This paper is concerned with the evaluation of design techniques, both for the propulsive performance and for the structural behavior of a composite flexible proprotor. A numerical model was developed using a combination of aerodynamic model based on Blade Element Momentum Theory (BEMT), and structural model based on anisotropic beam finite element, in order to evaluate the coupled structural and the aerodynamic characteristics of the deformable proprotor blade. The numerical model was then validated by means of static performance measurements and shape reconstruction from Laser Distance Sensor (LDS) outputs. From the validation results of both aerodynamic and structural model, it can be concluded that the numerical approach developed by the authors is valid as a reliable tool for designing and analyzing the UAV-sized proprotor made of composite material. The proposed experiment technique is also capable of providing a predictive and reliable data in blade geometry and performance for rotor modes

Bénard, Emmanuel

Lv, Peng

Mohd Zawawi, Fazila

Morlier, Joseph

Moschetta, Jean-Marc

Prothin, Sebastien

English

This paper is concerned with the evaluation of design techniques, both for the propulsive performance and for the structural behaviour of a composite flexible proprotor. A numerical model was developed using a combination of aerodynamic model based on blade element momentum theory (BEMT), and structural model based on anisotropic beam finite element, in order to evaluate the coupled structural and the aerodynamic characteristics of the deformable proprotor blade. The numerical model was then validated by means of static performance measurements and shape reconstruction from laser distance sensor outputs. From the validation results of both aerodynamic and structural model, it can be concluded that the numerical approach developed by the authors is valid as a reliable tool for designing and analysing the UAV-sized proprotor made of composite material. The proposed experiment technique is also capable of providing a predictive and reliable data in blade geometry and performance for rotor modes

Open Archive Toulouse Archive Ouverte

Study of a flexible UAV proprotor

International audienceThis paper is concerned with the evaluation of design techniques, both for the propulsive performance and for the structural behavior of a composite flexible proprotor. A numerical model was developed using a combination of aerodynamic model based on Blade Element Momentum Theory (BEMT), and structural model based on anisotropic beam finite element, in order to evaluate the coupled structural and the aerodynamic characteristics of the deformable proprotor blade. The numerical model was then validated by means of static performance measurements and shape reconstruction from Laser Distance Sensor (LDS) outputs. From the validation results of both aerodynamic and structural model, it can be concluded that the numerical approach developed by the authors is valid as a reliable tool for designing and analyzing the UAV-sized proprotor made of composite material. The proposed experiment technique is also capable of providing a predictive and reliable data in blade geometry and performance for rotor modes

Archive Ouverte en Sciences de l'Information et de la Communication

Study of a Flexible UAV Proprotor

HAL-INSA Toulouse

Aerodynamic Design of Micro Air Vehicles for Vertical Flight,

BECAS V2, A cross-section analysis tool for anisotropic and inhomogeneous beam sections of arbitrary geometry,” RisøTechnicalReportRisø-R 1785,TechnicalUniversity of Denmark,

Developing Anisotropic Beam Element for Design Composite Wind Turbine Blades,

Experimental Analysis of a Fixed Wing VTOL. MAV in Ground Effect,

Full-Field Dynamic Displacement and Strain Measurement Using

Helicopter Aerodynamics. Cambridge, 2nd edition,

Hover Performance of a Micro Air Vehicle: Rotor at Low Reynolds number,

Improvements to Tilt Rotor PerformanceThrough Passive Blade Twist Control,

Measurement of Deformation of Rotating Blades Using

Measurement of Rotorcraft Blade Deformation Using Projection Moire Interferometry,

Optical Methods in Engineering Metrology, Chapman and Hall,

Wind tunnel tests of wings at Reynolds numbers below 70,000,

XFOIL: An Analysis and Design System for Low Reynolds Number Airfoil, Low Reynolds Number Aerodynamics,

International audienceThis paper is concerned with the evaluation of design techniques, both for the propulsive performance and for the structural behaviour of a composite flexible proprotor. A numerical model was developed using a combination of aerodynamic model based on blade element momentum theory (BEMT), and structural model based on anisotropic beam finite element, in order to evaluate the coupled structural and the aerodynamic characteristics of the deformable proprotor blade. The numerical model was then validated by means of static performance measurements and shape reconstruction from laser distance sensor outputs. From the validation results of both aerodynamic and structural model, it can be concluded that the numerical approach developed by the authors is valid as a reliable tool for designing and analysing the UAV-sized proprotor made of composite material. The proposed experiment technique is also capable of providing a predictive and reliable data in blade geometry and performance for rotor modes

http://oatao.univ-toulouse.fr/11305/1/Mohd-Zawawi_11305.pdf

Study of a Flexible UAV Proprotor

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Open Archive Toulouse Archive Ouverte

Archive Ouverte en Sciences de l'Information et de la Communication

HAL-INSA Toulouse

Open Archive Toulouse Archive Ouverte

Archive Ouverte en Sciences de l'Information et de la Communication

HAL-INSA Toulouse