IEA Tasks & Annexe
There are 125 results.
IEA Bioenergy Task 32: Biomass Combustion (Working Period 2022 - 2024)
Biomass combustion is an important technology for providing renewable energy worldwide. Almost half of the EU's energy consumption is used for heat, which, among other technologies, can be provided by biomass combustion in a climate-friendly manner. It is therefore a key technology for achieving national and international climate and energy goals. This project shall ensure the exchange of information on relevant topics in order to support the success of Austrian actors from industry and research.
IEA Bioenergy Task 33: Gasification of Biomass and Waste (Working Period 2022 - 2024)
The aim of Task 33 is to exchange information on the production and utilization of renewable gas from biomass and waste for the production of power, heat, biofuels and biochemicals. Especially the information exchange about R&D programs, implementation and possible markets is taken into account, to remove technical and non-technical barriers.
IEA Bioenergy Task 37: Energy from Biogas (Working Period 2022 - 2024)
Biogas technology is now widespread in many of the Task's participating countries. In addition to general knowledge sharing and highlighting best practice examples, the focus of the work in this triennium lies on the role of biogas in decarbonising industry and agriculture, biogas in the energy system and process optimisation in the area of emissions and process stability.
IEA Bioenergy Task 44: Flexible Bioenergy and System Integration (Working Period 2022 - 2024)
IEA Bioenergy Task 44 contributes to the development and analysis of bioenergy solutions that can provide flexible resources for a low carbon energy system. The objective is to improve the understanding on the types, quality and status of flexible bioenergy, and identification of barriers and future development needs in the context of the entire energy system (power, heat and transport).
IEA AFC Annex 34: Fuel Cells for Transportation (Working period 2022 - 2025)
The vision of the Technology Collaboration Programme on Advanced Fuel Cells (AFC TCP) is to make a significant contribution to addressing the opportunities and barriers to the commercialisation of fuel cells by promoting the development of fuel cell technologies and their applications at the international level. In detail, Annex 34 deals with the advantages and disadvantages of fuel cells, the further development of storage media, the recording of cost reduction potentials and the results analysis of pilot projects for mobile applications.
IEA HEV Task 46: LCA of Electric Trucks, Buses, Two-Wheelers and other Vehicles (Working period 2022 - 2025)
The objective of this R&D service is the participation in Task 46 of the IEA Hybrid and Electric Vehicle (HEV) TCP with the work on the internationally agreed topics and the managing of the task as Operating Agent. Beside the Life Cycle Assessment (LCA) studies of typical examples also methods for the assessment of climate neutrality and circularity are developed. This is done in dedicated expert workshops.
IEA Wind Task 52: Large-Scale Deployment of Wind Lidar (Working period 2022 - 2026)
Task 52 works towards the widespread adoption of wind LiDAR-systems and provides a strong opportunity to generate and spread knowledge and experience through global networking. Energiewerkstatt contributes to Task 52 with a comparative study of data availability of different LiDAR measurement principles under Alpine conditions and will take an organisational role in the creation of guidelines for the use of ground-based LiDAR in wind energy applications.
IEA Wind Task 54: Wind Energy in Cold Climates (Working period 2022 - 2024)
In order to achieve the development targets for renewable energies, generation plants will increasingly have to be installed at locations with more demanding technical and environmental conditions in the future. For wind energy, this means planning and operating turbines under icing conditions in many countries. The task investigates and evaluates technological solutions in this environment and publishes procedural recommendations in the form of technical reports and guidelines.
IEA SHC Task 68: Efficient Solar District Heating Systems (Working period 2022 - 2024)
Regarding the use of CO2-free technologies for local/district heating systems, solar technologies in particular offer an efficient option. In this task, the opportunities and challenges are investigated in order to efficiently provide the required temperatures necessary for local/district heating networks through solar technologies, to promote digitalisation, to identify new business models and measures for cost reduction, and to spread the knowledge about the potential of solar district heating systems.
IEA DHC Annex XIII Project 02: MEMPHIS 2.0 - Advanced algorithm for spatial identification, evaluation of temporal availability and economic assessment of waste heat sources and their local representation
The identification and integration of waste heat sources is a key measure towards the decarbonisation district heating networks (DHN). Aim of MEMPHIS 2 is to develop an improved algorithm for identification of different current and future waste heat sources; including time relations of the heat emitted and techno-economic details as well as the further development of the online waste heat explorer.
IEA DHC Annex XIII Project 07: CASCADE - A comprehensive toolbox for integrating low-temperature sub-networks in existing district heating networks
The majority of urban district heating networks operate at high temperatures, which are a barrier to the efficient integration of heat sources such as solar, geothermal, ambient or low temperature waste heat. CASCADE is investigating the integration of low-temperature networks into the return pipe of existing district heating networks, which will reduce return temperatures and thus improve efficiency and increase its capacity to connect new customers.
IEA ISGAN Annex 5: Smart Grids International Research Facility Network (SIRFN). (Working period 2021-2022)
The Smart Grids International Research Facility Network (SIRFN) aims at improving the implementation of Smart Grids technologies by collaboration between smart grid testing facilities, test beds, and large-scale demonstrations. In the working period 2021-2022, the focus will be laid on the development of extended interoperability tests for decentralised energy resources and micro grids.
IEA AFC Annex 31: Polymer Electrolyte Fuel Cells (Working period 2020 - 2024)
AFC Annex 31 covers the technological development of the key components of fuel cells, system development, market introduction support through the analysis and development of the political framework conditions and the reduction of market entry barriers.
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-SHC Task 66: SOLAR ENERGY BUILDINGS - Integrated solar energy supply concepts for climate-neutral buildings and communities for the "City of the Future”
The energy supply for climate-neutral buildings is based on holistic system concepts that achieve high renewable fractions by intelligently combining technologies, sector coupling, high grid interaction and flexibilization measures. The Solar Energy Buildings Task supports exactly this development. The objective is to identify relevant stakeholders and their needs, to develop a technology portfolio and optimised integrated energy concepts and to give recommendations to policy makers and energy-related companies.
IEA HPT Annex 58: High-Temperature Heat Pumps
Industrial heat pumps, especially high temperature heat pumps with useful temperatures higher than 100°C, are a central element in the future energy system. In order to increase the application of high temperature heat pumps in industry, this project will provide an overview of the technological possibilities up to the procurement process of high temperature heat pumps. This should increase the understanding of the technology and its potential and reduce existing market barriers.
IEA-SHC Task 65: Solar Cooling for the Sunbelt Regions
Without measures, cooling demand will triple by 2050. The aim of Task 65 is to adapt existing technologies to the boundary conditions of the sunbelt, to find suitable system concepts, to evaluate them and to disseminate the advantages. In addition to system adaptations, the Austrian focus is on life cycle cost-benefit analysis and the further development of existing assessment tools.
IEA EBC Annex 81: Data-Driven Smart Buildings
The latest developments in digitization have the potential to significantly reduce the costs of building operations. The annex is intended to improve access to low-cost, high-quality data from buildings and to support the development of data-driven energy efficiency applications and analyses. This enables the optimization of building controls in real time and offers energy efficiency data and decision support for building managers.
IEA EBC Annex 82: Energy flexible buildings towards resilient low carbon energy systems
The aim of the Annex is to gain knowledge about the energy flexibility services that buildings and clusters of buildings may deliver to different types of energy networks. The project increases the knowledge about the barriers and motivation for the stakeholders. Their constructive involvement is a key for making building energy flexibility a value for the resilience of future energy networks.
IEA-SHC Task 64: Solar Process Heat
The main objective of the task is to identify, verify and promote the role of SHIP (Solar Heat in Industrial Processes) systems as single system and in integrated energy systems. Technical and non-technical barriers will be tackled. The main results of the project are a dimensioning and integration guideline for SHIP and integrated energy systems and a Guideline to Market for SHIP and integrated energy systems.