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Towards Enhanced Integration of Design and Production in the Factory of the Future through Isogeometric Technologies

Towards Enhanced Integration of Design and Production in the Factory of the Future through Isogeometric Technologies

Objective

The project aims at significant improvement of the interoperability of computational tools for the design, analysis and optimization of functional products. An isogeometric approach is applied for selected manufacturing application areas (cars, trains, aircraft) and for computer-aided machining. Computer Aided Design and numerical simulation algorithms are vital technologies in modern product development, yet they are today far from being seamlessly integrated. Their interoperability is severely disturbed by inconsistencies in the mathematical approaches used. Efficient feedback from analysis to CAD and iterative refinement of the analysis model is a feature of isogeometric analysis, and would be an essential improvement for computer-based design optimization and virtual product development. The new paradigm of isogeometric analysis demonstrates that much is to be gained in efficiency, quality and accuracy of the analysis step by replacing traditional Finite Elements by volumetric (trivariate) NURBS elements.
A general uptake of isogeometric approaches in industry can only be expected if there exist convincing technically verified and validated case studies showing real advantages over the current approaches, using both qualitative and quantitative indicators. It is also clear that the prior knowledge, such as it is contained in existing CAD-models, CAD-systems and numerical solvers, cannot just be dumped. It has to be investigated how the isogeometric concepts can actually be introduced on a large scale, starting from the interoperability of typical CAD-models and new isogeometric CAD-models all the way to product data management issues and standards.
Our vision is to provide and disseminate tangible evidence of the performance of the isogeometric approach in comparison to traditional ones in four important application areas as well as addressing interoperability and other issues that necessarily arise in a large-scale industrial introduction of isogeometry.
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Coordinator Contact

Tor DOKKEN (Dr)

Coordinator

STIFTELSEN SINTEF

Address

Strindveien 4
7034 Trondheim

Norway

Activity type

Higher or Secondary Education Establishments

EU Contribution

€ 616 902

Administrative Contact

Roger Bjørgan Moe (Mr.)

Participants (9)

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UNIVERSITAT LINZ

Austria

EU Contribution

€ 287 589

ENGINEERING CENTER STEYR GMBH & CO KG

Austria

EU Contribution

€ 306 000

SIEMENS AKTIENGESELLSCHAFT

Germany

EU Contribution

€ 344 470

TECHNISCHE UNIVERSITAET KAISERSLAUTERN

Germany

EU Contribution

€ 279 700

TOPSOLID

France

EU Contribution

€ 362 177

INSTITUT NATIONAL DE RECHERCHE ENINFORMATIQUE ET AUTOMATIQUE

France

EU Contribution

€ 328 179

ALENIA AERMACCHI SPA

Italy

EU Contribution

€ 308 453

UNIVERSITA DEGLI STUDI DI PAVIA

Italy

EU Contribution

€ 279 700

JOTNE EPM TECHNOLOGY AS

Norway

EU Contribution

€ 382 830

Project information

Grant agreement ID: 284981

Status

Closed project

  • Start date

    1 September 2011

  • End date

    31 August 2014

Funded under:

FP7-ICT

  • Overall budget:

    € 5 213 450

  • EU contribution

    € 3 496 000

Coordinated by:

STIFTELSEN SINTEF

Norway