Projects within the framework of open4innovation
There are 1230 results.
IEA SHC Task 53: New Generation Solar Cooling & Heating Systems
Within the framework of the IEA SHC Task 53 'New Generation (NG) Solar Cooling & Heating Systems', solar-electric and solar-thermal air-conditioning systems were investigated. The main objective was the development and documentation of reliable and economical NG system solutions. A comprehensive comparison of different NG systems as well as the elaboration of support measures for the market launch are core results of the international cooperation.
IEA SHC Task 54: Price reduction
IEA SHC Task 54 was an interdisciplinary, collaborative project with the main focus on significant price reductions of solar thermal systems. Measures to achieve a reduction of the customer price up to 40% included simplified system designs, standardized components and cost-efficient materials and production and installation processes.
IEA SHC Task 55: Integrating Large SHC Systems into DHC Networks
Despite the large potential for integrating large solar thermal plants into district heating and cooling networks, the share of solar heat worldwide is below 1%. The aim of this project was to analyse the technical, economic, and regulatory barriers that hinder a faster market development of such systems, and to propose solutions to support the growing heat market. The results (roadmaps, data, information) are available in the form of fact sheets.
IEA SHC Task 56: Building Integrated Solar Envelope Systems for HVAC and Lighting
IEA SHC Task 56 focused on the critical analysis, simulation, laboratory testing and onsite monitoring of envelope systems entailing elements that use and/or control incident solar energy. The central task was the integration of HVAC and lighting systems into a building’s Solar Envelope solution through a systemic approach.
IEA SHC Task 58/ECES Annex 33: Material and Component Development for Thermal Energy Storage
This Task/Annex addresses second generation materials for PCM and TCM energy storage and includes material development, characterization and testing under application conditions. In addition, the focus was on the interaction between material and storage component and on the expected storage performance of innovative materials.
IEA SHC Task 59/EBC Annex 76: Deep Renovation of Historic Buildings - Towards lowest possible energy demand and CO2 emission (nZEB)
The goal of Task 59 was to document international best practice examples (knowledge base), develop a multidisciplinary planning process, and develop holistic retrofit solutions for historic buildings. As a knowledge base, the Historic Building Retrofit Atlas (www.HiBERatlas.com) emerged from the project. In the HiBERatlas more than 55 best practice examples are documented. In addition to the management of Subtask A (Knowledge Base) and Subtask C (Conservation compatible retrofit solutions & strategies), innovative technical and organizational retrofit solutions, which have already been applied in national demonstration projects and tested in practice, have been incorporated and further developed through the Austrian participation.
IEA SHC Task 61/EBC Annex 77: Integrated Solutions for Daylighting and Electric Lighting
Lighting accounts for around 15% of global electricity consumption - intelligent coordination of daylighting and electric lighting solutions together with integral lighting controls enable significant energy savings. At the same time, the solutions must be optimally planned in a user-centered approach based on the visual and non-visual effects of light. The task analysed user requirements as well as existing technologies and design methods and documented exemplary implementations in case studies.
IEA SHC Task 62: Solar Energy in Industrial Water and Wastewater Management
The main objective of IEA SHC Task 62 was to increase the use of solar thermal energy in industry, to develop new collector technologies and to open up industrial and municipal water treatment as a new area of application with high market potential for solar thermal energy. The focus was on thermal separation technologies as well as technologies for solar water decontamination and disinfection. By combining the technologies with solar collectors, an innovative and economically attractive overall solution should be created for integration into industry.
IEA TCP AFC Annex 33: Fuel Cells for Stationary Applications (Working period 2022 - 2024)
The development of the energy system is characterized in particular by increasing decentralized power generation from renewable energy sources. Hydrogen is a key energy source for the decarbonization of buildings, mobility and industry. In 2022, Austria took on a sub-task in the IEA AFC TCP, which is investigating the use of stationary fuel cells in climate-neutral neighbourhoods. The project analyses its success factors and limitations and tests modelling tools.
IEA TCP Fluidized Bed Conversion (FBC). Working period 2013-2016
The Technology Collaboration Programme includes the collaboration, the exchange of relevant information and networking in the area of fluidized bed conversion of fuels applied for clean energy production.
IEA UsersTCP Empowering all: Gender in policy and implementation for achieving transitions to sustainable energy (Working period 2022-2024)
Previous work in the Task suggests that countries with higher income levels pay little attention to inclusive energy (-technology) use and its implications. Therefore, this project focused on obtaining more data on the gender aspects of energy users through a survey, developing guidelines on inclusive technology development, and communicating the overall research results with interested stakeholders.
IEA UsersTCP: Social License to Automate (working period 2019-2021)
Automation applications for load shifting, also in the homes of end customers, will play an important role in the current transformation process of the energy system. The project “Social License to Automate” examined the question, which aspects are important for the success of these innovations and technologies, and under which circumstances end users are prepared to accept or reject energy-related automation processes.
IEA UsersTCP: “Empowering all” Gender in policy and implementation for achieving transitions to sustainable energy (Working period 2020-2022)
The Annex supports the design of a more efficient and inclusive energy system by integrating gender perspectives. Based on case studies and best practice examples, country-specific recommendations for inclusive energy policies are being elaborated.
IEA Wind Task 19: Wind Energy in Cold Climates (working period 2013 - 2015)
The international experts elaborated two guidelines on the current state of wind energy utilization under icing conditions: the "State of the Art Report" and the "Recommended Practices Report". On a national level, Energiewerkstatt compiled a comparative report on international approval procedures with the assessment of icefall risk, a report regarding operational experience with a stand-alone power supply unit as well as a report on the evaluation of different ice detection systems.
IEA Wind Task 19: Wind Energy in Cold Climates (working period 2016 - 2018)
IEA Wind Task 19 deals with the challenges of the utilisation of wind energy in Cold Climates (i.e. under icing-conditions) and offers through global networking and mutual exchange of experience, the possibility of collecting and generating additional know-how. Aim of the subtask was to share experiences with international partners and standardising of icefall risk assessments. In addition, an evaluation report on the functionality of the new Vestas rotor blade heating system was published.
IEA Wind Task 19: Wind Energy in Cold Climates (working period 2019 - 2021)
The project deals with the challenges of wind power utilisation in icing conditions and provides a strong opportunity to generate new knowledge by global networking. Energiewerkstatt leads a subtask in the field of icefall risk and works on deriving rules of thumb for the risk assessment of the ice throw risk of turbines in operation during icing conditions.
IEA Wind Task 27: Small Wind Turbines in High Turbulence Sites
To ensure safety, reliability and productivity of small wind turbines (SWT) the experts of IEA Wind Task 27 developed a standard consumer label for small wind turbines. Since 2013 Task 27 is focussing on small wind turbines in high turbulence sites. By actively participating in the IEA Implementing Agreement Wind Energy Task 27, Austria’s stakeholders will become participants in the global small wind network. The establishment of a national working group as well as the organisation of an annual small wind conference in Austria will foster a durable collaboration and provide new impetus to the Austrian Small Wind Community.
IEA Wind Task 27: Small Wind Turbines in High Turbulence Sites (working period 2016 - 2018)
Since 2013 Task 27 is focussing on small wind turbines (SWT) in high turbulence sites. By actively participating in the IEA Implementing Agreement Wind Energy Task 27, Austria’s stakeholders will become participants in the global small wind network. The establishment of a national working group as well as the organisation of an annual small wind conference in Austria will foster a durable collaboration and provide new impetus to the Austrian Small Wind Community.
IEA Wind Task 27: Small Wind Turbines in High Turbulence Sites (working period 2018 - 2019)
By participating in the IEA Wind Task 27, a number of goals could be achieved, including the development of a site assessment scheme for wind turbines in areas with high turbulence intensities, the further development of the IEC 61400 standard, the participation in the “Compendium of IEA Wind TCP Task 27 case studies “And the update of the “Small Wind Power Report 2018” as well as activities such as holding the event “Small Wind Power Conference” in Austria.
IEA Wind Task 32: Wind LiDAR Systems für Wind Energy Deployment (Working period 2019-2021)
IEA Wind Task 32 (since 2022: Task 52) deals with the challenges of using Wind-LiDAR-Systems and provides a strong opportunity to generate new knowledge by global networking. Energiewerkstatt elaborated in this phase of Task 32 an analysis regarding data availabilities of LiDAR measurement campaigns at different sites in Austria and resumed an organisational role regarding the assessment of uncertainties of LiDAR measurements in complex terrain.