The large-scale research project ThermaFLEX has been successfully completed, the publishable final report can be DOWNLOADED<\/a> here.<\/strong><\/p><\/blockquote>\n
Initial situation<\/u><\/p>\n
In 2016, Austria’s space heating demand amounted to approx. 87 TWh\/a (total energy demand: 311 TWh\/a). A quarter of this is provided via grid-connected heat supply through more than 2,000 district heating systems.<\/p>\n
This means that the local and district heating sector already plays a central role in Austria’s energy supply. Around 5,400 kilometers of valuable heating pipe infrastructure have been laid in Austria. They pass sewage treatment plants as well as industrial and commercial operations whose residual and waste heat could be used in many ways, and on their way there are open spaces where solar heating systems and heat storage tanks could be installed. The already installed infrastructure, the existing expansion potential, especially in dense urban areas, the use of new concepts, technologies and renewable energy sources, the use of opportunities for sector coupling and the resulting contributions to the decarbonization of our energy system will make the sector even more important in the future.<\/p>\n
Every fourth house in Austria is already supplied via heating networks – the aim of the ThermaFLEX flagship project is to make them more flexible. Consistently integrating renewable energies and waste heat into the heating networks of the future would not only improve the air in cities, but also avoid a considerable amount of CO2<\/sub> emissions, increase security of supply and protect consumers from rising oil and gas prices in the long term.<\/p>\n
Objective<\/u><\/p>\n
The aim of the project was to develop strategies for making heating networks more flexible and to develop alternative energy sources for the heating networks in order to increase the proportion of renewable heat.<\/p>\n
Approach and methodology<\/u><\/p>\n
In a sustainable and fully decarbonized energy system, for example, large shares of renewable, sometimes volatile energy sources, integrated sector coupling, decentralized energy conversion structures, etc. have led to a significant increase in system complexity. Gleichzeitig mussten aber einerseits die Versorgungs\u00adsicherheit gewahrt bleiben sowie andererseits die Energiekosten f\u00fcr die Endkunden erschwinglich bleiben. This could only be achieved by increasing the flexibility of the overall system, which allows intelligent interaction between technical and non-technical elements.<\/p>\n
District heating systems are ideally suited for measures to increase flexibility in terms of sector coupling, the integration of renewable energy sources, waste heat utilization, the use of heat storage, new operating strategies and user integration. This potential for flexibility can be further increased if holistic approaches are pursued and new scientific methods for simulation and optimization are used in planning, implementation and operation.<\/p>\n
Demonstrators<\/u><\/p>\n
The focus was on exemplary demonstrators in district heating supply areas in small, medium-sized and large cities, all of which were scientifically supported as part of the ThermaFLEX lead project and most of which have also been implemented in practice (further details on the individual demonstrators are available on the linked detail pages).<\/p>\n
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- Eco-energy park\/absorption heat pump – Salzburg<\/a><\/li>\n
- Waste heat recovery from thermal water – Therme Wien<\/a><\/li>\n
- High-temperature heat pump Vienna Spittelau<\/a><\/li>\n
- Heating and cooling with wastewater – Vienna Blumental<\/a><\/li>\n
- Integration of a large-scale solar system – M\u00fcrzzuschlag<\/a><\/li>\n
- Decarbonization of district heating – Leibnitz<\/a><\/li>\n
- Modernization and integration of a heat pump – Saalfelden<\/a><\/li>\n
- Virtual heating plant – Gleisdorf<\/a><\/li>\n<\/ul>\n