基于试验分岔分析的翼身融合飞行器纵向稳定性

付军泉; 史志伟; 耿玺; 朱佳晨; 王力爽; 吴大卫; 潘立军

doi:10.7527/S1000-6893.2020.24931

航空学报 >

2022 , Vol. 43 >Issue 1: 124931 - 124931

DOI: https://doi.org/10.7527/S1000-6893.2020.24931

流体力学与飞行力学

基于试验分岔分析的翼身融合飞行器纵向稳定性

付军泉 ,
史志伟 ,
耿玺 ,
朱佳晨 ,
王力爽 ,
吴大卫 ,
潘立军

展开

1. 南京航空航天大学航空学院, 南京 210016;
2. 中国商飞上海飞机设计研究院, 上海 201210

收稿日期: 2020-10-30

修回日期: 2020-12-15

网络出版日期: 2020-12-14

基金资助

国家自然科学基金（12072155）；江苏高校优势学科建设工程资助项目；非定常空气动力学与流动控制工信部重点实验室

收起

Longitudinal stability of blended-wing-body aircraft based on experimental bifurcation analysis

FU Junquan ,
SHI Zhiwei ,
GENG Xi ,
ZHU Jiachen ,
WANG Lishuang ,
WU Dawei ,
PAN Lijun

Expand

1. College of Aerospace Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China;
2. COMAC Shanghai Aircraft Design and Research Institute, Shanghai 201210, China

Received date: 2020-10-30

Revised date: 2020-12-15

Online published: 2020-12-14

Supported by

National Natural Science Foundation of China (12072155); Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions; Key Laboratory of Unsteady Aerodynamics and Flow Control, Ministry of Industry and Information Technology

Fold

摘要

针对翼身融合布局飞行器的纵向稳定性问题，基于分支和突变理论，求解迎角随升降舵变化的平衡分岔图，并对平衡分支的稳定性和突变点进行了分析。结合风洞虚拟飞行试验技术，发展了试验分岔分析方法，并设计了基于非线性动态逆的伪线性控制器，由此获得并分析了开环试验和闭环试验平衡分岔图。对比分析表明，理论分岔分析与开环试验分岔分析在小迎角范围结果基本一致，验证了试验分岔分析方法的可行性和准确性；翼身融合飞行器产生纵向失稳的主要原因是机翼表面流动分离，从而导致C_mα发生突变引起的；闭环试验分岔分析实现了翼身融合飞行器非线性全局稳定性控制，通过纵向非线性控制器，可以将不稳定平衡分支改造成稳定的平衡分支。

关键词： 翼身融合(BWB); 纵向稳定性; 试验分岔分析; 虚拟飞行试验; 非线性动态逆

本文引用格式

付军泉 , 史志伟 , 耿玺 , 朱佳晨 , 王力爽 , 吴大卫 , 潘立军 . 基于试验分岔分析的翼身融合飞行器纵向稳定性[J]. 航空学报, 2022 , 43(1) : 124931 -124931 . DOI: 10.7527/S1000-6893.2020.24931

Abstract

Bifurcation analysis and the catastrophe theory are used to study the longitudinal stability of Blended-Wing-Body (BWB) aircraft. Equilibrium branches of the angle of attack with the elevator are obtained, and stability of the branches and the catastrophe points analyzed. Then bifurcation analysis is introduced into the virtual flight tests to physically track the equilibrium branches, enabling the experimental bifurcation analysis research in the wind tunnel. A pseudo-linear controller based on the nonlinear dynamic inverse is designed, with the open-loop and closed-loop experimental bifurcation diagrams obtained and analyzed. The comparative analysis shows that the theoretical bifurcation analysis and the open-loop experimental bifurcation analysis are basically consistent in the range of small angles of attack, verifying the feasibility and accuracy of the experimental bifurcation analysis method. The longitudinal instability of the BWB aircraft is mainly caused by the sudden changes of C_mα. The closed-loop experimental bifurcation analysis realizes the nonlinear global stability control, transforming the unstable equilibrium branch into a stable one through the longitudinal nonlinear controller.

Key words： Blended-Wing-Body (BWB); longitudinal stability; experimental bifurcation analysis; virtual flight tests; nonlinear dynamic inversion

参考文献

[1] AMMAR S, LEGROS C, TRÉPANIER J Y. Conceptual design, performance and stability analysis of a 200 passengers blended wing body aircraft[J]. Aerospace Science and Technology, 2017, 71: 325-336.
[2] LARKIN G, COATES G. A design analysis of vertical stabilisers for Blended Wing Body aircraft[J]. Aerospace Science and Technology, 2017, 64: 237-252.
[3] LIEBECK R H. Design of the blended wing body subsonic transport[J]. Journal of Aircraft, 2004, 41(1): 10-25.
[4] 王刚, 张彬乾, 张明辉, 等. 翼身融合民机总体气动技术研究进展与展望[J]. 航空学报, 2019, 40(9): 623046. WANG G, ZHANG B Q, ZHANG M H, et al. Research progress and prospect for conceptual and aerodynamic technology of blended-wing-body civil aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2019, 40(9): 623046(in Chinese).
[5] VELAZQUEZ O, WEISS J, MORENCY F. Preliminary investigation on stall characteristics of a regional BWB for low speed approach[C]//35th AIAA Applied Aerodynamics Conference. Reston: AIAA, 2017: 3738.
[6] LU Y, ZHANG S G, ZHANG Z J, et al. Multiple hierarchy risk assessment with hybrid model for safety enhancing of unmanned subscale BWB demonstrator flight test[J]. Chinese Journal of Aeronautics, 2019, 32(12): 2612-2626.
[7] KWATNY H G, DONGMO J E T, CHANG B C, et al. Nonlinear analysis of aircraft loss of control[J]. Journal of Guidance, Control, and Dynamics, 2012, 36(1): 149-162.
[8] SHEN L, HUANG D, WU G X. Effects of yaw-roll coupling ratio on the lateral-directional departure prediction and restraint[J]. Chinese Journal of Aeronautics, 2019, 32(10): 2239-2253.
[9] DONG Y Z, SHI Z W, CHEN K, et al. The suppression of flying-wing roll oscillations with open and closed-loop spanwise blowing[J]. Aerospace Science and Technology, 2020, 99: 105766.
[10] 付军泉, 史志伟, 周梦贝, 等. 一种翼身融合飞行器的失速特性研究[J]. 航空学报, 2020, 41(1): 123176. FU J Q, SHI Z W, ZHOU M B, et al. Stall characteristics research of blended-wing-body aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2020, 41(1): 123176(in Chinese).
[11] MURPHY P C, KLEIN V, FRINK N T. Nonlinear unsteady aerodynamic modeling using wind-tunnel and computational data[J]. Journal of Aircraft, 2016, 54(2): 659-683.
[12] OWENS B, BRANDON J, CROOM M, et al. Overview of dynamic test techniques for flight dynamics research at NASA LaRC[C]//25th AIAA Aerodynamic Measurement Technology and Ground Testing Conference. Reston: AIAA, 2006.
[13] LUTZE F H, DURHAM W C, MASON W H. Unified development of lateral-directional departure criteria[J]. Journal of Guidance, Control, and Dynamics, 1996, 19(2): 489-493.
[14] MAYER R H, ZONDERVAN D J. Concept and benefits of a unified departure operation spacing standard[C]//2012 IEEE/AIAA 31 st Digital Avionics Systems Conference (DASC). Piscataway: IEEE, 2012: 4A6-1.
[15] PARANJAPE A A, ANANTHKRISHNAN N. Analytical criterion for aircraft spin susceptibility[J]. Journal of Aircraft, 2010, 47(5): 1804-1807.
[16] PARANJAPE A, SINHA N, ANANTHKRISHNAN N. Use of bifurcation and continuation methods for aircraft trim and stability analysis-A state-of-the-art[C]//45th AIAA Aerospace Sciences Meeting and Exhibit. Reston: AIAA, 2007.
[17] LOWENBERG M H. Bifurcation analysis as a tool for post-departure stability enhancement[C]//22nd Atmospheric Flight Mechanics Conference. Reston: AIAA, 1997.
[18] SHARMA S, COETZEE E B, LOWENBERG M H, et al. Numerical continuation and bifurcation analysis in aircraft design: An industrial perspective[J]. Philosophical Transactions Series A, Mathematical, Physical, and Engineering Sciences, 2015, 373: 20140406.
[19] GILL S J, LOWENBERG M H, NEILD S A, et al. Upset dynamics of an airliner model: A nonlinear bifurcation analysis[J]. Journal of Aircraft, 2013, 50(6): 1832-1842.
[20] 高浩, 周志强. 高机动性飞机大迎角全局稳定性研究[J]. 航空学报, 1987, 8(11): 561-571. GAO H, ZHOU Z Q. A study of the global. stability of high performance aircrafts at high angle-of-attack[J]. Acta Aeronautica et Astronautica Sinica, 1987, 8(11): 561-571(in Chinese).
[21] 黎康, 方振平. 分叉分析方法在大迎角控制律设计中的应用[J]. 航空学报, 2003, 24(4): 289-292. LI K, FANG Z P. Application of bifurcation analysis to control law design at high angles of attack[J]. Acta Aeronautica et Astronautica Sinica, 2003, 24(4): 289-292(in Chinese).
[22] 刘昶, 赵波. 应用分支和突变理论对飞机空间机动稳定性的研究[J]. 航空学报, 1988, 9(9): 399-408. LIU C, ZHAO B. A study of aircraft global dynamic stability in maneuver by using the bifurcation and catastropha theory[J]. Acta Aeronautica et Astronautica Sinica, 1988, 9(9): 399-408(in Chinese).
[23] 陈永亮. 飞机大迎角非线性动力学特性分析与控制[D]. 南京: 南京航空航天大学, 2007. CHEN Y L. Nonlinear dynamic characteristics analysis and control of aircraft at high-angle-of-attack[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2007(in Chinese).
[24] GONG Z, ARAUJO-ESTRADA S, LOWENBERG M H, et al. Experimental investigation of aerodynamic hysteresis using a five-degree-of-freedom wind-tunnel maneuver rig[J]. Journal of Aircraft, 2019, 56(3): 1029-1039.
[25] PATTINSON J, LOWENBERG M H, GOMAN M G. Investigation of poststall pitch oscillations of an aircraft wind-tunnel model[J]. Journal of Aircraft, 2013, 50(6): 1843-1855.
[26] 董彦非, 荣康, 高杰. 飞机飞行品质规范发展综述[J]. 飞行力学, 2010, 28(5): 1-4. DONG Y F, RONG K, GAO J. Development of aircraft flying qualities specification[J]. Flight Dynamics, 2010, 28(5): 1-4(in Chinese).

Options

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献