Güvenli, Temiz ve Verimli Enerji...uzmanlık sağlayacak bir platformun yaratılması...
Transcript of Güvenli, Temiz ve Verimli Enerji...uzmanlık sağlayacak bir platformun yaratılması...
Ufuk2020 Programı Green Deal (Yeşil Mutabakat) Çağrısı
Güvenli, Temiz ve Verimli Enerji
Çağrı YILDIRIM
Ufuk2020 Enerji Alanı Ulusal İrtibat Noktası
14/07/2020
Area 1: Increasing Climate Ambition: Cross sectoral challenges
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Towards Climate-Neutral and Socially Innovative Cities
Şehirlerin «İklim Aksiyon Planları» ve «Sosyal İnovasyon Aksiyon Planları» geliştirmeleri ve uygulamalarına yönelik teknik, idari, finansal ve sosya ekonomik uzmanlık sağlayacak bir platformun yaratılması hedeflenmektedir
Ortaklık yapısında:
• Araştırma kuruluşları
• Akademi
• Sosyal girişimciler
• Finansçılar
48-60 Ay
Activity 4: Bütçenin %60
20 -30 Büyük Uygulama Sahaları
• Yatırımcılar• Hayırseverler• NGOs• Ulusal ve yerel
yönetimler• Vatandaşlar
Towards Climate-Neutral and Socially Innovative Cities
Develop: science-based indicators for assessing cities’ climate neutral action plans
(emissions reduction); innovative urban greening assessment methodologies for
planning & monitoring emissions reduction; inter-operable and comparable cities
evidence repositories
Identifying regulatory, institutional, governance, financing, public acceptance, and other barriers preventing progress towards climate neutrality
Sharing of experience and good practices between cities
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Activity 1: Climate action plans and Green Deal innovation
Activity 2 : Investment project preparation and finance
Identify strategies and financing solutions for cities to reach climate neutrality
Build on existing practices developed by global, European and national initiatives and programmes
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Towards Climate-Neutral and Socially Innovative Cities
Activity 2: Investment project preparation and finance:
Support cities and local communities in testing
solutions
Combine existing results of European R&I with
social innovation
Citizens engagement activities
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Towards Climate-Neutral and Socially Innovative Cities
Activity 3: Social innovation and citizens’ engagement
Open call(s): to support large scale pilots for the deployment in leadcities
Replicability via at least 2 follower cities (smaller than 50 000inhabitants)
20 to 30 large scale pilots
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Activity 4: Research and Innovation for climate-neutral transformation of cities
Towards Climate-Neutral and Socially Innovative Cities
Expected Impacts
Establish a European level structure offering support to and promotion ofsystemic transformation of cities towards climate neutrality
Empower cities and local communities through social innovation
Put in place measures allowing climate neutrality by 2030 for the participatingleading cities and districts;
Put in place measures towards climate neutrality by 2030 in European cities that will demonstrate visible substantial reduction of greenhouse gas emissions and air pollution
Improved share of sustainable and active transport modes
Area 2: Clean, affordable and secure energy
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Demonstration of innovative critical technologies to enable future large-scale deployment of offshore renewable
energy technologies
Yenilikçi çözümlerin geliştirilerek;
-Açık deniz yenilenebilir enerji teknolojilerinin enerji sistem entegrasyonunun sağlanması
- Fosil tabanlı enerji üretimine bağımlılığın azaltılması
Rüzgar Güneş Dalga Enerjisi Gelgit Enerjisi (tidal)
Teknolojiler TRL 7 Seviyesine getirilmesi beklenmektedir
Enerji Sistemlerinin Entegrasyonu
Demonstration of innovative critical technologies to enable future large-scale deployment
of offshore renewable energy technologies
• Offshore renewable energy power generating systems: innovative large scale integrated systems,
floaters and substructures, mooring and anchoring systems
• Grid infrastructure: innovative Direct Current (DC), AC/DC hybrid technologies and systems as a
supporting step towards large offshore HVDC grids (e.g.multi-vendor Multi-Terminal HVDC (MT
HVDC) systems, grid forming converter, HVDC diode rectifiers, Modula Multilevel Converters
(MMC), DC Circuit Breaker (DCCB); DC/DC converter and DC/power hub) and their control and
management system; for floating renewable energy technologies: innovative dynamic inter-
device/inter-array cables and connections to converter stations at sea or offshore hubs.
• Power to X/storage systems: innovative offshore storage and/or power to X systems to maximise
the use of offshore resources and increase the system resilience
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Demonstration of innovative critical technologies to enable future large-scale
deployment of offshore renewable energy technologies
• Industrial design and manufacturing processes, circularity, scalability, installation methods,
transport, operation &maintenance, supply chains and the related digital infrastructures.
• Regulatory, market and financial challenges
• Marine spatial planning issues as well as currently known barriers such as costs, public
acceptance and vulnerability to changing climate conditions in offshore areas, and considering
needs, values and expectations of society through close and continuous discussion with
stakeholders
• Projects are requested to demonstrate the technologies at sea while respecting existing
environmental regulatory framework
• Present an environmental monitoring plan to be implemented during the demonsration activities
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Go/No Go Moment
Expected Impacts:
The project should clearly demonstrate all potential impacts on the future roll-out of large-scale deployment of offshore renewable energy,
The project should demonstrate how it contributes to the SustainableDevelopment Goals of the United Nations (SDG 7 & SDG 9).
Increasing incentives for investment and economies of scale in offshore bringingdown costs and create new business models and services.
The project should demonstrate how it contributes to the different EU policies like the SET-plan, the European Green Deal, Clean Planet for All and the New Circular Economy Strategy
New Circular Economy Strategy
Area 2: Clean, affordable and secure energy
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Develop and demonstrate a 100 MW electrolyser upscaling the link between renewables and commercial/industrial
applications
100 MW’lık elektrolizör uygulaması
State of the Art: Daha büyük modüllerin geliştirilmesi
Geliştirilen modüllerin 100 MW’lık elektrolizör sistemine entegrasyonu
Yakıt Pilleri ve Hidrojen Ortak Girişimi (FCH JU)• Demo4Grid (4 MW)• Driving CleanEnergy Forward (20 MW)
Develop and demonstrate a 100 MW electrolyser
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Main Activity
• Development, installation and
operation of a 100 MW
electrolyser
• Demonstrate the increased
usage and economic impact
of RES mix
• Operation of an electrolyser
system in real life conditions
industrial or port environment
Other Activities
• Demonstration of the future
economic viability
• Reduced footpringt / address
potential health and safety
• Evaluation of the environmental
performance of system
• Evaluation of ecological and
societal benefits
• Combination with other EU or national financing instruments
• Financing plan
Knowledge Sharing Activity:
• 3 Workshops / 2 of them in
Europe
• Contribute to addressing
common challenges,
information and dissemination
with other relevant projects
funded by EC
Technological impacts
• Establish a European industry capable of developing novel hundreds of MW electrolysers using a European value chain,
• Reduce the plant’s footprint by 30% thanks to the larger modules
Operational and environmental impacts
• Demonstrating feasible operation of 100 MW-scale electrolysis and the use of the produced hydrogen
• Assessment of feasibility to connect the electrolyser to a production site of renewable sources of energy such as offshore/onshore wind, or solar plants
Cost competitiveness impacts:
• Demonstrate a compelling economic and environmental case, including boundary conditions, for key applications such as transport, energy storage, raw material (hydrogen and oxygen) or heat and power production
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Expected Impacts
Energy and resource efficient buildings
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Building and renovating in an energy and resource efficient way
Mevcut binaları sıfır emisyon / sıfır kirlilik olarak tasarlanması veya uyarlanması
Pozitif enerji binalara dönüşümün sağlanması
Enerji Verimli Bina Yenileme
Enerji Verimli Bina Tasarımı
HVAC çözümler
En az 2 uygulama sahasının olması (ikametli ve ikametsiz, yeni ve/veya yenilenmiş)
Teknolojiler TRL 7/8 Seviyesine getirilmesi beklenmektedir
Yenilenebilir Enerji Teknolojilerinin Entegrasyonu
Enerji Depolama Sistemleri
Akıllı Bina Hizmetleri Tüketici Farkındalığı Arttırma Faaliyetleri
Building and renovating in an energy and resource efficient way
Energy and resource efficient, seamless industrial
construction/renovation workflows
Recycling/reuse of construction materials or reduction of them
Demonstrating high replicability, reduced maintenance costs and long term performance
Ensuring the fire and seismic safety of the building
Minimizing disruption for building occupants
Delivering post-construction/renovation monitoring of both operational energy
performance
Sustainable and highly energy efficient building designs
Digital and EGNSS based methods of design and constructio, smart
monitoring and tracking of building and renovation process
Innovative and more energy efficient Building Integrated
Photovoltaics (BIPV) converting the building envelope into
electricity producing surfaces
Sustainable, innovative zero-emission and more cost and energy efficienct, RES power generation in the buildings
Power generation systems (BAPV where BIPV is not an option)
HVAC solutions (reversible heat pumps with refrigerants)
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Scalability design of green, positive energy neighbourhoods
Highly energy-efficient building operation and long term performance with the help of digital
technologies
Optimal dynamic matching of on-site renewable energy generation and building consumption;
integrated demand-response
Smart home services, advanced automated controls
Integration between building energy management sysstems/building automotion
control systems, renewable electricity, storage, grid and urban service facilities
Potential for local flexibility to be aggragated and bundled; possibility to trade
Citizen awareness raising activities
Green neighbourhood «libing labs» to facilitate:
Social innovation
Promote education
Training for sustainability
Coordination on standards and
regulatory aspects to ensure operational
efficiency of buildings and HVAC technologies
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Energy storage systems with bidirectional charging functionalities
The validation of the market and consumer uptake potential should be carried out in the forms of living labs
Innovation clusters will be set up
Building and renovating in an energy and resource efficient way
Expected Impacts:
Primary energy savings triggered by the project
Investments in sustainable energy triggered by the project
Reduction of greenhouse gas emissions towards zero (in tCO2-eq/year)
Reduction of air pollutants towards zero (in kg/year) for the total life-cycle compared
Demonstration of high potential for replicability using new or existing innovation clusters incorporating the whole value chain