Search results
There are 252 results.
IEA EBC Annex 89: Ways to Implement Net-zero Whole Life Carbon Buildings
IEA EBC Annex 89 focuses on the pathways and actions needed by various stakeholders and decision-makers to implement whole life cycle based net-zero greenhouse gas (GHG) emissions from buildings in policy and practice. Annex 89 will support key stakeholders and decision-makers in developing and implementing effective Paris-goal compatible schemes and solutions to achieve NetZ-WLC buildings at multiple scales.
IEA EBC Annex 91: Open BIM for Energy Efficient Buildings
Building Information Modeling (BIM) is considered a key technology for optimising the overall energy performance of buildings. The project lays the foundations for OpenBIM tools to include the assessment and optimisation of the energy efficiency of buildings in the future, for Open BIM processes and data models to be increasingly harmonised and standardised, and thus for smaller construction companies to have the opportunity to work on complex BIM projects in the future.
IEA EBC Working Group on Cities and Communities (WGCC)
The WGCC enables information and experience exchange, the identification of bottlenecks that lead to specific research questions and a direct communication with cities on their needs, to enable them to transform their energy systems. The working group is a joint initiative across several TCPs with in-depth participation of technical and non-technical (external) experts.
IEA ES Annex 35: Flexible Sector Coupling through Energy Storage Implementation
The aim of the IEA ES Annex 35 is to investigate and evaluate the potential of different storage technologies and configurations for the application to the sector coupling of electricity, heat and mobility sector and to draft recommendations for politics, research and industry based on the results.
IEA ES Annex 39: Large Thermal Energy Storages for District Heating
Large-scale heat storage systems will play a central role in increasing the necessary flexibility of district heating networks and enable the further expansion of renewable energies. The main objective of the Annex is to determine the aspects that are important in planning, decision-making and implementing large thermal energy storages for integration into district heating systems and for industrial processes, given the boundary conditions for different locations and different system configurations.
IEA ES Annex 49: Low Exergy Systems for High-Performance Buildings and Communities
The objective of Annex 49 is the development of approaches for reducing the exergy demand of buildings, so as to reduce the CO2 emissions of the building stock and support structures for sustainable and reliable energy systems in the building sector. To achieve the objectives of Annex 49, the following activities have been carried out:Application of exergy analysis and providing tools, guidelines, best-practice examples and background information for planners and decision makers in the fields of construction, energy and politics Support of cost-efficient low-energy/exergy measures for renovation and new building taking into account both the residential and the service sector Promotion of exergy-related performance analysis of buildings, particularly from the perspectives of communities / regions
IEA ES Annex 50: Prefab Systems for Low Energy/High Comfort Building Renewal
Development of integrated concepts for multi-storey buildings, which enable renovations of buildings with high energy efficiency at good user acceptance during the realisation phase as well as afterwards (comfort, affordability). Relevant components: integrated solutions of roof and façade with high rate of pre-fabrication, the possibility of integrating the energy façade/roofs and energy distribution and supply.
IEA ES Task 36: Carnot Batteries
Carnot Batteries are an emerging technology for the inexpensive and site-independent storage of electric energy at medium to large scale (> 1.000 MWh). The technology transforms electricity into thermal energy, stores it in inexpensive media such as water or molten salt and transforms the thermal energy back to electricity as required. Carnot Batteries have the potential to solve the global storage problem of renewable electricity in a more economic and ecologic way than conventional batteries.
IEA ES Task 41: Economics of Energy Storage
What is the value of energy storage and how can it be quantified? How can the benefits and value of energy storage be translated into promising business models? The Task will conduct a coordinated methodological assessment of the economic viability of energy storage (electrical, thermal, and chemical) in applications relevant to the energy system. This will be used to derive preferred conditions for energy storage configurations.
IEA ES Task 43: Storage for renewables and flexibility through standardized use of building mass
Thermal building mass activation uses building masses to condition interior spaces, but can also function as energy storage through targeted overheating/undercooling. This storage potential can be used for local and grid-connected renewable thermal and electrical energy (Power2Heat). The project develops new content on the construction, control and business models of such storages and disseminates it as guidelines, data and on the basis of best-practice objects that have been implemented.
IEA ES Task 44: Power-to-Heat and Heat integrated Carnot Batteries for Zero-Carbon (industrial) heat and Power supply
The rise of renewable energy causes fluctuating energy production. The electrification of heat supply further challenges the electricity grid. Coupling electricity and heating with thermal storage helps to strengthen grid resilience and ensures stable energy supply. This project identifies and evaluates heat-integrated Carnot battery concepts to store thermal and electrical energy and supply electricity and thermal energy on demand.
IEA ES Task 45: Accelerating the uptake of Large Thermal Energy Storages
The aim of Task 45 is to accelerate the market launch of large-scale heat storage systems. For this purpose, numerical simulation techniques and material measurement techniques are to be improved and a material database expanded. In addition, a standardized evaluation and communication basis will be developed leading to a method for yield assurance. The methods and findings will be disseminated specifically to municipal utilities, planners and operators of district heating systems as well as decision-makers.
IEA Energy Efficient End-use Equipment (4E)
The activities of IEA 4E TCP are carried out in four platforms and joint ExCo projects. The active Platforms are: Electric Motor Systems (EMSA), Sustainable Lighting and Controls (SSL), Efficient, Demand Flexible Networked Appliances (EDNA) and Power Electronic Conversion Technology (PECTA).
IEA Energy Storage (ES)
The aim of the IEA Energy Storage (ES) Technology Programme is to enable integrated research, development, implementation and integration of energy storage technologies in order to optimise the energy efficiency of all types of energy systems and to promote the use of renewable energy sources instead of fossil fuels.
IEA Energy in Buildings and Communities Programme (EBC TCP)
The Energy in Buildings and Communities Programme by the IEA enables collaborative research and development projects. Thematically, it focuses on integrating energy efficient and sustainable technologies in buildings and communities.
IEA Experts Group "R&D Priority Setting and Evaluation" (EGRD) - Working period 2017 - 2019
The IEA Experts Group (EGRD) was established by the Committee on Energy Research and Technology (CERT). It examines analytical approaches to energy technologies, policies, and research and development and evaluates the benefits of RTI policies. Its results and recommendations feed into IEA analysis, and enable a broad perspective of energy technology issues.
IEA Experts Group "R&D Priority Setting and Evaluation" (EGRD). Working period 2020 - 2022
The IEA Experts Group (EGRD) was established by the Committee on Energy Research and Technology (CERT). It examines analytical approaches to energy technologies, policies, and research and development and evaluates the benefits of RTI policies. Its results and recommendations feed into IEA analysis, and enable a broad perspective of energy technology issues.
IEA FBC Implementing Agreement Fluidized Bed Conversion (working period 2017 - 2020)
The technology 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 FBC Implementing Agreement Fluidized Bed Conversion (working period 2020 - 2023)
The aim of the project is to continue to further develop the internationally very well accepted participation of Austria in the information network of the IEA Fluidized Bed Conversion (FBC) Technology Collaboration Programme (TCP) to optimize fluidized bed conversion of fuels applied to clean energy production (heat and power). All stakeholders will be included on a national as well as on a global level.
IEA FBC Technology Collaboration Programme Fluidized Bed Conversion (Working Period 2024-2026): "IEA Green FBC"
The goal is to further expand and deepen the international cooperation of IEA fluidized bed technology both globally and nationally with regards to green technologies and to continue the successful course towards a most climate-friendly, sustainable and low-pollutant heat and power production using fluidized bed technology. All stakeholders are included and work closely together on a national and global level.