There are 418 results.
SaLüH! Renovation of multi-family houses with small apartments, low-cost technical solutions for ventilation, heating and hot water
New innovative concepts for heating and ventilation were investigated. Very compact heat pumps are developed in such a way that it will be possible to integrate these units into the window parapet or into a prefabricated timber façade.
Based on a building typology, strategies for prefabrication for high-quality thermic-energetic renovation of school buildings were developed. New solutions for ventilation systems to achieve good air quality and shading systems were analysed and tested. The "School vent cool" method for renovation of schools has been developed.
In a technical feasibility study and based on a real example, the project analysed innovative plus-energy refurbishment concepts for school buildings. The goal was to develop refurbishment concepts with a high replication potential which combine future-oriented energy concepts with feasible technical and architectural solutions.
SCI_BIM - Scanning and data capturing for Integrated Resources and Energy Assessment using Building Information Modelling
The aim of the project is to increase the resources- and energy efficiency through coupling of various digital technologies and methods for data capturing (geometry and materials composition) and modelling (as-built BIM), as well as through gamification.
Sensible storages, which are currently used in district heating networks for seasonal storage of excess heat (e.g. from solar thermal or industrial waste heat), exhibit high space demand, investment costs and heat losses. Within this project, concepts for using innovative storage technologies, e.g. thermochemical storages (TCS) having high heat densities and enabling pressure- and lossless storage, were developed and analyzed on a technological, economic and ecological basis. Additionally, the regulatory framework has been evaluated.
Refurbishment of single- and two-familiy houses in timber construction in Austria has a large CO2-saving potential. To meet the special requirements for the refurbishment of timber constructions, a concept for the renovation to passive house respectively plus-energy house standard with special focus on ecologic construction materials was developed in this project.
SIMULTAN - Simultaneous planning environment for buildings in resilient, highly energy efficient and resource-efficient districts
This project enabled the opportunity for an essential energy efficiency increase within overlapping buildings, to achieve the objective of resilient cities and districts with respect to a high quality of life, resource sustainability and energy efficiency. The goal was a workable tool based on a multidisciplinary planning approach, to support the decision finding process in order to design both refurbishment projects and new developments within a highly efficient city.
Possibilities and requirements of transferring the Swiss “2000-Watt Site” certificate to Austria
In a practical way the project showed that with optimised small wind turbines a useful potential of wind power can also be generated at different suitable locations with low wind conditions directly at households and companies.
SmallWindPower@Home - Impact assessment of building-mounted small wind turbines on performance, people, building and environment
Within the project SmallWindPower@Home the impact of complex obstacles on the local flow pattern as well as on the inflow and the performance of different building-mounted small wind turbines (SWT) will be evaluated. Furthermore the effects of these building-mounted SWT on the building, the resident people and the direct environment will be analysed.
The EPBD recast 2010 targeted "nearly zero energy buildings". This low amount of energy is to be covered by energy from renewable energy sources. The project "Smart ABC" analysed a variety of relevant solution sets regarding the building performance and the renewable based energy supply options. Energetic and ecological impacts were analyzed in order to optimize the integration of renewable energy technologies in building standards and to find answers how to depict a building cluster regarding standards and tools.
A specially developed simulation model is employed to ascertain the energetic potential of adaptive façade systems. The dynamic behavior of the physical properties of the adaptive façade system reacts to both internal and external changing conditions. The goal was the development of an adaptive façade, which helps provide maximum comfort for the building occupants with minimum energy consumption.
Smart Pölten 2.0 Holistic view on a Vertical Farm in preparation for a demonstration project for the city of St. Pölten
The city of St. Pölten forsees great potential in Vertical Farming with regard to the objectives related to the concept of the Smart City program - linking local food production, quality of life by reducing resource consumption. This has to be evaluated by combining Vertical Farms with existing living buildings. Eco-social and socio-economic considerations play an important role in this process.
The concept of a smart city explicitly refers to a sustainable city development. To apply smart city concepts in practice, it is essential to develop practice- and profit-oriented business models (smart services), which at the same time generate social and ecological benefits. Smart services were developed for the application in three specific city development areas and their practicability was verified in a comprehensive stakeholder process with decision makers.
Smart.Monitor – SMART city indicators and MONITORing for smart city objectives – based on the example of the Smart City Vienna Framework Strategy
Elaborating and preparing the basic information and data required to conceptualize indicators and a monitoring system for the smart city framework strategy. The results shall support the future monitoring of the Smart City Vienna Framework Strategy.
The present study aims to explore the application options for compact units (ventilation devices including micro heat pumps, developed for passive houses) in low energy buildings. Compact ventilation units for heat recovery, heating and domestic hot water shall bear the basic heating load, whereas peak loads shall be covered by newly-developed auxiliary heating equipment combined with intelligent control algorithms. This allows increased energy efficiency as well as cost effectiveness together with higher living quality and lower ecological load.
The emerging development of smart grids provides market opportunities for new ICT-based services ("smart value-added services"). Economic and organizational barriers are foreseeable that could affect the establishment of business models and service providers (data formats, connectivity, controllability, etc.). In order to improve the chances especially for new and local actors, SMARTIES proactively tries to eliminate hindrances of innovation.
This project aims for feasible low-cost solutions, which allow residents of multi-party houses, with special focus on social housing to profit and participate in the energy transition process and associated trends (e.g. community generation units, exploitation of flexibility). The results of the project are low-cost concepts and business models of community generation units and utilization concepts, tested for their feasibility in a social housing complex. These concepts are based on special requirements of different lifestyles in low-income households and take the framework of social housing such as tenant fluctuation into account.
The main goal was to establish a long-term cooperation for "Solar Cooling" between the Austria Solar Innovation Center (ASiC) and the Center for Sustainable Energy Systems (CSES) at the renowned Australian National University (ANU) in Canberra. Combining the competences of both institutes immediately offers the chance to boost the penetration of the European and the Australian market with this new technology for cooling in sustainable buildings.
In this project the application of a solid oxide fuel cell (SOFC) for energy supply (heat and power) of urban areas will be investigated. Due to the high temperature level of the produced heat it would be possible to use this heat for the energy supply of different heat and power consumers (residential buildings, industrial plants, etc.). One aim is to provide the SOFC-heat at several temperature levels in order to establish the advantages of the fuel cell. On the one hand the legal and market-based conditions will be evaluated, on the other hand the technological feasibility will be scoured by the use of CFD-simulation of the heat production.