Summary
MADELEINE will increase the TRL and demonstrate the benefits of high-fidelity (HiFi), adjoint-based multi-disciplinary optimisation (MDO) to address the objectives of industry in terms of:
- Competitiveness: by reducing time and cost of aircraft or engine development;
- Environment: by finding more efficient multi-disciplinary compromises and fostering the integration of greener technologies.
More specifically MADELEINE will:
- Upgrade the Capability of MDO, enhanced by HiFi simulations, to capture the essential interactions between disciplines and faster identify better designs or evaluate the potential of new technologies and disruptive configurations;
- Improve the Efficiency of MDO, because the efficient identification of designs, satisfying all disciplines’ constraints, requires the exploration of large design spaces;
- Enhance the Usability of MDO for industrial design, through dedicated modelling, which will reduce the time to setup an MDO problem and exploit the results;
- Extend the Impact of MDO on cost reduction by including requirements from manufacturing.
The technologies (Multi-physics adjoint solvers, parameterisations, MDO formulations, High Performance Computing, manufacturing oriented design) will be demonstrated for airframe and engine design: aero-structure wing design, aero-acoustic fan and propeller design, manufacturing oriented aero-structure fan design and manufacturing oriented aero-thermal high-pressure turbine design. The TRL of MDO on large design spaces, with hundreds or thousands of parameters of optimisation, is expected to increase from 2-3 to 4-6.
MADELEINE will last 36 months (EC requested contribution of 5 815 182€), gathering partners from 6 EU countries: 5 universities, 4 research centres, 2 software companies (including 1 SME) and 3 large industries. Their complementary expertise is essential for the realisation of the technical work, for achieving a broad dissemination and a large impact on all industries.
- Competitiveness: by reducing time and cost of aircraft or engine development;
- Environment: by finding more efficient multi-disciplinary compromises and fostering the integration of greener technologies.
More specifically MADELEINE will:
- Upgrade the Capability of MDO, enhanced by HiFi simulations, to capture the essential interactions between disciplines and faster identify better designs or evaluate the potential of new technologies and disruptive configurations;
- Improve the Efficiency of MDO, because the efficient identification of designs, satisfying all disciplines’ constraints, requires the exploration of large design spaces;
- Enhance the Usability of MDO for industrial design, through dedicated modelling, which will reduce the time to setup an MDO problem and exploit the results;
- Extend the Impact of MDO on cost reduction by including requirements from manufacturing.
The technologies (Multi-physics adjoint solvers, parameterisations, MDO formulations, High Performance Computing, manufacturing oriented design) will be demonstrated for airframe and engine design: aero-structure wing design, aero-acoustic fan and propeller design, manufacturing oriented aero-structure fan design and manufacturing oriented aero-thermal high-pressure turbine design. The TRL of MDO on large design spaces, with hundreds or thousands of parameters of optimisation, is expected to increase from 2-3 to 4-6.
MADELEINE will last 36 months (EC requested contribution of 5 815 182€), gathering partners from 6 EU countries: 5 universities, 4 research centres, 2 software companies (including 1 SME) and 3 large industries. Their complementary expertise is essential for the realisation of the technical work, for achieving a broad dissemination and a large impact on all industries.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/769025 |
| Start date: | 01-06-2018 |
| End date: | 30-11-2021 |
| Total budget - Public funding: | 5 815 181,00 Euro - 5 815 181,00 Euro |
Cordis data
Original description
MADELEINE will increase the TRL and demonstrate the benefits of high-fidelity (HiFi), adjoint-based multi-disciplinary optimisation (MDO) to address the objectives of industry in terms of:- Competitiveness: by reducing time and cost of aircraft or engine development;
- Environment: by finding more efficient multi-disciplinary compromises and fostering the integration of greener technologies.
More specifically MADELEINE will:
- Upgrade the Capability of MDO, enhanced by HiFi simulations, to capture the essential interactions between disciplines and faster identify better designs or evaluate the potential of new technologies and disruptive configurations;
- Improve the Efficiency of MDO, because the efficient identification of designs, satisfying all disciplines’ constraints, requires the exploration of large design spaces;
- Enhance the Usability of MDO for industrial design, through dedicated modelling, which will reduce the time to setup an MDO problem and exploit the results;
- Extend the Impact of MDO on cost reduction by including requirements from manufacturing.
The technologies (Multi-physics adjoint solvers, parameterisations, MDO formulations, High Performance Computing, manufacturing oriented design) will be demonstrated for airframe and engine design: aero-structure wing design, aero-acoustic fan and propeller design, manufacturing oriented aero-structure fan design and manufacturing oriented aero-thermal high-pressure turbine design. The TRL of MDO on large design spaces, with hundreds or thousands of parameters of optimisation, is expected to increase from 2-3 to 4-6.
MADELEINE will last 36 months (EC requested contribution of 5 815 182€), gathering partners from 6 EU countries: 5 universities, 4 research centres, 2 software companies (including 1 SME) and 3 large industries. Their complementary expertise is essential for the realisation of the technical work, for achieving a broad dissemination and a large impact on all industries.
Status
CLOSEDCall topic
MG-1.3-2017Update Date
26-10-2022
Images
No images available.
Geographical location(s)
Structured mapping
Search
Organisations
-
| OFFICE NATIONAL D'ETUDES ET DE RECHERCHES AEROSPATIALES (ONERA) (Coördinator)
-
| Airbus Operations SAS
-
| DASSAULT AVIATION
-
| DEUTSCHES ZENTRUM FUR LUFT - UND RAUMFAHRT EV
-
| ESI Group
-
| ESI NORDICS AB
-
| IRT ANTOINE DE SAINT EXUPERY
-
| L - UP SAS
-
| National Technical University of Athens
-
| OPTIMAD ENGINEERING SRL
-
| ROLLS-ROYCE PLC
-
| Stichting Nationaal Lucht- En Ruimtevaartlaboratorium (NLR - Royal Netherlands Aerospace Centre)
-
| TECHNISCHE UNIVERSITAET MUENCHEN
-
| THE UNIVERSITY OF SHEFFIELD
-
| UNIVERSITA DEGLI STUDI DI CAGLIARI (UNICA)