| 669 | 9 | 576 |
| Downloads | Citas | Reads |
The comprehensive aerodynamic performance in the flight envelope and the balance of the maneuverability and stability requirements of the aircraft can be improved by coordinated deflection of inner and outer wing sections of multi-section morphing wing. In view of the characteristics of multiple combined deformation modes provided by multi-section morphing wing, the typical morphing structures are analyzed.The research status and achievements of multi-section morphing wing are summarized in key technical fields such as intelligent material structure design, aerodynamic characteristics analysis, stability analysis and flight control system design. The technical difficulties and the key problems that the multi-section morphing wing is applied into the large size UAVs are pointed out, which can provide a reference for the research of key technologies of multi-section morphing wing and the development of morphing aircraft in the future.
[1]朱睿颖,齐征,王兰松,等.可变构型飞行器航迹优化设计[J].战术导弹技术,2020(5):157-164.
[2]武宇飞,龙腾,毛能峰.跨介质变体飞行器设计优化技术进展[J].战术导弹技术,2020(4):29-40.
[3]张泽鹏,院老虎,杜白雨,等.变体飞行器LPV建模与内外环鲁棒控制[J].战术导弹技术,2023(1):105-114.
[4] Barbarino S,Bilgen O,Ajaj R M,et al. A review of morphing aircraft[J]. Journal of Intelligent Material Systems&Structures,2011,22(9):823-877.
[5] Bowman J C,Plumley R W,Dubois J A,et al. Mission effectiveness comparisons of morphing and non-morphing vehicles[C]. 6th AIAA Aviation Technology,Integration and Operations Conference(ATIO),Wichita,Kansas,2006.
[6]艾俊强,李士途.变体飞机典型形式的历史发展及其应用机型浅析[J].航空工程进展,2010,1(3):205-209.
[7]杨晓科,杨凌宇,张晶,等.变重量/重心飞机建模及姿态控制律设计[J].北京航空航天大学学报,2011,37(1):54-57+62.
[8]李小飞,张梦杰,王文娟,等.变弯度机翼技术发展研究[J].航空科学技术,2020,31(2):12-24.
[9]桑为民,陈年旭.变体飞机的研究进展及其关键技术[J].飞行力学,2009,27(6):5-9.
[10]白鹏,陈钱,徐国武,等.智能可变形飞行器关键技术发展现状及展望[J].空气动力学学报,2019,37(3):426-443.
[11] Olympio K,Gandhi F. Modeling and numerical analyses of skin design concepts[C]. 50th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics,and Materials Conference,17th AIAA/ASME/AHS Adaptive Structures Conference,Palm Springs,California,2009.
[12] Bubert E,Woods B,Kothera C,et al. Design and fabrication of a passive 1-D morphing aircraft skin[J]. Journal of Intelligent Material Systems&Structures,2010,21(17):1699-1717.
[13] Yokozeki T,Sugiura A,Hirano Y. Development of variable camber morphing airfoil using corrugated structure[J]. Journal of Aircraft,2014,51(3):1023-1029.
[14]赵金涛,王帮峰,牟常伟,等.波纹式结构柔性蒙皮拉伸变形与应变研究[J].中国机械工程,2010,21(16):1959-1963.
[15]牟常伟.用于变体机翼的大变形柔性蒙皮构型及性能的初步探究[D].南京:南京航空航天大学,2010.
[16]宁素娟.具有传感和驱动功能的碳纤维柔性蒙皮研究[D].南京:南京航空航天大学,2010.
[17]高飞.面向变体结构的蜂窝结构设计与制造研究[D].大连:大连理工大学,2021.
[18] Gomez J C,Garcia E. Morphing unmanned aerial vehicles[J]. Smart Materials&Structures,2011,20(10):103001-1-103001-16.
[19] Vasista S,Tong L,Wong K C. Realization of morphing wings:A multidisciplinary challenge[J]. Journal of Aircraft,2012,49(1):11-28.
[20] Sofia A Y N,Meguid S A,Tan K T,et al. Shape morphing of aircraft wing:Status and challenges[J]. Materials&Design,2010,31(3):1284-1292.
[21] Reich G, Sanders B. Introduction to morphing aircraft research[J]. Journal of Aircraft, 2015, 44(4):1059-1059.
[22] Bye D R,Programs A D,Force A,et al. Design of a morphing vehicle[C]. 48th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference,Honululu,Hawaii,2007.
[23] Love M H,Zink P S,Stroud R L,et al. Demonstration of morphing technology through ground and wind tunnel tests[C]. 48th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference,Honululu,Hawaii,2007.
[24] Abdulrahim M,Lind R. Using avian morphology to enhance aircraft maneuverability[C]. AIAA Atomospheric Flight Mechanics Conference and Exhibit, Keystone,Colorado,2006.
[25] Bourdin P,Gatto A,Friswell M I. Performing coordinated turns with articulated wing-tips as multi-axis control effectors[J]. Aeronautical Journal, 2010, 114(1151):35-47.
[26] Johnson T, Frecker M, Abdalla M, et al. Nonlinear analysis and optimization of diamond cell morphing wings[J]. Journal of Intelligent Material Systems and Structures,2009,20(7):815-824.
[27] Bharti S,Frecker M,Lesieutre G,et al. Tendon actuated cellular mechanisms for morphing aircraft wing[C].Proceedings of SPIE-The International Society for Optical Engineering,San Diego,California,2007.
[28] Marks C R,Joo J J,Reich G. A reconfigurable wing for biomimetic aircraft[C]. 54th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference,Boston,Massachusetts,2013.
[29] Mattioni F,Weaver P M,Potter K D,et al. The application of thermally induced multistable composites to morphing aircraft structures[C]. Proceedings of SPIEIndustrial and Commercial Applications of Smart Structures Technologies,San Diego,California,2008.
[30] Luca M D, Mintchev S, Heitz G, et al. Bioinspired morphing wings for extended flight envelope and roll control of small drones[J]. Interface Focus,2017,7(1):20160092-1-20160092-11.
[31] Neal D A,Good M G,Johnston C O,et al. Design and wind tunnel analysis of a fully adaptive aircraft configuration[C]. 45th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference, Palm Springs,Califonia,2004.
[32] Muhammad A,Park H C,Hwang D Y,et al. Mimicking unfolding motion of a beetle hind wing[J]. Chinese Science Bulletin,2009,54(14):2416-2424.
[33] Stowers A K, Lentink D. Folding in and out:passive morphing in flapping wings[J]. Bioinspiration&Biomimetics,2015,10(2):025001-1-025001-16.
[34]顾莉莉.仿生变体机翼结构和驱动基础研究[D].南京:南京航空航天大学,2013.
[35]郝银凤.基于仿生学的变体机翼探索研究[D].南京:南京航空航天大学,2012.
[36] Vale J,Leite A,Lau F,et al. Aero-structural optimization and performance evaluation of a morphing wing with variable span and camber[J]. Journal of Intelligent Material Systems&Structures, 2011, 22(10):1057-1073.
[37] Lesieutre G A, Browne J A, Frecker M I. Scaling of performance,weight,and actuation of a 2-D compliant cellular frame structure for a morphing wing[J]. Journal of Intelligent Material Systems&Structures,2011,22(10):979-986.
[38] Wang Q,Chen Y,Tang H. Mechanism design for aircraft morphing wing[C]. 53rd AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference,Honululu,Hawaii,2012.
[39] Ajaj R M,Friswell M I,Bourchak M,et al. Span morphing using the GNATSpar wing[J]. Aerospace Science and Technology,2016,53:38-46.
[40] Santos P,Sousa J,Gamboa P. Variable-span wing development for improved flight performance[J]. Journal of Intelligent Material Systems&Structures, 2017, 28(8):961-978.
[41] Kheong L W,Jacob J D. In flight aspect ratio morphing using inflatable wings[C]. 46th AIAA Aerospace Sciences Meeting and Exhibit,Reno,Nevada,2008.
[42] Blondeau J E,Pines D J. Pneumatic morphing aspect ratio wing[C]. 45th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference,Palm Springs,Califonia,2004.
[43]王臻,杨智春,崔高伟,等.变后掠伸缩变体机翼的受控运动[J].机械科学与技术,2010,29(10):1314-1319.
[44]雷娟棉,王贤勇,黄灿,等.变形翼机构:CN,CN102673774 B[P],2012.
[45]李智,董二宝,许旻,等.伸缩翼变形机构设计与实验研究[J].机械与电子,2013(7):65-68.
[46] Zhao Y,Hu H. Parameterized aeroelastic modeling and flutter analysis for a folding wing[J]. Journal of Sound&Vibration,2012,331(2):308-324.
[47] Jung Y Y, Kim J H. Unsteady subsonic aerodynamic characteristics of wing in fold motion[J]. Information Theory IEEE Transactions on, 2011, 12(1):412-417.
[48]吴健,昂海松.可折叠翼变形飞行器气动特性研究[J].航空科学技术,2010(2):25-28.
[49]郭秋亭,张来平,常兴华,等.变形飞机动态气动特性数值模拟研究[J].空气动力学学报,2011,29(6):744-750.
[50] Hartloper C,Kinzel M,Rival D E. On the competition between leading-edge and tip-vortex growth for a pitching plate[J]. Experiments in Fluids,2013,54(1):1447.
[51] Wolf T,Konrath R. Avian wing geometry and kinematics of a free-flying barn owl in flapping flight[J]. Experiments in Fluids,2015,56(2):28
[52] Verstraete M L,Preidikman S,Roccia B A,et al. A numerical model to study the nonlinear and usteady aerodynamics of bioinspired morphing-wing concepts[J]. International Journal of Micro Air Vehicles, 2015, 7(3):327-345.
[53] Obradovic B,Subbarao K. Modeling of dynamic loading of morphing wing aircraft[J]. Journal of Aircraft,2011,48(2):424-435.
[54] Moller A. P,Swaddler J P. Asymmetry,developmental stability, and evolution[M]. Oxford University Press,Oxford,1997.
[55] Rosén M, Hedenstrom A. Gliding flight in a jackdaw:A wind tunnel study[J]. Journal of Experimental Biology,2001,204(6):1153-1166.
[56] Lentink D. How swifts control their glide performance with morphing wings[J]. Nature,2007,446(7139):1082-1085.
[57] Han H, Hu J, Yong Y. Investigation of the unsteady aerodynamic characteristics of an unmanned aerial vehicle with variable-sweep morphing[C]. 32nd AIAA Applied Aerodynamics Conference, Atlanta, Georgia,2004.
[58]刘玉荣.家燕羽毛表面结构与翅翼翼型气动特性研究[D].长春:吉林大学,2012.
[59]华欣.海鸥翅翼气动性能研究及其在风力机仿生叶片设计中的应用[D].长春:吉林大学,2013.
[60]徐成宇,钱志辉,刘庆萍.基于长耳鸮翼前缘的仿生耦合翼型气动性能[J].吉林大学学报工学版,2010,40(1):108-110.
[61]蔡常睿.基于信鸽翅膀的仿生机翼气动性能研究[D].长春:吉林大学,2018.
[62] Snyder M P,Sanders B,Eastep F E,et al. Vibration and flutter characteristics of a folding wing[J]. Journal of Aircraft,2009,46(3):791-799.
[63] Wang I,Gibbs S C,Dowell E H. Aeroelastic model of multisegmented folding wings:Theory and experiment[J]. Journal of Aircraft,2012,49(3):911-921.
[64] Lee D H,Weisshaar T A. Aeroelastic studies on a folding wing configuration[C]. 46th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference,Austin,Texas,2005.
[65] Lee D H,Chen P C. Nonlinear aeroelastic studies on a folding wing configuration with free play hinge nonlinearity[C]. 47th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference, Newport,Rhode Island,2006.
[66] Attar P,Tang D,Dowell E H.. Nonlinear aeroelastic study for folding wing structures[J]. AIAA Journal,2010,48(10):2187-2195.
[67] Reich G W,Bowman J C,Sanders B,et al. Development of an integrated aeroelastic multibody morphing simulation tool[C]. 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference,Newport,Rhode Island,2006.
[68] Grant D T,Abdulrahim M,Lind R. Flight dynamics of a morphing aircraft utilizing independent multiple-joint wing sweep[C]. AIAA Atomospheric Flight Mechanics Conference and Exhibit,Keystone,Colorado,2006.
[69]展京霞,王晋军.机翼掠角非对称变化的横航向效应[J].中国科学(E辑:技术科学),2009,39(7):1281-1283.
[70]展京霞,王晋军.仿雨燕机翼柔性对纵向气动特性的影响[J].实验流体力学,2010,24(2):1-4.
[71]郭翔鹰,陈璐璐,张伟. Z型折叠机翼的气动力计算及非线性动力学分析[J].动力学与控制学报,2018,16(5):430-439.
[72]金鼎,张炜,艾俊强.折叠机翼变体飞机纵向操纵性与稳定性研究[J].飞行力学,2011,29(1):5-8+12.
[73] Yue T,Wang L X,Ai J Q. Longitudinal linear parameter varying modeling and simulation of morphing aircraft[J]. Journal of Aircraft,2013,50(6):1673-1681.
[74] Yue T,Wang L X,Ai J Q,et al. Gain self-scheduled H∞control for morphing aircraft in the wing transition process based on an LPV model[J]. Chinese Journal of Aeronautics,2013(4):909-917.
[75] Grant D T,Chakravarthy A,Lind R. Modal interpretation of time-varying eigenvectors of morphing aircraft[C]. AIAA Atmospheric Flight Mechanics Conference,Chicago,Illinois,2009.
[76] Chakravarthy A. Time-varying dynamics of a micro air vehicle with variable-sweep morphing[J]. Journal of Guidance Control&Dynamics,2012,35(3):890-903.
[77] Chakravarthy A,Paranjape A,Chung S J. Control law design for perching an agile MAV with articulated wings[C]. AIAA Atmospheric Flight Mechanics Conference,Toronto,Ontario Canada,2010.
[78] Wright K,Lind R. Sensor emplacement on vertical surfaces with biologically inspired morphing from bats[J].Journal of Aircraft,2015,46(4):1450-1454.
[79]张杰,吴森堂.一种变体飞行器的动力学建模与动态特性分析[J].北京航空航天大学学报,2015,41(1):58-64.
[80]许来斌,杨树兴,陈军,等. M型机翼变体飞机动力学分析[J].北京理工大学学报,2013, 33(2):127-132.
[81] Seigler T M,Neal D A,Bae J S,et al. Modeling and flight control of large-scale morphing aircraft[J]. Journal of Aircraft,2012,44(4):1077-1087.
[82] Koch T S. Stability and control of a morphing vehicle[D]. Seattle:University of Washington,2012.
[83] Baldelli D H,Lee D H,Pena RS S,et al. Modeling and control of an aeroelastic morphing vehicle[J]. Journal of Guidance Control&Dynamics,2008,31(6):1687-1699.
[84]徐孝武,张炜.折叠机翼变体飞机的动力学建模与分析[J].西北工业大学学报,2012,30(5):681-688.
[85]徐孝武,张炜,詹浩.折叠机翼变体飞机非对称变形控制效率分析[J].航空工程进展,2018,9(2):223-229.
[86]颜凯.变体飞机的动力学建模仿真及控制律设计[D].南京:南京航空航天大学,2013.
[87]刘玮,陆宇平,殷明.折叠翼飞行器气动建模及变形稳定控制律设计[J].电子设计工程,2014,22(8):1-4.
[88] Paranjape A A,Chung S J,Selig M S. Flight mechanics of a tailless articulated wing aircraft[J]. Bioinspiration&Biomimetics,2011,6(2):1-20.
[89] Abdulrahim M. Maneuvering control and configuration adaptation of a biologically inspired morphing aircraft[D]. Gainesville:University of Florida,2007.
[90]杨贯通.变外形飞行器建模与控制方法研究[D].北京:北京理工大学,2015.
[91]童磊.不对称变后掠翼飞行器多刚体建模与飞行控制[D].合肥:中国科学技术大学,2013.
Basic Information:
DOI:10.16358/j.issn.1009-1300.20230121
China Classification Code:V271.4
Citation Information:
[1]Ma Hang,Song Bifeng,Zhou Zhongbin ,et al.Analysis of development status of multi-section morphing wing technology[J].Tactical Missile Technology,2024,No.223(01):75-84+112.DOI:10.16358/j.issn.1009-1300.20230121.
2024-02-08
2024-02-08
2024-02-08