Summary
Future, sustainable, growth of the aviation industry relies on continued improvements in efficiency giving reductions in fuelcconsumption and increases in payload. Research efforts therefore focus on aerodynamic performance and structural weightcsavings. This inherently requires more highly performing wings, control surfaces and turbomachinery blades where transoniccflow is common place and the formation of shock waves the key aerodynamic challenge. In particular, the interaction ofcshock waves with boundary-layers is one of, if not the main performance-limiting or safety critical flow phenomena across all of these flow fields. Thus, a good understanding of the interaction of shock waves with boundary layers is essential for the development of future, more efficient, air vehicles and engines.
Increased aerodynamic forces can lead to flow separation and reductions in engine and airframe efficiency. In such cases, flow control is needed to maintain system performance. However, novel designs are also likely to increase the extent of laminar flow and this implies that flow control devices need to operate in a laminar or transitional regime. This requires a better understanding of their function and their interaction with flow transition.
The main research objectives of the TEAMAero project are: (1) improvement of fundamental understanding of shock wave boundary layer interaction (SBLI) physics including three-dimensionality and unsteadiness (2) identification of flow domains best suited to flow control device installation (3) development of flow control schemes using wall transpiration (suction/blowing), vortex generators and surface treatments to delay the separation onset, and (4) development of novel numerical will be updated methods for the prediction of SBLI effects.
Increased aerodynamic forces can lead to flow separation and reductions in engine and airframe efficiency. In such cases, flow control is needed to maintain system performance. However, novel designs are also likely to increase the extent of laminar flow and this implies that flow control devices need to operate in a laminar or transitional regime. This requires a better understanding of their function and their interaction with flow transition.
The main research objectives of the TEAMAero project are: (1) improvement of fundamental understanding of shock wave boundary layer interaction (SBLI) physics including three-dimensionality and unsteadiness (2) identification of flow domains best suited to flow control device installation (3) development of flow control schemes using wall transpiration (suction/blowing), vortex generators and surface treatments to delay the separation onset, and (4) development of novel numerical will be updated methods for the prediction of SBLI effects.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/860909 |
| Start date: | 01-04-2020 |
| End date: | 30-06-2024 |
| Total budget - Public funding: | 3 955 103,64 Euro - 3 955 103,00 Euro |
Cordis data
Original description
Future, sustainable, growth of the aviation industry relies on continued improvements in efficiency giving reductions in fuelcconsumption and increases in payload. Research efforts therefore focus on aerodynamic performance and structural weightcsavings. This inherently requires more highly performing wings, control surfaces and turbomachinery blades where transoniccflow is common place and the formation of shock waves the key aerodynamic challenge. In particular, the interaction ofcshock waves with boundary-layers is one of, if not the main performance-limiting or safety critical flow phenomena across all of these flow fields. Thus, a good understanding of the interaction of shock waves with boundary layers is essential for the development of future, more efficient, air vehicles and engines.Increased aerodynamic forces can lead to flow separation and reductions in engine and airframe efficiency. In such cases, flow control is needed to maintain system performance. However, novel designs are also likely to increase the extent of laminar flow and this implies that flow control devices need to operate in a laminar or transitional regime. This requires a better understanding of their function and their interaction with flow transition.
The main research objectives of the TEAMAero project are: (1) improvement of fundamental understanding of shock wave boundary layer interaction (SBLI) physics including three-dimensionality and unsteadiness (2) identification of flow domains best suited to flow control device installation (3) development of flow control schemes using wall transpiration (suction/blowing), vortex generators and surface treatments to delay the separation onset, and (4) development of novel numerical will be updated methods for the prediction of SBLI effects.
Status
SIGNEDCall topic
MSCA-ITN-2019Update Date
28-04-2024
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Organisations
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| INSTYTUT MASZYN PRZEPLYWOWYCH IM ROBERTA SZEWALSKIEGO POLSKIEJ AKADEMII NAUK - IMP PAN (Coördinator)
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| DEUTSCHES ZENTRUM FUR LUFT - UND RAUMFAHRT EV
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| INSTITUT NATIONAL POLYTECHNIQUE DE TOULOUSE
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| NUMERICAL MECHANICS APPLICATIONS INTERNATIONAL SA
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| OFFICE NATIONAL D'ETUDES ET DE RECHERCHES AEROSPATIALES (ONERA)
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| ROLLS-ROYCE DEUTSCHLAND LTD & CO KG
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| TECHNISCHE UNIVERSITAT BERLIN
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| TECHNISCHE UNIVERSITEIT DELFT
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| THE UNIVERSITY OF CAMBRIDGE
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| UNIVERSITA DEGLI STUDI DI ROMA LA SAPIENZA
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| UNIVERSITE D'AIX MARSEILLE (AMU)
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| UNIVERSITY OF GLASGOW