IEA Tasks & Annexe
There are 13 results.
IEA IETS Task 18: Digitalization, Artificial Intelligence and Related Technologies for Energy Efficiency and GHG Emissions Reduction in Industry (Working period 2023 - 2024)
The work in Task 18 enables the exchange of experience and knowledge between industry and research institutions from different countries. Through this cooperation best practices are identified and disseminated to promote the implementation of energy-efficient technologies in industry. In the medium and long-term, this contributes to reduce energy consumption and greenhouse gas emissions of industry.
IEA IETS Task 15: Industrial Excess Heat Recovery (Phase 4)
Excess heat recovery plays a crucial role in reducing emissions in industry. Through strategic planning and efficient process integration, companies can improve their energy efficiency and significantly reduce their carbon footprint. Task XV facilitates the international exchange of experience and knowledge between different companies. This identifies best practices to promote the implementation of energy-efficient technologies in industry.
IEA IETS Task 17: Membrane processes in biorefineries (Working period 2023 - 2025)
Biorefineries are essential for the transition from petroleum- to a biobased industry. The use of biomass as raw material for recyclable materials, chemicals and energy sources is essential and requires efficient and sustainable production processes. This project aims to strengthen national and international know-how transfer between research and development for membrane-based processes in biorefineries. The focus is on application, improvement and innovation in all aspects of membrane distillation.
IEA IETS Task 11: Industrial Biorefineries (Working period 2022-2024)
Biorefineries producing a portfolio of biobased products or bioenergy are the backbone of the growing bioeconomy. IEA IETS Task 11 aims to minimize greenhouse gas emissions to net zero along different biorefinery pathways. Tools and methodologies for increasing energy efficiency and the use of renewable energies are to be summarized and disseminated to relevant target groups.
IEA IETS Task 21 Decarbonizing industrial systems in a circular economy framework
Energy and CO2 savings through circular economy, especially directly through carbon circularity (CCU), and resource and energy efficiency through industrial symbiosis are two key approaches to decarbonizing industry.
IEA IETS Annex 11: Industrial Biorefineries (Working period 2020-2022)
With the increasing market share of bio-based products, the concepts of circular economy are highly relevant for the industry. In this context, biorefineries have established themselves as an explicitly integrative, multi-functional overall concept and essential hub in the use of biomass as a raw material source for the sustainable production of various (intermediate) products (chemicals, valuable materials, energy carriers).
IEA IETS Annex 18: Digitalization, artificial intelligence and related technologies for energy efficiency and reduction of GHG emissions in industry (Working period 2020 - 2023)
The work in Task 18 enables the exchange of experience and knowledge between industry and research institutions from different countries. Through this cooperation best practices are identified and disseminated to promote the implementation of energy-efficient technologies in industry. In the medium and long-term, this contributes to reduce energy consumption and greenhouse gas emissions of industry.
IEA IETS Annex 17: Membrane processes in biorefineries (Working period 2020 - 2022)
The aim of IEA IETS Task 17 was to network and strengthen the Austrian membrane and biorefinery research landscape and to promote international exchange on energy- and cost-efficient separation technologies such as membrane distillation (MD), forward osmosis (FO), pervaporation (PV) and liquid membrane permeation (FMP) for the optimised use of lignocellulosic material in biorefineries. A guideline for the integration of emerging membrane processes was created for this purpose.
IEA IETS Annex 15: Industrial Excess Heat Recover (Phase 3)
Within the framework of the IEA IETS Annex 15 (Phase 3), potentials for the use of waste heat as well as technologies for its integration are collected, bundled and processed through contributions from national research activities. The contributions of the Austrian consortium included technology development and integration concepts of heat pump and energy storage systems, risk analysis in the implementation of waste heat projects, and work on operation optimization and design of hybrid energy systems.
IEA-IETS Task 19: Electrification of Industry
The electrification of industry can make a major contribution to CO2 reduction. The aim of the task was a transfer of knowledge between the international and the state levels. Nationally, the aim was to spread and establish the topic of “electrification of industry” through stakeholder involvement. A comparison of electrification based on roadmaps and resources was carried out and, above all, systemic aspects of electrification of industry were analysed.
IEA Industrial Energy-Related Technologies and Systems (IETS TCP)
The Industrial Energy-Related Technology Programme (IETS) focuses on energy use in a broad range of industry sectors. It fosters international co-operation amongst relevant research strands, networking within and across industrial sectors, as well as exchange of information and knowledge between experts from industry, science and politics.
IEA IETS Annex 17: Membrane filtration for energy-efficient separation of lignocellulosic biomass components
The overarching goal of IEA IETS TCP Annex 17 is to strengthen the network of the Austrian membrane and biorefinery landscape.
IEA-IETS Annex 15: Industrial Excess Heat Recover (Phase 2)
In the framework of IEA IETS Annex 15 potentials of excess heat and technologies for their integration were collected from national research projects, bundled and elaborated on. This way, a broad knowledge base was built on experience gained in carrying out surveys for potential use of excess heat. Experiences with questionnaires, process integration tools and extrapolation of data using existing knowledge about the respective energy systems were exchanged. A process database with detailed process information could also be established, which can be used for further research activities. Also, in the area of policy instruments, recommendations for future measures to increase the use of surplus heat were derived on the basis of national contributions.