Demoobject energy-autarkic solarplant

Within the project at hand a production plant with store house and offices will be constructed. It will serve as a reality testing field for long-term measurement of components and systems developed in previous projects. In case of a successful development, it shall serve for the demonstration of innovative energy systems and components for the interested public and for experts.

Titel und Synopse

Energieautarke Solarfabrik - Demoobjekt energieautarke Solarfabrik

Im vorliegenden Projekt soll als Demonstrationsobjekt ein Produktionsbetrieb und ein Warenlager samt Büros errichtet werden, das zugleich als Realitätstest samt Langzeitmessungen dient. Es soll als reales Versuchslabor für Entwicklungen aus Vorprojekten fungieren und bei erfolgreicher Entwicklung der Demonstration innovativer Energiesysteme und Komponenten für Interessierte und das Fachpublikum dienen.


Project description / tasks

Status

ongoing

Summary

Starting point / motivation

Project leader Sun Master aims to build up a demonstration object with numerous developments in terms of innovative and efficient use of energy. They will introduce new standards for buildings by developing systems and components in three sub-projects. Parallelly, those developments will be tested at the demonstration object. Using a simple technical basis a maximum of comfort and an optimum of economic output shall be provided. By simulations it has to be checked, which is an adequate relation between surface and volume of the building. In connection with an optimum of wind stiffness and thermal energy safety strategy it should be possible to build an industrial production plant without any external energy source for the internal heat treatment.

Contents and goals

Prospected goals:

  • New building in passive house standard
  • Optimized climate control for the building with controlled air supply.
  • Energy recovering equipment of removed air
  • Use of fire water for warm water generation.
  • Thermal solar panels as cover for the plant outside.
  • Low temperature systems for an optimum of power output and efficiency.
  • Warmth keeping under the plant by an thermal earth storage system
  • Installation of photovoltaic panels on the front side of the building.
  • Cold air supply by thermal driven climate machines instead of electrical climate control devices.
  • Use of a cooling tank for case of burning plant for cooling the machines with cool water.
  • Use of "night coolness".
  • Activation of walls and building components for climate control reasons.
  • Optimized press-air supply.
  • Efficient light devices
  • Use of rain water.

Methods of treatment

The project is separated into three subprojects, which have the contents of three cooperative developments of systems and components with the targeted goals mentioned above.

The development process is based on a partnership of project partners and external know-how sources out of several types of professions. All new products will be tested in a status of a prototype in the real laboratory called 'energy-autarkic solarplant". So, there is also a good chance for optimizing the parts in real conditions while the plant is operating. In the same way the resistance of the systems can be tested for a long time period.

The development of the components is done in a typical and modern way.

Expected results / conclusions

  1. The demonstration object will be built in passive-house standard.
  2. High efficient air supply will be provided; Installation of an innovative fresh air system by using cool night air for climate control. Use of optimized air cooling vans for lower power consumption.
  3. Heat recovery system for the emitted air volume.
  4. Use of internal heat supply at the production line for warm water etc.. All hydraulic cooling systems are linked to a thermal absorption machine for energy recovery and storage.
  5. Installation of a thermal solar panel at the front of the building. By doing this, two functions are covered: first, generation of thermal power and second, building an attractive good looking surface for the building.
  6. Storage of thermal power by the innovative heat earth storage system. If the storage will not work, it will be a break up criterion for the whole project.
  7. Installation of a photovoltaic panel system for the electric power supply.
  8. High efficient climate machine under the use of a thermal absorption device. For the project there will be a new machine with all necessary parameters developed, which is not available at the moment.
  9. Use of fire water for the cooling of machines. Taking the cooling tank as a puffer system. Development of a control system for the intelligent internal use of thermal energy.
  10. Use of cool air in the night for cooling the plant and bureaus.
  11. Activation of building components with high thermal capacity for controlling the climate in rooms and for the whole plant.
  12. Optimized light sources. There is a focus on efficient light systems and also on the controlling of light supply.
  13. Use of rain water. Big tanks around and under the plant shall store this water sources for the use in production in terms of e.g. cleaning. In this way the company will lower the consumption of clean water for human use and it is also targeted, that water without calcium carbonate will result in a longer lifetimecircle of all systems touched by the water.

Simulation Winter/Summer

Simulation Winter
Simulation Summer

Project partners

Project management

Herbert Gösweiner
SUN MASTER Energiesysteme GmbH

Project or cooperation partner


Contact address

SUN MASTER Energiesysteme GmbH
Herbert Gösweiner
Solarstraße 7, A-4653 Eberstalzell
Tel.: +43 (7241) 28 125
Fax: +43 (7241) 28 125 - 300
E-Mail: info@sun-master.at, office@goesweiner.at
Homepage: www.sun-master.at


FFG ID: 817619

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