / End-users engagement,
        • Social incentives,
        • Affordability,
        • Digital Inclusion
        • Digital Inclusion,
        • Educational activities and trainings (including capacity building towards technology literacy, energy efficient behaviour)
        • Digital Inclusion,
        • Educational activities and trainings (including capacity building towards technology literacy, energy efficient behaviour)
        • Strategies towards (local) community-building,
        • Co-creation / Citizen engagement strategies,
        • Behavioural Change / End-users engagement,
        • Quality of Life,
        • Citizen/owner involvement in planning and maintenance,
        • Educational activities and trainings (including capacity building towards technology literacy, energy efficient behaviour)
        • Strategies towards (local) community-building,
        • Co-creation / Citizen engagement strategies,
        • Affordability
        A3P007: Other
        A3P008: Integrated urban strategies
        A3P008: Integrated urban strategies
        • Digital twinning and visual 3D models
        • Strategic urban planning,
        • Digital twinning and visual 3D models,
        • District Energy plans,
        • Building / district Certification
        • District Energy plans,
        • Building / district Certification
        • Digital twinning and visual 3D models,
        • District Energy plans,
        • SECAP Updates
        A3P008: Other
        A3P009: Environmental strategies
        A3P009: Environmental strategies
        • Energy Neutral
        • Low Emission Zone,
        • Net zero carbon footprint,
        • Life Cycle approach,
        • Sustainable Urban drainage systems (SUDS)
        • Energy Neutral,
        • Low Emission Zone,
        • Pollutants Reduction,
        • Greening strategies
        • Energy Neutral,
        • Low Emission Zone,
        • Pollutants Reduction,
        • Greening strategies
        • Low Emission Zone,
        • Net zero carbon footprint,
        • Carbon-free
        • Energy Neutral,
        • Low Emission Zone,
        • Pollutants Reduction
        A3P009: Other
        A3P010: Legal / Regulatory aspects
        A3P010: Legal / Regulatory aspects- European Commission has legislated on Energy Community (Renewable energy directive - 2018/2001/EU and Common rules for the internal electricity market directive- 2019/944/EU). - Spanish building certification is regulated through Royal Decree 235/2013.- European Commission has legislated on Energy Community (‘Renewable energy’ directive - 2018/2001/EU and ‘Common rules for the internal electricity market’ directive- 2019/944/EU). - Spanish building certification is regulated through Royal Decree 235/2013.
        B1P001: PED/PED relevant concept definition
        B1P001: PED/PED relevant concept definitionExPEDite aims at creating and deploying a novel digital twin, allowing for real-time monitoring, visualization and management of district-level energy flows. Cities consume 65% of the world’s energy supply and are responsible for 70% of the CO² emissions, hence sharing a lot of the responsibility for climate change. We are faced with the challenge of redesigning our existing cities to make them more sustainable, resilient, inclusive and safe. Developing Positive Energy Districts (PEDs), is a breakthrough way to deal with the issue of urban emissions and applying adaptation and mitigation strategies to climate change, while ensuring that these urban areas generate an annual surplus of renewable energy and net zero greenhouse gas emissions. PEDs must address environmental, economic and social issues, providing solutions to energy consumption, production, emissions, transport & mobility and livability. By constantly monitoring and evaluating parameters through existing and/or novel sensor systems (e.g., renewable energy production/supply, transport conditions, air quality, energy demand, meteorological conditions, etc.), unconventional techniques may be applied to provide more sustainable options for the district’s needs.The Rymdgatan's Residential Portfolio in Sweden presents a compelling case study for its classification as a PED-related research, given its alignment with sustainable behaviours and overarching PED development principles as follows: Inclusivity and Social Equity: The residential portfolio situated in Rymdgatan caters primarily to a low-income community. By focusing on this demographic, the project addresses critical aspects of social equity within sustainable urban development. Ensuring access to energy-efficient housing and amenities for economically disadvantaged populations not only fosters social cohesion but also mitigates energy poverty, a pressing concern in many urban contexts. Multifamily Residential Building: The inclusion of multifamily residential buildings within the portfolio underscores a commitment to density and efficient land use, both essential components of sustainable urban design. Such developments promote resource optimisation by consolidating housing units, thereby reducing per capita energy consumption and infrastructure demands. Moreover, multifamily dwellings often facilitate community engagement and shared resource management, fostering a culture of sustainability among residents. Low Carbon Retrofitting and Transition: The overarching initiative to transition the entire Jakobsgårdarna district. The included Rymdgatan portfolio, towards low carbon retrofitting, represents a significant example of decarbonization and climate resilience. By integrating energy-efficient technologies and renewable energy solutions into existing infrastructure, the project not only reduces carbon emissions but also serves as a blueprint for revitalising old urban environments sustainably. This holistic approach to retrofitting demonstrates a systemic commitment to environmental stewardship and long-term sustainability. Climate Adaptation and Renewable Energy Integration: Despite Sweden's climatic challenges, including lower solar resources during winter months, the Rymdgatan project leverages its geographical context to optimize renewable energy utilization. Sweden's greater solar resource availability during summer and geothermal potentials complement the design's emphasis on seasonal energy planning, where surplus energy generated during peak periods can be stored or redistributed efficiently. By embracing climate-responsive design strategies, the project demonstrates resilience in the face of climate variability while harnessing renewable energy potential effectively.The pilot area was selected on the basis of several criteria: its location within areas prioritised by Karşıyaka Municipality for combating climate change, compliance with the building regulations set out in the Green Building-Site-Operation (2023) guide, which are in line with Municipality's energy policy, the presence of open spaces that allow various applications for renewable energy, proximity to public facilities such as schools and municipal services, the availability of data on energy consumption (e.g. electricity and natural gas bills) and architectural features, the potential for community building, the suitability for solar energy systems, considering orientation and roof structure, and the potential for future building renovations. The aim of the initiative is to explore the feasibility of transforming the district into a Positive Energy District (PED).
        B1P002: Motivation behind PED/PED relevant project development
        B1P002: Motivation behind PED/PED relevant project developmentExpected outcome 1 Increased number of (tangible) city planning actions for positive clean energy districts using the (proto-)PED design, development and management digital twin tools (based on pre-market research learnings) using open-standards based components which can be reused elsewhere. 2 Increased integration of existing smaller scale management systems (e.g. Building management systems) with open-standards based operational city platforms using sectorial data (e.g. building data, mobility, urban planning, etc.). 3 Enhanced data gathering approaches with identification of relevant multidimensional data sets (e.g. meteorological, load profile, social, geo-spatial, etc.) high-resolution real-time data streams (e.g. renewable energy production, energy consumption), and relevant forecasting data, drawing also on the work of common European data spaces. 4 Increased number of city planning departments / approaches using common data and (replicable) elements and processes. 5 Consolidated city sensor network specifications, complemented by appropriate data gathering approaches for soft data. 6 Improved performance of AI based self-learning systems for optimization of positive clean energy districts and bottom-up complex models. 7 Enhanced innovation capacity of local/regional administrations and accelerated uptake of shared, smart and sustainable zero emission solutions.Borlänge city has committed to become the carbon-neutral city by 2030.
        B1P003: Environment of the case study area
        B2P003: Environment of the case study areaUrban areaUrban areaRuralRurbanUrban area
        B1P004: Type of district
        B2P004: Type of district
        • Renovation
        • Renovation
        • Renovation
        B1P005: Case Study Context
        B1P005: Case Study Context
        • Re-use / Transformation Area,
        • Retrofitting Area
        • Retrofitting Area,
        • Preservation Area
        • Retrofitting Area
        B1P006: Year of construction
        B1P006: Year of construction19902005
        B1P007: District population before intervention - Residential
        B1P007: District population before intervention - Residential100
        B1P008: District population after intervention - Residential
        B1P008: District population after intervention - Residential100
        B1P009: District population before intervention - Non-residential
        B1P009: District population before intervention - Non-residential6
        B1P010: District population after intervention - Non-residential
        B1P010: District population after intervention - Non-residential6
        B1P011: Population density before intervention
        B1P011: Population density before intervention0000000
        B1P012: Population density after intervention
        B1P012: Population density after intervention000.0106586224233280000
        B1P013: Building and Land Use before intervention
        B1P013: Residentialnonoyesnonoyesyes
        B1P013 - Residential: Specify the sqm [m²]4360102795
        B1P013: Officenononononoyesno
        B1P013 - Office: Specify the sqm [m²]
        B1P013: Industry and Utilitynonononononono
        B1P013 - Industry and Utility: Specify the sqm [m²]
        B1P013: Commercialnonononononono
        B1P013 - Commercial: Specify the sqm [m²]
        B1P013: Institutionalnonononononono
        B1P013 - Institutional: Specify the sqm [m²]
        B1P013: Natural areasnonononononono
        B1P013 - Natural areas: Specify the sqm [m²]
        B1P013: Recreationalnonononononono
        B1P013 - Recreational: Specify the sqm [m²]
        B1P013: Dismissed areasnonononononono
        B1P013 - Dismissed areas: Specify the sqm [m²]
        B1P013: Othernonoyesnononono
        B1P013 - Other: Specify the sqm [m²]706
        B1P014: Building and Land Use after intervention
        B1P014: Residentialnonoyesnonoyesyes
        B1P014 - Residential: Specify the sqm [m²]4360102795
        B1P014: Officenononononoyesno
        B1P014 - Office: Specify the sqm [m²]
        B1P014: Industry and Utilitynonononononono
        B1P014 - Industry and Utility: Specify the sqm [m²]
        B1P014: Commercialnonononononono
        B1P014 - Commercial: Specify the sqm [m²]
        B1P014: Institutionalnonononononono
        B1P014 - Institutional: Specify the sqm [m²]
        B1P014: Natural areasnonononononono
        B1P014 - Natural areas: Specify the sqm [m²]
        B1P014: Recreationalnonononononono
        B1P014 - Recreational: Specify the sqm [m²]
        B1P014: Dismissed areasnonononononono
        B1P014 - Dismissed areas: Specify the sqm [m²]
        B1P014: Othernonoyesnononono
        B1P014 - Other: Specify the sqm [m²]706
        B2P001: PED Lab concept definition
        B2P001: PED Lab concept definitionaddressing the concept and implementation of Microgrids and aims to become a leading experimental facility for improving the optimal development of Flexible Energy Buildings and Flexibility Aggregation
        B2P002: Installation life time
        B2P002: Installation life timeCEDER will follow an integrative approach including technology for a permanent installation.
        B2P003: Scale of action
        B2P003: ScaleDistrictVirtual
        B2P004: Operator of the installation
        B2P004: Operator of the installationCIEMAT. Data detail in contact: mariano.martin@ciemat.es and oscar.izquiedo@ciemat.esIREC
        B2P005: Replication framework: Applied strategy to reuse and recycling the materials
        B2P005: Replication framework: Applied strategy to reuse and recycling the materials
        B2P006: Circular Economy Approach
        B2P006: Do you apply any strategy to reuse and recycling the materials?NoNo
        B2P006: Other
        B2P007: Motivation for developing the PED Lab
        B2P007: Motivation for developing the PED Lab
        • Strategic
        • Strategic,
        • Private
        B2P007: Other
        B2P008: Lead partner that manages the PED Lab
        B2P008: Lead partner that manages the PED LabResearch center/UniversityResearch center/University
        B2P008: Other
        B2P009: Collaborative partners that participate in the PED Lab
        B2P009: Collaborative partners that participate in the PED Lab
        • Academia,
        • Industrial
        B2P009: Other
        B2P010: Synergies between the fields of activities
        B2P010: Synergies between the fields of activitiesThe operation of the laboratory with all the components of the energy networks requires a collaborative work between various departments and entities. On the one hand, it is necessary to optimize the operation of renewable systems based on the weather conditions, forecast of the demand side and the flexibility of the generation systems. On the other hand, the optimization of the energy demands through a more sustainable behaviour of both the building and the users want to be acquired. For this, it is necessary to take into account technical aspects but also market, comfort and encourage the user participation, creating a decision-making matrix that allows optimizing the operation of the global system.
        B2P011: Available facilities to test urban configurations in PED Lab
        B2P011: Available facilities to test urban configurations in PED Lab
        • Buildings,
        • Demand-side management,
        • Prosumers,
        • Renewable generation,
        • Energy storage,
        • Energy networks,
        • Efficiency measures,
        • Information and Communication Technologies (ICT),
        • Ambient measures,
        • Social interactions
        • Demand-side management,
        • Energy storage,
        • Energy networks,
        • Efficiency measures,
        • Information and Communication Technologies (ICT)
        B2P011: Other
        B2P012: Incubation capacities of PED Lab
        B2P012: Incubation capacities of PED Lab
        • Monitoring and evaluation infrastructure,
        • Tools for prototyping and modelling
        • Monitoring and evaluation infrastructure,
        • Tools for prototyping and modelling,
        • Tools, spaces, events for testing and validation
        B2P013: Availability of the facilities for external people
        B2P013: Availability of the facilities for external people
        B2P014: Monitoring measures
        B2P014: Monitoring measures
        • Equipment
        • Equipment
        B2P015: Key Performance indicators
        B2P015: Key Performance indicators
        • Energy,
        • Environmental,
        • Economical / Financial
        • Energy,
        • Environmental
        B2P016: Execution of operations
        B2P016: Execution of operations
        B2P017: Capacities
        B2P017: Capacities- Innovative grid configuration to connect bio boilers and solar thermal on buildings. - Environmental & air quality evaluation. - Testing and evaluation of high efficient heating & cooling systems: Gas, biomass, geothermal and absorption H&C pumps … - Definition and implementation of the different regulation modes for the global system. Using the data from the research focused-partners, several regulation modes for the DH network could be defined and implemented in order to obtain an optimal operation of the network. - Innovation in MPC control to enable harvesting 100% renewables in the most efficient way. - Physical integration of the technologies with the existing facilities at the living lab. - Connection between the solar thermal collectors to achieve the lowest heat losses, providing the possibility to use the grid as high or low temperature DH, according to the demand schedule of the buildings. - Test the bio-boiler of the last generation and ultra-low emissions biomass condensing boiler in order to increase efficiency and reduce GHG and air pollutant emissions of the DH plant. - Control of the supply temperature of the DH grid to enable 100% renewables harvesting in the most efficient way. - Research of the incidence of a normal building or a bioclimatic building in the DH grid demand. - Methodologies for concept validation: Definition of the minimum requirements to verify the suitability of the solutions proposed. - Tests campaign: Experimental operation and characterization in a relevant environment, to exploit the technologies at their best and test different demand profiles, different configuration and loads, with real time monitoring and continuous commissioning to control the performance of the technology. - Validation and upgrading recommendation for the DH&C at district level. - Evaluation of innovation actions for potential energy interventions with demand response in buildings. - The complete available infrastructure (MV and LV electric systems, transformation hubs, end consumption, generation sources, communication elements, etc.) belongs to CEDER-CIEMAT, making this the perfect scenario to test and try the performance of “Smart Grid” and “Microgrid” projects. - The type of electric grid, its voltage levels (MV or LV), its variety of real loads (different buildings with different profiles: industrial buildings, offices and so on) and its sources of renewable generation and storage, mean it is ideal for intermediate tests between a small-scale laboratory and final deployment of the real product.- Building simulation model: thermal inertia and thermal loads of a building or community can be co-simulated with a building model. – System Operator and Aggregator simulation models: the interaction with remote control actions carried out by electricity System Operators or flexibility Aggregators can be simulated as well. – Grid simulation model: the physical interaction of the building with the grid power supply can be simulated enabling the experimental validation of flexibility services to the network.
        B2P018: Relations with stakeholders
        B2P018: Relations with stakeholdersCEDER - CIEMAT is a public research body assigned to the Ministry of Science and Innovation under the General Secretariat for Research, focusing on energy and environment. To develop this lab CIEMAT has relations with private renewable companies, research centers and academia institutions.
        B2P019: Available tools
        B2P019: Available tools
        • Energy modelling
        • Energy modelling
        B2P019: Available tools
        B2P020: External accessibility
        B2P020: External accessibilityCIEMAT is a public body, so it´s open to any institution according the actual regulation and agreements.
        C1P001: Unlocking Factors
        C1P001: Recent technological improvements for on-site RES production5 - Very important5 - Very important4 - Important2 - Slightly important1 - Unimportant4 - Important5 - Very important
        C1P001: Innovative, integrated, prefabricated packages for buildings envelope / Energy efficiency of building stock5 - Very important5 - Very important5 - Very important5 - Very important1 - Unimportant2 - Slightly important4 - Important
        C1P001: Energy Communities, P2P, Prosumers concepts5 - Very important5 - Very important3 - Moderately important5 - Very important3 - Moderately important5 - Very important1 - Unimportant
        C1P001: Storage systems and E-mobility market penetration4 - Important3 - Moderately important2 - Slightly important5 - Very important4 - Important1 - Unimportant
        C1P001: Decreasing costs of innovative materials4 - Important4 - Important4 - Important1 - Unimportant3 - Moderately important3 - Moderately important5 - Very important
        C1P001: Financial mechanisms to reduce costs and maximize benefits4 - Important5 - Very important5 - Very important1 - Unimportant5 - Very important5 - Very important4 - Important
        C1P001: The ability to predict Multiple Benefits5 - Very important4 - Important3 - Moderately important4 - Important2 - Slightly important4 - Important
        C1P001: The ability to predict the distribution of benefits and impacts5 - Very important4 - Important4 - Important4 - Important3 - Moderately important4 - Important
        C1P001: Citizens improved awareness and engagement on sustainable energy issues (bottom-up)5 - Very important5 - Very important5 - Very important4 - Important1 - Unimportant3 - Moderately important2 - Slightly important
        C1P001: Social acceptance (top-down)5 - Very important4 - Important5 - Very important3 - Moderately important1 - Unimportant3 - Moderately important5 - Very important
        C1P001: Improved local and national policy frameworks (i.e. incentives, laws etc.)3 - Moderately important5 - Very important4 - Important3 - Moderately important1 - Unimportant5 - Very important5 - Very important
        C1P001: Presence of integrated urban strategies and plans3 - Moderately important4 - Important5 - Very important3 - Moderately important1 - Unimportant3 - Moderately important5 - Very important
        C1P001: Multidisciplinary approaches available for systemic integration3 - Moderately important5 - Very important5 - Very important2 - Slightly important4 - Important1 - Unimportant4 - Important
        C1P001: Availability of grants (from EC or other donors) to finance the PED Lab projects4 - Important5 - Very important4 - Important5 - Very important5 - Very important1 - Unimportant5 - Very important
        C1P001: Availability of RES on site (Local RES)4 - Important5 - Very important5 - Very important4 - Important1 - Unimportant5 - Very important
        C1P001: Ongoing or established collaboration on Public Private Partnership among key stakeholders4 - Important4 - Important2 - Slightly important3 - Moderately important5 - Very important4 - Important5 - Very important
        C1P001: Any other UNLOCKING FACTORS3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P001: Any other UNLOCKING FACTORS (if any)
        C1P002: Driving Factors
        C1P002: Climate Change adaptation need4 - Important5 - Very important5 - Very important4 - Important4 - Important5 - Very important5 - Very important
        C1P002: Climate Change mitigation need (local RES production and efficiency)5 - Very important4 - Important5 - Very important5 - Very important4 - Important5 - Very important5 - Very important
        C1P002: Rapid urbanization trend and need of urban expansions1 - Unimportant4 - Important3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant3 - Moderately important
        C1P002: Urban re-development of existing built environment3 - Moderately important4 - Important4 - Important5 - Very important4 - Important1 - Unimportant3 - Moderately important
        C1P002: Economic growth need2 - Slightly important4 - Important4 - Important3 - Moderately important4 - Important2 - Slightly important4 - Important
        C1P002: Improved local environmental quality (air, noise, aesthetics, etc.)3 - Moderately important4 - Important1 - Unimportant4 - Important4 - Important1 - Unimportant5 - Very important
        C1P002: Territorial and market attractiveness2 - Slightly important4 - Important1 - Unimportant3 - Moderately important1 - Unimportant3 - Moderately important5 - Very important
        C1P002: Energy autonomy/independence5 - Very important4 - Important2 - Slightly important4 - Important5 - Very important1 - Unimportant5 - Very important
        C1P002: Any other DRIVING FACTOR3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P002: Any other DRIVING FACTOR (if any)
        C1P003: Administrative barriers
        C1P003: Difficulty in the coordination of high number of partners and authorities4 - Important4 - Important4 - Important4 - Important4 - Important3 - Moderately important4 - Important
        C1P003: Lack of good cooperation and acceptance among partners3 - Moderately important4 - Important4 - Important2 - Slightly important1 - Unimportant3 - Moderately important3 - Moderately important
        C1P003: Lack of public participation3 - Moderately important4 - Important3 - Moderately important1 - Unimportant2 - Slightly important4 - Important5 - Very important
        C1P003: Lack of institutions/mechanisms to disseminate information3 - Moderately important3 - Moderately important4 - Important3 - Moderately important3 - Moderately important1 - Unimportant4 - Important
        C1P003:Long and complex procedures for authorization of project activities5 - Very important3 - Moderately important5 - Very important5 - Very important5 - Very important3 - Moderately important3 - Moderately important
        C1P003: Time consuming requirements by EC or other donors concerning reporting and accountancy4 - Important3 - Moderately important4 - Important4 - Important5 - Very important1 - Unimportant5 - Very important
        C1P003: Complicated and non-comprehensive public procurement4 - Important3 - Moderately important5 - Very important4 - Important3 - Moderately important1 - Unimportant5 - Very important
        C1P003: Fragmented and or complex ownership structure3 - Moderately important3 - Moderately important4 - Important5 - Very important5 - Very important5 - Very important5 - Very important
        C1P003: City administration & cross-sectoral attitude/approaches (silos)3 - Moderately important3 - Moderately important5 - Very important5 - Very important4 - Important2 - Slightly important5 - Very important
        C1P003: Lack of internal capacities to support energy transition3 - Moderately important3 - Moderately important5 - Very important4 - Important4 - Important3 - Moderately important5 - Very important
        C1P003: Any other Administrative BARRIER3 - Moderately important1 - Unimportant1 - Unimportant5 - Very important1 - Unimportant1 - Unimportant
        C1P003: Any other Administrative BARRIER (if any)
        C1P004: Policy barriers
        C1P004: Lack of long-term and consistent energy plans and policies4 - Important1 - Unimportant5 - Very important1 - Unimportant1 - Unimportant3 - Moderately important5 - Very important
        C1P004: Lacking or fragmented local political commitment and support on the long term4 - Important1 - Unimportant5 - Very important2 - Slightly important1 - Unimportant4 - Important4 - Important
        C1P004: Lack of Cooperation & support between national-regional-local entities3 - Moderately important1 - Unimportant4 - Important3 - Moderately important2 - Slightly important4 - Important5 - Very important
        C1P004: Any other Political BARRIER1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P004: Any other Political BARRIER (if any)
        C1P005: Legal and Regulatory barriers
        C1P005: Inadequate regulations for new technologies4 - Important4 - Important4 - Important4 - Important5 - Very important2 - Slightly important5 - Very important
        C1P005: Regulatory instability3 - Moderately important3 - Moderately important2 - Slightly important3 - Moderately important2 - Slightly important3 - Moderately important5 - Very important
        C1P005: Non-effective regulations4 - Important3 - Moderately important2 - Slightly important4 - Important2 - Slightly important3 - Moderately important5 - Very important
        C1P005: Unfavorable local regulations for innovative technologies3 - Moderately important4 - Important4 - Important2 - Slightly important4 - Important2 - Slightly important5 - Very important
        C1P005: Building code and land-use planning hindering innovative technologies4 - Important3 - Moderately important2 - Slightly important2 - Slightly important3 - Moderately important1 - Unimportant5 - Very important
        C1P005: Insufficient or insecure financial incentives4 - Important3 - Moderately important3 - Moderately important3 - Moderately important5 - Very important3 - Moderately important4 - Important
        C1P005: Unresolved privacy concerns and limiting nature of privacy protection regulation4 - Important3 - Moderately important2 - Slightly important4 - Important1 - Unimportant1 - Unimportant3 - Moderately important
        C1P005: Shortage of proven and tested solutions and examples3 - Moderately important4 - Important2 - Slightly important4 - Important1 - Unimportant3 - Moderately important
        C1P005: Any other Legal and Regulatory BARRIER3 - Moderately important1 - Unimportant1 - Unimportant4 - Important1 - Unimportant1 - Unimportant
        C1P005: Any other Legal and Regulatory BARRIER (if any)
        C1P006: Environmental barriers
        C1P006: Environmental barriers2 - Slightly important3 - Moderately important- Climate Variability: 5 - Topographical Constraints: 4 - Sunlight Availability: 5 - Environmental Regulations: 3 - Zoning Restrictions: 2 - Air and Water Pollution: 2 - Natural Disasters: 1 - Water Scarcity: 1
        C1P007: Technical barriers
        C1P007: Lack of skilled and trained personnel4 - Important4 - Important4 - Important1 - Unimportant5 - Very important3 - Moderately important5 - Very important
        C1P007: Deficient planning3 - Moderately important4 - Important4 - Important2 - Slightly important5 - Very important4 - Important4 - Important
        C1P007: Retrofitting work in dwellings in occupied state4 - Important1 - Unimportant4 - Important2 - Slightly important1 - Unimportant3 - Moderately important5 - Very important
        C1P007: Lack of well-defined process4 - Important4 - Important2 - Slightly important2 - Slightly important4 - Important1 - Unimportant4 - Important
        C1P007: Inaccuracy in energy modelling and simulation4 - Important1 - Unimportant2 - Slightly important2 - Slightly important5 - Very important2 - Slightly important5 - Very important
        C1P007: Lack/cost of computational scalability4 - Important3 - Moderately important3 - Moderately important5 - Very important4 - Important1 - Unimportant4 - Important
        C1P007: Grid congestion, grid instability4 - Important4 - Important5 - Very important5 - Very important5 - Very important2 - Slightly important3 - Moderately important
        C1P007: Negative effects of project intervention on the natural environment3 - Moderately important3 - Moderately important2 - Slightly important5 - Very important1 - Unimportant3 - Moderately important3 - Moderately important
        C1P007: Energy retrofitting work in dense and/or historical urban environment5 - Very important3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant5 - Very important4 - Important
        C1P007: Difficult definition of system boundaries3 - Moderately important3 - Moderately important1 - Unimportant2 - Slightly important1 - Unimportant4 - Important4 - Important
        C1P007: Any other Thecnical BARRIER3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P007: Any other Thecnical BARRIER (if any)
        C1P008: Social and Cultural barriers
        C1P008: Inertia4 - Important3 - Moderately important2 - Slightly important2 - Slightly important4 - Important3 - Moderately important5 - Very important
        C1P008: Lack of values and interest in energy optimization measurements5 - Very important3 - Moderately important5 - Very important2 - Slightly important5 - Very important2 - Slightly important4 - Important
        C1P008: Low acceptance of new projects and technologies5 - Very important4 - Important5 - Very important2 - Slightly important5 - Very important2 - Slightly important5 - Very important
        C1P008: Difficulty of finding and engaging relevant actors5 - Very important3 - Moderately important4 - Important3 - Moderately important5 - Very important4 - Important4 - Important
        C1P008: Lack of trust beyond social network4 - Important3 - Moderately important5 - Very important4 - Important3 - Moderately important4 - Important5 - Very important
        C1P008: Rebound effect4 - Important3 - Moderately important4 - Important2 - Slightly important4 - Important2 - Slightly important5 - Very important
        C1P008: Hostile or passive attitude towards environmentalism5 - Very important3 - Moderately important3 - Moderately important5 - Very important5 - Very important3 - Moderately important3 - Moderately important
        C1P008: Exclusion of socially disadvantaged groups2 - Slightly important3 - Moderately important3 - Moderately important2 - Slightly important1 - Unimportant3 - Moderately important3 - Moderately important
        C1P008: Non-energy issues are more important and urgent for actors3 - Moderately important3 - Moderately important3 - Moderately important3 - Moderately important1 - Unimportant3 - Moderately important4 - Important
        C1P008: Hostile or passive attitude towards energy collaboration3 - Moderately important3 - Moderately important5 - Very important1 - Unimportant3 - Moderately important3 - Moderately important
        C1P008: Any other Social BARRIER3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P008: Any other Social BARRIER (if any)
        C1P009: Information and Awareness barriers
        C1P009: Insufficient information on the part of potential users and consumers3 - Moderately important3 - Moderately important2 - Slightly important1 - Unimportant3 - Moderately important3 - Moderately important
        C1P009: Perception of interventions as complicated and expensive, with negative socio-economic or environmental impacts3 - Moderately important3 - Moderately important5 - Very important5 - Very important4 - Important4 - Important
        C1P009: Lack of awareness among authorities3 - Moderately important5 - Very important4 - Important2 - Slightly important3 - Moderately important4 - Important
        C1P009: Information asymmetry causing power asymmetry of established actors3 - Moderately important5 - Very important2 - Slightly important1 - Unimportant4 - Important4 - Important
        C1P009: High costs of design, material, construction, and installation3 - Moderately important5 - Very important4 - Important5 - Very important4 - Important5 - Very important
        C1P009: Any other Information and Awareness BARRIER3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P009: Any other Information and Awareness BARRIER (if any)
        C1P010: Financial barriers
        C1P010: Hidden costs4 - Important5 - Very important2 - Slightly important5 - Very important3 - Moderately important4 - Important
        C1P010: Insufficient external financial support and funding for project activities3 - Moderately important5 - Very important5 - Very important5 - Very important3 - Moderately important3 - Moderately important
        C1P010: Economic crisis3 - Moderately important5 - Very important3 - Moderately important4 - Important4 - Important5 - Very important
        C1P010: Risk and uncertainty3 - Moderately important5 - Very important2 - Slightly important5 - Very important3 - Moderately important4 - Important
        C1P010: Lack of consolidated and tested business models3 - Moderately important5 - Very important2 - Slightly important5 - Very important4 - Important4 - Important
        C1P010: Limited access to capital and cost disincentives3 - Moderately important5 - Very important5 - Very important4 - Important5 - Very important
        C1P010: Any other Financial BARRIER3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P010: Any other Financial BARRIER (if any)
        C1P011: Market barriers
        C1P011: Split incentives3 - Moderately important4 - Important5 - Very important4 - Important4 - Important5 - Very important
        C1P011: Energy price distortion5 - Very important4 - Important5 - Very important5 - Very important4 - Important5 - Very important
        C1P011: Energy market concentration, gatekeeper actors (DSOs)5 - Very important3 - Moderately important2 - Slightly important5 - Very important2 - Slightly important3 - Moderately important
        C1P011: Any other Market BARRIER3 - Moderately important1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant1 - Unimportant
        C1P011: Any other Market BARRIER (if any)
        C1P012: Stakeholders involved
        C1P012: Government/Public Authorities
        • Planning/leading
        • Monitoring/operation/management
        • Planning/leading,
        • Design/demand aggregation,
        • Construction/implementation,
        • Monitoring/operation/management
        C1P012: Research & Innovation
        • Planning/leading,
        • Design/demand aggregation,
        • Construction/implementation,
        • Monitoring/operation/management
        • Planning/leading
        • Design/demand aggregation
        • Design/demand aggregation
        C1P012: Financial/Funding
        • Planning/leading,
        • Design/demand aggregation,
        • Monitoring/operation/management
        • None
        • None
        • Planning/leading
        C1P012: Analyst, ICT and Big Data
        • Planning/leading,
        • Monitoring/operation/management
        • None
        • Monitoring/operation/management
        • Planning/leading
        C1P012: Business process management
        • Monitoring/operation/management
        • None
        • Construction/implementation,
        • Monitoring/operation/management
        • Planning/leading
        C1P012: Urban Services providers
        • Planning/leading,
        • Monitoring/operation/management
        • None
        • Planning/leading
        • Planning/leading
        C1P012: Real Estate developers
        • Construction/implementation
        • Design/demand aggregation
        • None
        • Planning/leading
        C1P012: Design/Construction companies
        • Construction/implementation
        • None
        • Construction/implementation
        • Planning/leading
        C1P012: End‐users/Occupants/Energy Citizens
        • Design/demand aggregation
        • Monitoring/operation/management
        • Monitoring/operation/management
        • Monitoring/operation/management
        C1P012: Social/Civil Society/NGOs
        • Design/demand aggregation
        • Monitoring/operation/management
        • None
        • Construction/implementation
        C1P012: Industry/SME/eCommerce
        • Construction/implementation
        • None
        • Construction/implementation,
        • Monitoring/operation/management
        • Design/demand aggregation
        C1P012: Other
        C1P012: Other (if any)
        Summary

        Authors (framework concept)

        Beril Alpagut (Demir Energy); Giulia Turci (University of Bologna); Michal Kuzmic (Czech Technical University in Prague); Paolo Civiero (Università Roma Tre); Serena Pagliulia (University of Bologna); Oscar Seco (CIEMAT); Silvia Soutullo (CIEMAT); Daniele Vettorato (EURAC Research, IEA Annex 83); Bailador Ferreras M. Almudena (CIEMAT); Vicky Albert-Seifried (FHG ISE)

        Contributors (to the content)

        Laura Aelenei (LNEG), Nienke Maas (TNO), Savis Gohari (OsloMet), Andras Reith (ABUD), Ghazal Etminan (AIT), Maria-Beatrice Andreucci (Universita Sapienza), Francesco Reda (VTT, IEA Annex 83), Mari Hukkalainen (VTT), Judith-Borsboom (Locality), Gilda Massa (ENEA), Jelena Ziemele (University of Latvia), Nikola Pokorny (CVUT), Sergio Diaz de Garayo Balsategui (CENER, IEA Annex 83), Matthias Haaze (ZHAW, IEA Annex 83), Christoph Gollner (FFG, JPI UE), Silvia Bossi (ENEA, JPI UE), Christian Winzer (Zurich University of Applied Science), George Martinopoulos (Centre for Research and Technology Hellas), Maria Nuria Sánchez (CIEMAT), Angelina Tomova (Energy Agency of Plovdiv)

        Implemented by

        Boutik.pt: Filipe Martins, Jamal Khan
        Marek Suchánek (Czech Technical University in Prague)