There are 35 results.
Development of a cost-efficient all-in façade greening system („Greening-Toolkit“) including a maintenance concept, involving all trades and processes, for a broad (facing roads) implementation on facades in the urban built environment, combined with a process innovation for simplification of all necessary coordination processes.
CO-MOD - Increasing comfort and energy efficiency through improved lighting and air quality in schools - implementation through modular EPC-models and ESCO-networks
In general local educational institutions such as schools and kindergardens have a high average demand for improved comfort and energy efficiency improvements. CO-MOD develops a flexible, modular concept (with provider networks, various financing options incl. "Grandmother"-Energy Services, contract modules) that can also respond to the individual circumstances of smaller objects.
CoolAIR - Predictive control of natural nighttime ventilation and daylight-optimized shading for passive building cooling
Natural nighttime ventilation and daylight-optimized shadowing are high potential approaches to efficiently and economical cool buildings. Nevertheless, the full potential cannot be acquired, since, if at all, such behavior is manually initiated by users. Goal of this project is the development of an automated, self-learning system that can assess the full cooling capabilities and establish an alternative to conventional air conditioning systems.
Cooling LEC - Energy-flexible buildings by controlling cooling systems via unidirectional communication in local energy communities
As a result of climate change and the rise in temperature, especially due to the increase in active cooling systems, especially at low-voltage level, new challenges are being posed to the electricity system (in particular to the distribution network). Due to the high electrical input of active cooling units and the high density of plants, which are sometimes operated uncoordinated and at unfavorable times, leads to peak consumption in the system. The project Cooling LEC therefore has as its overall objective the development and demonstration of a central control / intelligence of decentralized active cooling systems by further developing the unidirectional communication of ripple control systems to create energy-flexible buildings in the sense of the new approach of "Local Energy Communities" by creating a "special tariff". Ripple control systems have been established for many decades and are available and proven by all energy suppliers. The upscaling potential is very big.
EDEN - Developement of a structured data and preparation documentation with a minimized error-proneness for energy performance cerificates.
Current energy performance certificates hold major flaws. Therefore, the presented research initiative aimed at the development of a standardized and easy-to-use, generic Input-Data-Documentation, which ensures the quality of energy certificates for all involved stakeholders. During the development, the documentation had been conducted and for a chosen sample of representative buildings, which is expected to demonstrate the high potential of such a development.
Innovative, dynamic control concepts shall be developed which enable (air) heat pumps in combination with PV- or renewable grid electricity to use the building mass of a multi-familiy house as heat storage. User acceptance shall be evaluated and possible business models shall be developed.
The project examines the challenges of urban manufacturing (UM) from the energy perspective and shows opportunities arising from the implementation of UM concepts for the future design of sustainable energy systems for cities.
The integration of heat pumps can increase the cost effectiveness of existing heating networks and counter the high costs for the expansion of power grids at the same time. Aim of the project is to develop innovative business models for small and medium municipal heating networks with focus on synergies between heat and power market. Main focus is a heat pump pooling for several heat grids.
GameOpSys - Gamification for optimizing the energy consumption of buildings and higher-level systems
The central goal is the development of a mobile application that enables the energy optimization and planning of buildings, neighborhoods and higher-level energy systems through the participation of the user and the user as a new source of data and information. The development of the application is strongly transdisciplinary and integrates mathematical methods of simulation and optimization as well as psychological aspects of user behavior in order to develop new business models and open up new markets.
greening UP! Sustainable green maintenance, maintenance, maintenance of vertical greenery including legal aspects
Based on extensive surveys and analyses of existing vertical building greenery in outdoor areas (floor and system-bound façade greening) and vertical interior greenery, the project develops tailor-made green care, maintenance and repair concepts and addresses legal aspects. The "greening UP!" Knowledge pool with concrete recommendations and clearly presented findings as well as the conception of a digital tool for the "First Green Aid" complete the project.
GREENsChOOLENERGY - Development and practical implementation of sustainable solutions for urban hotspots in combination with greening / PV / water
Use of the synergetic effects in the construction of photovoltaic, greening and irrigation systems at the location of HTL1 Klagenfurt Lastenstraße, to optimize the yield of experimental photovoltaic elements and at the same time reduce urban heat islands.
The aim of the project is a functional test to determine whether an up-to-date data set of energy-oriented data can be collected for neighbourhood planning through gamification, cost-efficiently, quickly and reliably. This will be determined using the example of the potential determination of industrial and commercial waste heat sources in Vienna and Graz.
The goal of the INFINITE-project is to lay the foundations for a more wide-spread implementation of urban energy supply systems across buildings, using renewable energy sources produced in local supply units. At the same time the projects supports to reduce the demand for fossil fuels and higher-level energy infrastructure.
Development of transparent, technical and economic models for medium and high volume residential buildings, with special focus on the non-profit sector. Topics such as generation living, teleworking as well as smart homes are developed in an integrated model, for dense structures as well as pavillons and townhouses. All models follow the three pillars of sustainability.
MehrWertStrom 2030 - PV-Community system - Exploring a participatory pilot project with regional added value for structurally weak regions
The "MehrWertStrom 2030" project analysed the legal, technical, organizational and economic feasibility of PV community joint venture facilities on multi-party buildings including the added value for structurally weak regions and developed innovative solutions related to organization, financing and realization.
Based on the results of the national-funded exploratory projects called “Smart Exergy Leoben”, and “Energy Sponge Bruck”, the present implementation project aims at analysing how local, renewable resources support the supply of electric mobility in Leoben in the long term and to integrate it into the municipal distribution grid in a good economic sense.
In the NETSE project the basics for the implementation of energy communities are developed. This includes the relevant technical equipment and interfaces, the development of a platform for the operation of an energy community as well as tools for the optimization of the technical setup and the operation of energy communities.
The project deals with applications optimizing the self-consumption of PV-generated energy within urban quarters by enabling peer-to-peer relations among energy prosumers based on blockchain technology. The aim is to develop and validate these applications in the field being used by consumers.
PV4residents – Innovative Finance Service and Business Model for PV Power Plants of Multiple Dwellings with On-site Use of Electricity
The aim is to develop a business model, which enables a stronger penetration of PV plants on multiple dwellings with self-consumption of produced electricity by the residents. Involvement of the municipality allows to deliver surplus electricity for their needs. Basis of the business model is an analysis of the technical, legal, administrative, user related and economic barriers with participation of stakeholders and to identify best practice solutions.
The core of the project P³Power is the measurement technology NetDetection, which is able to detect the power consumption of a household from any point, e.g. a regular wall socket. Based on this technology a plug&play powerplant, consisting of photovoltaics and battery pack, is realized. The system is able to guarantee 100% self-consumption within flexible aggregates (from single households to whole communes) without any changes of existing infrastructure. The measurement technology will be implemented into digital hardware, evaluated comprehensively in lab and household environment and subsequently new energy service business models are developed.