Suchergebnisse
ThermEcoFlow: Innovative Technologien & Methoden für Raumluftkomfort und Energieoptimierung in Thermengebäuden
ThermEcoFlow setzt sich zum Ziel den Energieverbrauch von Thermen durch verbesserte Simulationsmodelle und KI-gestützte Regelungen zu optimieren. Durch präzisere Modellierung von Luftströmungen, Feuchtigkeitslasten und Verdunstungen und KI-gestützten Steuerungssystemen soll der Energieverbrauch und die CO2-Emissionen langfristig gesenkt und der Raumkomfort für Besucher:innen verbessert werden.
Twin2Share - Digitale Zwillinge zur energetischen Optimierung in Energiegemeinschaften (EGs)
Digitale Zwillinge zur Unterstützung von Energiegemeinschaften über ihren Lebenszyklus. Im Fokus stehen die Optimierung von Energieeffizienz und Kosten, dynamisches Lastmanagement und die Einbindung von Nutzer:innen, um nachhaltige Energienutzung und die Stabilisierung des Stromnetzes zu fördern.
TOPS – Topologieoptimierte Stahlbetondecken mit digitaler Schalung und Bewehrung
Das Projekt TOPS untersucht materialeffiziente Rippendecken aus Stahlbeton, die durch Topologieoptimierung bis zu 50 % Beton im Vergleich zu herkömmlichen Flachdecken einsparen. Ein „File-to-Factory“-Prozess ermöglicht die automatisierte Schalungs- und Bewehrungsfertigung mit digitalen Technologien. Die Anwendung der Bauweise reduziert CO₂-Emissionen und trägt zur Dekarbonisierung des Bauwesens bei.
SPOT – Smartes Stellplatz-Optimierungstool
SPOT entwickelt ein datengetriebenes Tool zur bedarfsgerechten Optimierung von Stellplätzen in urbanen Räumen, um Flächen effizienter zu nutzen und die Klimaneutralität zu fördern. Das Tool unterstützt Städte bei der Reduktion von Parkplatzflächen und der Schaffung von Grünflächen, indem es evidenzbasierte Stellplatzschlüssel berechnet.
Topview - Methodik zur effizienten Nutzung von Fernerkundungsdaten für Klimawandelanpassung und Energieraumplanung
Entwicklung integrierter Ansätze zur nachhaltigen Energie- und Wärmeplanung in urbanen Räumen durch Nutzung von Fernerkundungsdaten und geoinformationsgestützten Technologien zur Entscheidungsfindung bei Planung von Energieinfrastrukturen und Klimaanpassungsmaßnahmen.
Urban Sky – Satellitengestützte Planungs- und Analyseanwendungen für klimaneutrale und resiliente Städte
Im Projekt wird untersucht, wie Satellitendaten Städte und Gemeinden z.B. in der Stadtentwicklung, Energieraumplanung und Mobilitätswende unterstützen können. Basierend auf Bedarfs- und Potenzialanalysen sowie rechtlichen Rahmenbedingungen werden Servicekonzepte abgeleitet, die bestehende Daten mit Satellitenanwendungen integrieren. Die Ergebnisse werden in einer Studie und Space4Cities-Umsetzungs-Roadmap präsentiert.
BATTMON - Increasing the usable charging capacity, service life and safety of battery storage systems in urban areas
The aim of BATTMON is to develop an improved method of determining the condition of battery storage systems for applications in buildings and neighborhoods. To this end, area-based foil sensors are being developed for the spatially resolved measurement of temperature and pressure. This data will be used to estimate the state of charge and also the state of health more accurately and to detect cell damage at an early stage in order to reduce the risk of fire and explosion.
BIM.sustAIn - Artificial Intelligence to enhance sustainability in BIM projects
The construction sector faces growing challenges in meeting sustainability requirements, particularly during early project phases where key decisions on materials, construction methods, and energy concepts are made. This project aims to leverage AI and BIM to optimize sustainability assessments by providing precise CO₂ balance forecasts and material suggestions. The innovative approach reduces manual effort and supports the implementation of climate-neutral construction, contributing significantly to Austria’s climate goals.
Climbing plant NAVI - Webapplication for the reliable selection of climbing plants
The comprehensive web application "Climbing Plants NAVI" takes important parameters such as the type of greening, weight classes, toxicity, ecological value, the possibility of culinary use, into account and thereby supports the selection of suitable climbing plants for greening projects. The climbing plants NAVI is not only intended for municipal representatives, planners and other professionals, but is also directed at private individuals.
Circular Bio Floor- Floor construction made from biomaterials
In this project biogenic building materials from wood industry waste and geopolymer binders are developed that can be used as tamped fill or 3D-printed dry-screed elements in timber construction. These materials offer functional benefits and an excellent eco-balance, contribute to the conservation of forests and enable the production of separable and reusable floor segment panels using digital manufacturing technologies. That significantly reduces the consumption of primary raw materials.
Autology - the automated ontology generator
Ontologies form the basis for the acquisition, analysis/processing, utilization, documentation, and archiving of building and component data throughout all stages of the lifecycle. Currently, the semantic description and structuring of data can only be achieved with significant manual effort. At this point, the Autology project utilizes Artificial Intelligence. The overarching project objective is the automated extraction and generation of metadata for the creation of ontologies from the building automation system, employing innovative AI-based approaches.
DataScience4SmartQuarters - Energy saving potentials through neighbourhood and community planning – Part 2
DataScience4SmartQuarters develops and researches an innovative method for the fast and efficient evaluation of simulation scenarios (building/energy, mobility) for communities.
sustAIn4Build - AI competence for sustainable building management in climate neutral cities
The objective of the project sustAIn4Build is to increase energy efficiency and sustainability in the building sector by using artificial intelligence (AI). Industry-specific training programs support Austrian companies to develop a workflow for integrating AI technologies into their processes, enabling them to develop resource-saving, cost-effective and sustainable solutions. This strengthens their competitiveness and contributes to the achievement of European decarbonisation goals.
TEA-PUMP – Techno-economic Analysis of Thermoelectric Modules for Efficiency and Performance Enhancement in Heat Pumps for Residential Buildings
The TEA-Pump project explores the innovative use of thermoelectric elements (TEM) in compression heat pumps to enhance their efficiency and performance. Through a comprehensive techno-economic analysis, promising heat pump (HP) configurations for use in urban multi-family housing are identified. The project makes a significant contribution to the decarbonization of heating and cooling supply and supports the development of climate-neutral cities through energy-efficient, future-oriented heat pump technologies.
ThermEcoFlow: Innovative technologies and methods for indoor air comfort and energy optimisation in thermal spa buildings
ThermEcoFlow aims to optimize the energy consumption of thermal spas facilities through improved simulation models and AI-supported control systems. By precisely modelling airflow, humidity loads, and evaporation, combined with AI-driven regulation, the project seeks to reduce energy consumption and CO₂ emissions in the long term while enhancing indoor comfort for visitors.
SPOT – Smart Parking Space Optimization Tool
SPOT develops a data-driven tool for demand-oriented optimization of parking spaces in urban areas to use space more efficiently and promote climate neutrality. The tool supports cities in reducing parking areas and creating green spaces by calculating evidence-based parking space ratios.
IMPACT – Hybrid hydraulic and electric charging of stratified compact hot water
The IMPACT project is developing an innovative decentralised hot water storage technology for large-volume urban housing. Thanks to a novel, flat design, the system enables highly efficient utilisation of renewable energy sources such as heat pumps and photovoltaics. The aim is to create a cost-efficient, sustainable solution for decarbonising water heating that is optimised using intelligent energy management and machine learning methods.
KliB40-Climate Compass: Climate-neutral Bregenz 2040, climate compass for the structured participation of stakeholders and the citizens
The "KliB40 Climate Compass" supports Bregenz on its path to climate neutrality by 2040 through transparent development, selection, and monitoring of measures. It facilitates the coordination of climate protection activities and actively involves stakeholders. By evaluating existing software solutions, the project ensures optimal digital support for planning and implementing the city's climate strategy.
Kimoni – Artificial Intelligence for Monitoring the Performance of Green Infrastructure
Kimoni develops an AI-based tool for high-resolution analysis and assessment of Green Infrastructure for climate change adaptation. By combining satellite and geospatial data with machine learning, Kimoni provides a cost-efficient and scalable solution to comply with the EU Taxonomy and optimize climate-friendly investments.
iLESS - Intelligent load profile analysis to maximize self-consumption of solar power
The goal is to reconstruct the individual contributions of various devices from existing load profile curves. This problem is of fundamental importance in the context of maximizing self-consumption of solar power by private households.