In the present investigation, the helicopter blade is modelled as a rotating beam with two degrees of freedom, namely the elastic flatwise bending and torsion. A mathematical model in the frequency domain is developed, incorporating the incompressible unsteady aerodynamic loads associated with helicopters in forward flight. The effects of dynamic adaptation of the root boundary conditions on the beam aeroelastic response are studied. The results suggest that it is possible to control the local dynamic response at particular sections of the blade by varying the frequency and relative phase of the control signal
Governing equations are obtained for helicopter rotor blades with surface bonded piezoceramic actuat...
Active vibration control is a widely implemented method for the helicopter vibration control. Due to...
Active integral twist control for vibration reduction of helicopter rotors during forward flight is ...
In the present investigation, the helicopter blade is modeled as a rotating beam with two degrees of...
In the present paper, the aeroelastic stability of helicopter rotor blade is determined using Aeroel...
A flight dynamics model based on elastic blades for helicopters is developed. Modal shape analysis i...
International audienceThe dynamic loads transmitted from the rotor to the airframe are responsible f...
The paper presents the theoretical basis for the simulation of active helicopter blades. The analysi...
This paper investigates the feasibility of employing adaptive material to build both sensors and act...
An aeroelastic analysis based on finite elements in space and time is used to model the helicopter r...
Abstract. This paper describes the fundamental design approach of a mechanical device using smart st...
An individual blade controller designed to attenuate the aeroelastic response of helicopter rotors i...
Active integral twist control for vibration reduction of helicopter rotors during forward flight is ...
Applying adaptronics to helicopters has a high potential to significantly suppress noise, reduce vib...
Applying adaptronics to helicopters has a high potential to significantly suppress noise, reduce vib...
Governing equations are obtained for helicopter rotor blades with surface bonded piezoceramic actuat...
Active vibration control is a widely implemented method for the helicopter vibration control. Due to...
Active integral twist control for vibration reduction of helicopter rotors during forward flight is ...
In the present investigation, the helicopter blade is modeled as a rotating beam with two degrees of...
In the present paper, the aeroelastic stability of helicopter rotor blade is determined using Aeroel...
A flight dynamics model based on elastic blades for helicopters is developed. Modal shape analysis i...
International audienceThe dynamic loads transmitted from the rotor to the airframe are responsible f...
The paper presents the theoretical basis for the simulation of active helicopter blades. The analysi...
This paper investigates the feasibility of employing adaptive material to build both sensors and act...
An aeroelastic analysis based on finite elements in space and time is used to model the helicopter r...
Abstract. This paper describes the fundamental design approach of a mechanical device using smart st...
An individual blade controller designed to attenuate the aeroelastic response of helicopter rotors i...
Active integral twist control for vibration reduction of helicopter rotors during forward flight is ...
Applying adaptronics to helicopters has a high potential to significantly suppress noise, reduce vib...
Applying adaptronics to helicopters has a high potential to significantly suppress noise, reduce vib...
Governing equations are obtained for helicopter rotor blades with surface bonded piezoceramic actuat...
Active vibration control is a widely implemented method for the helicopter vibration control. Due to...
Active integral twist control for vibration reduction of helicopter rotors during forward flight is ...