A Comprehensive Approach for the Optimal Control of Tiltrotor Cabin Noise Through Actively-Driven Piezoelectric Actuators

This paper deals with the abatement of the tonal noise generated by the propulsive system inside the fuselage of a mid-range tiltrotor aircraft. The problem is basically multidisciplinary, involving interactions among exterior noise field, elastic fuselage dynamics, interior acoustics and control system. A stiffened fuselage, with piezoelectric patches embedded into the structure, is supposed to be impinged by the aeroacoustic field generated by propellers and forced by the wing/pylon/proprotor vibratory loads at the wing-fuselage attachment. An optimal LQR cyclic control formulation, coupled with a genetic optimization algorithm (GA), is applied to synthesize the control law driving the smart actuators so as to alleviate cabin noise. The aeroacoustoelastic model considered in the control problem is obtained by combining a modal approach for the description of the acoustic field within the cabin, the elastic displacements of the smart shell and the wing/pylon/proprotor system, with a Boundary Element Method (BEM) for the prediction of exterior pressure disturbances. Numerical results examine the effectiveness and robustness of the proposed active control strategy when synthesized through the proposed LQR/GA algorithms.

[1]  Giovanni Bernardini,et al.  Analysis of Vibrations of an Innovative Civil Tiltrotor , 2013 .

[2]  Robert E. Smith,et al.  Adaptively Resizing Populations: Algorithm, Analysis, and First Results , 1993, Complex Syst..

[3]  Massimo Gennaretti,et al.  A boundary integral formulation for sound scattered by elastic moving bodies , 2008 .

[4]  M. Gennaretti,et al.  Optimal design of tonal noise control inside smart-stiffened cylindrical shells , 2012 .

[5]  Lothar Thiele,et al.  Comparison of Multiobjective Evolutionary Algorithms: Empirical Results , 2000, Evolutionary Computation.

[6]  J. S. Mixson,et al.  Review of recent research on interior noise of propeller aircraft , 1985 .

[7]  Daniel Raymer,et al.  Enhancing Aircraft Conceptual Design using Multidisciplinary Optimization , 2002 .

[8]  Giovanni Bernardini,et al.  Optimal Design and Acoustic Assessment of Swept-tip Helicopter Rotor Blades , 2012 .

[9]  Giovanni Bernardini,et al.  Tiltrotor Wing-Root Vibratory Loads Reduction Through Higher Harmonic Control Actuation , 2012 .

[10]  A. Leissa,et al.  Vibration of shells , 1973 .

[11]  Giovanni Bernardini,et al.  Aircraft Cabin Tonal Noise Alleviation Through Fuselage Skin Embedded Piezoelectric Actuators , 2011 .

[12]  Giovanni Bernardini,et al.  Aeroelastic response of helicopter rotors using a 3D unsteady aerodynamic solver , 2006, The Aeronautical Journal (1968).

[13]  Giovanni Bernardini,et al.  Novel Boundary Integral Formulation for Blade-Vortex Interaction Aerodynamics of Helicopter Rotors , 2007 .

[14]  Giovanni Bernardini,et al.  Cabin Noise Alleviation Through Fuselage Skin Embedded Smart Actuators , 2009 .

[15]  Douglas G. MacMartin COLLOCATED STRUCTURAL CONTROL FOR REDUCTION OF AIRCRAFT CABIN NOISE , 1996 .

[16]  Giovanni Bernardini,et al.  Prediction of Tiltrotor Vibratory Loads with Inclusion of Wing­-Proprotor Aerodynamic Interaction , 2010 .

[17]  Giovanni Bernardini,et al.  Aeroacousto-Elastic Modeling for Response Analysis of Helicopter Rotors , 2012 .

[18]  Giovanni Bernardini,et al.  Automated Marine Propeller Optimal Design Combining Hydrodynamics Models and Neural Networks , 2012 .