Design and Optimization of Piezoelectric Actuators for Aeroacoustic Noises Control in a Turbofan

M. Perez, M. Ezzine, K. Billon, V. Clair, J. Mardjono, M. Collet
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Abstract

This paper reports on the design and optimization of different types of piezoelectric actuators for aeroacoustic control applications. This study was carried out within the context of the European project CleanSky 2/InnoSTAT. The aim of our work is to reduce the aeroacoustic noises that appear in an airplane turbofan by adding an area of piezoelectric actuators on the Outlet Guide Vanes (OGV). These piezoelectric structures will subsequently be controlled with an active approach and tested in the open-jet anechoic wind tunnel at LMFE. The noise source which has to be reduce/control comes from vortices located in the turbulent flow (which can for example be created by the fan module) interacting with the stator blades. The predominant frequencies and the pressure fluctuations levels related to these vortices rely on the airflow speed and are fixed between 1000Hz and 2000Hz in our case. To reach the target, we plan to manufacture an area of piezoelectric actuators on the intrados and the extrados of the stator blades in order to control the response of the blade to the turbulence of the airflow responsible for the aeroacoustic noise. Several adjacent blades will be equipped with this type of transducers. This study outline the design and the optimization of each piezoelectric cell in order to achieve good results in the frequency range previously defined as well as an acceptable mechanical strength of the blade. A most detailed study on the active shunt will be investigate later on.
涡扇气动噪声控制压电驱动器的设计与优化
本文报道了不同类型气动声控制用压电作动器的设计与优化。这项研究是在欧洲项目CleanSky 2/InnoSTAT的背景下进行的。我们的工作目的是通过在出口导叶(OGV)上增加压电致动器区域来降低飞机涡扇中出现的气动噪声。随后,这些压电结构将采用主动方法进行控制,并在LMFE的开放式射流消声风洞中进行测试。必须减少/控制的噪声源来自于与静叶相互作用的湍流中的涡流(例如风扇模块产生的涡流)。与这些旋涡相关的主要频率和压力波动水平取决于气流速度,在我们的情况下固定在1000Hz和2000Hz之间。为了达到这个目标,我们计划在静叶的内腔和外腔上制造一个压电致动器区域,以控制叶片对造成气动噪声的气流湍流的响应。几个相邻的叶片将配备这种类型的传感器。本研究概述了每个压电单元的设计和优化,以便在先前定义的频率范围内取得良好的效果以及叶片的可接受的机械强度。关于主动分流的最详细的研究将在后面进行。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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