固体火箭技术
固體火箭技術
고체화전기술
Journal of Solid Rocket Technology
2015年
5期
601-607,652
,共8页
尉建利%王聪%葛颖琛%闫杰
尉建利%王聰%葛穎琛%閆傑
위건리%왕총%갈영침%염걸
高超声速飞行器%操纵性%控制律%一体化设计
高超聲速飛行器%操縱性%控製律%一體化設計
고초성속비행기%조종성%공제률%일체화설계
hypersonic vehicle%manipulability%control law%integrated design
高超声速飞行器主要飞行阶段包括助推分离段、巡航段和下降段,在分离段操纵面的任务是快速抑制分离扰动,而巡航段主要用于高精度姿态控制. 针对分离段和巡航段对舵面操纵性要求差别较大的特点,本文探讨从满足控制要求的角度对操纵面尺寸进行优化设计的方法,即操纵性/控制律一体化设计. 采用最优控制方法对飞行器自动驾驶仪增益进行优化,并基于多目标遗传算法的并行子空间优化方法,得到了高超声速飞行器最优舵面外形尺寸和相应的控制律. 仿真结果表明,最优舵面在分离段能够快速抑制分离扰动对飞行器姿态的影响,并将飞行器姿态迅速调整到发动机点火窗口;在巡航段能够快速抑制阵风干扰对飞行器姿态的影响,稳定飞行器姿态,为高超声速飞行器操纵性设计提供了依据.
高超聲速飛行器主要飛行階段包括助推分離段、巡航段和下降段,在分離段操縱麵的任務是快速抑製分離擾動,而巡航段主要用于高精度姿態控製. 針對分離段和巡航段對舵麵操縱性要求差彆較大的特點,本文探討從滿足控製要求的角度對操縱麵呎吋進行優化設計的方法,即操縱性/控製律一體化設計. 採用最優控製方法對飛行器自動駕駛儀增益進行優化,併基于多目標遺傳算法的併行子空間優化方法,得到瞭高超聲速飛行器最優舵麵外形呎吋和相應的控製律. 倣真結果錶明,最優舵麵在分離段能夠快速抑製分離擾動對飛行器姿態的影響,併將飛行器姿態迅速調整到髮動機點火窗口;在巡航段能夠快速抑製陣風榦擾對飛行器姿態的影響,穩定飛行器姿態,為高超聲速飛行器操縱性設計提供瞭依據.
고초성속비행기주요비행계단포괄조추분리단、순항단화하강단,재분리단조종면적임무시쾌속억제분리우동,이순항단주요용우고정도자태공제. 침대분리단화순항단대타면조종성요구차별교대적특점,본문탐토종만족공제요구적각도대조종면척촌진행우화설계적방법,즉조종성/공제률일체화설계. 채용최우공제방법대비행기자동가사의증익진행우화,병기우다목표유전산법적병행자공간우화방법,득도료고초성속비행기최우타면외형척촌화상응적공제률. 방진결과표명,최우타면재분리단능구쾌속억제분리우동대비행기자태적영향,병장비행기자태신속조정도발동궤점화창구;재순항단능구쾌속억제진풍간우대비행기자태적영향,은정비행기자태,위고초성속비행기조종성설계제공료의거.
The main flight phases of a hypersonic vehicle include propulsion-assisted separation phase,cruise phase and descent phase.In the separation phase,the task of control surface is to suppress the separation perturbation of the hypersonic vehicle quickly, but in the cruise phase,the task is to achieve the high-precision control of its attitude.During these two phases,the requirements for the manipulability of the rudder surface are rather different.To satisfy the control requirements,this paper explores the control surface dimension optimization and design method,namely the manipulability and control law integrated design method. It uses the optimal control method to optimize the gains of the autopilot of the hypersonic vehicle and then optimizes the boundary dimensions of its opti-mal rudder surface and its control law with the parallel subspace optimization method of the multi-objective genetic algorithm. The simulation results show that,during the separation phase,he optimal rudder surface can quickly suppress the influence of separation perturbation on the attitude of the hypersonic vehicle and quickly adjust its attitude to the engine ignition window and that,during the cruise phase,the optimal rudder surface can quickly suppress the influence of gust interference on the attitude and thus stabilize it.This exploration sheds light on a hypersonic vehicle's manipulability design.