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Lightweight, Energy-Efficient Tooling for the Manufacturing of Rotor Blades

Ziel

This proposal argues that the main objectives of the undertaking, light-weight and energy-efficient tools, can be achieved by the creation of self-heating composite tools which are appli-cable in an RTM process. The aim is to establish a set of full-sized rotor blade tools for a low-cost and energy efficient RTM cycle. This contains two tools (upper and lower mold) for preforming, consecutively referred to as “preforming tool” and two molds that form the impregnation and curing cavity, consecutively referred to as “RTM tool”.

Considering the RTM tool, the self-heating property is to be achieved with heating elements that are integrated into the composite structure near the cavity surface. The carbon textile heat-ing elements are flexibly distributed in reference to the mould surface in such a manner, that temperature gradients over the entire tool can be created.
During the project alternative systems which offer the equivalent potentials for heating like electrically heat able coatings will be considered and evaluated. Enhanced local heating device capable of high and homogeneous temperature for tool manufacturing will be investigated.
Integration and enhancement of process simulation tools in the design process for the RTM tool will provide feedback on setup variants in terms of temperature and material property distri-bution like glass transition temperature and degree of cure, as well as the resulting part’s shape “as built”, and thereby will help to establish a RTM tool design including the advanced heating concept “first right”. Curing simulation is the tool of choice to analyse the thermal response of the tool part setup including the energy release due to the crosslinking reaction of the resin and is vital for virtual process and tool optimization.

To verify the achievements concerning environmental impact a gate to gate life cycle assessment will be performed.

Aufforderung zur Vorschlagseinreichung

SP1-JTI-CS-2012-02
Andere Projekte für diesen Aufruf anzeigen

Koordinator

TECHNISCHE UNIVERSITAET MUENCHEN
Adresse
Arcisstrasse 21
80333 Muenchen
Deutschland

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Aktivitätstyp
Higher or Secondary Education Establishments
Kontakt Verwaltung
Elisabeth Ladstätter (Dr.)
EU-Beitrag
€ 276 750

Beteiligte (2)

QPOINT COMPOSITE GmbH
Deutschland
EU-Beitrag
€ 203 043
Adresse
Breitscheidstrasse 78
01237 Dresden

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Aktivitätstyp
Private for-profit entities (excluding Higher or Secondary Education Establishments)
Kontakt Verwaltung
Matti Reppe (Mr.)
FRAUNHOFER GESELLSCHAFT ZUR FORDERUNG DER ANGEWANDTEN FORSCHUNG EV
Deutschland
EU-Beitrag
€ 30 022
Adresse
Hansastrasse 27c
80686 Munchen

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Aktivitätstyp
Research Organisations
Kontakt Verwaltung
Andrea Zeumann (Ms.)