多控制面机翼/外挂系统的跨音速气动伺服弹性研究

项目名称： 多控制面机翼/外挂系统的跨音速气动伺服弹性研究

项目编号： No.11502106

项目类型： 青年科学基金项目

立项/批准年度： 2016

项目学科： 数理科学和化学

项目作者： 黄锐

作者单位： 南京航空航天大学

项目金额： 22万元

中文摘要： 跨音速气动力的非线性特性，使得跨音速气动伺服弹性研究极具挑战性。本项目以多控制面机翼/外挂系统为研究对象，围绕三维机翼的跨音速气动伺服弹性问题开展研究。主要研究工作如下：（1）针对由Navier-Stokes方程描述的三维跨音速空气动力系统，采用非线性系统辨识理论，提出一种新的非线性模型降阶方法；（2）基于非线性降阶模型开展机翼/外挂系统的跨音速气动弹性分析，并研究影响非线性降阶模型预测极限环振荡精度的机理；（3）研究前后缘控制面偏转引起的气动力非线性对跨音速气动伺服弹性系统的影响并建立多输入/多输出、非线性气动伺服弹性模型；（4）针对机翼/外挂系统跨音速气动伺服弹性行为的复杂性，设计具有高稳定性裕度的多输入/多输出鲁棒控制系统，抑制跨音速颤振失稳和极限环振荡。本项目旨在解决机翼/外挂系统的高效跨音速气动弹性分析和气动弹性主动控制问题，为先进随控布局飞机设计提供重要理论基础和关键技术储备。

中文关键词： 非线性气动弹性力学；跨音速颤振主动抑制；极限环振荡；非线性系统辨识；非线性模型降阶

英文摘要： Because of the nonlinear characteristics of transonic aerodynamic forces, it is a challenging task to study on the aeroservoelastic problems in transonic flight regimes. This project takes an elastic wing/store system with multiple control surfaces as a research subject and focus on the transonic aeroservoelastic analysis of a three-dimensional wing model. the main research work of this project can be summarized as follows: (1) Based on the theory of nonlinear system identification, a novel nonlinear reduced-order modeling approach is proposed for the three-dimensional, transonic aerodynamic systems described by the Navier-Stokes equations. (2) Transonic aeroservoelstic analysis of the wing/store system is implemented via the present nonlinear reduced-order model. Moreover, the influence mechanism of the present nonlinear reduced-order modeling approach in predcting the accuracy of the limit-cycle oscillations of the wing/store system is further investigated. (3) The effects of aerodynamic nonlinearity on the nonlinear behaviors of transonic aeroservoelastic systems are investigated, respectively. Moreover, a nonlinear mathmatical modeling approach for the multi-input/multi-output,transonic aeroservoelastic systems is built. (4) Because of the complexitiy of the transonic aeroservoelastic behaviors of the wing/store system, a multi-input/multi-ouput robust control system having high stability margin is synthesized to suppress the transonic flutter instability and limit-cycle oscillation of the wing/store system. This project is aim to deal with the problems of the efficient transonic aeroelastic analysis and aeroelastic active control of the wing/store system. The research achievements of this project will provide important theoretical foundation and technical reserves for designing the advanced control configuraed vehicles.

英文关键词： Nonlinear Aeroelasticity;Transonic Active Flutter Suppression;Limit-Cycle Oscillation;Nonlinear System Identification;Nonlinear Reduced-Order Model