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Advances and prospects in application of key structural technologies for intelligent ammunition
Received date: 2025-06-03
Revised date: 2025-06-30
Accepted date: 2025-07-23
Online published: 2025-08-11
Supported by
National Key Research and Development Program(2022YFB4602000);National Natural Science Foundation of China(52372346)
Modern warfare is evolving toward “informationization, unmanned operation, multi-domain integration and intelligence.” As a decisive element of precision-strike and high-efficiency firepower systems, intelligent ammunitions have become a key factor in seizing battlefield initiative and ensuring victory. The structural subsystem constitutes the backbone of intelligent ammunitions and the fundamental carrier for lightweight, high-efficiency design. Focusing on a three-tier intelligent architecture of “individual-swarm-system-of-systems,” this paper dissects the latest advances at home and abroad in such critical technologies as lightweight anti-high-overload structures, integrated thermal-protection/load-bearing structures, active control via smart materials, low-cost modularity, and highly reliable dynamic dispensing. Development trends of relevant technologies are reviewed and future directions for key structural technologies of intelligent ammunitions are envisioned, so as to underpin the successful employment of intelligent ammunitions in future cross-domain joint operations and large-scale, cross-platform combat.
Yongli ZHANG , Zhiqi NIU , Lei YU , Junhui MENG , Feng SUN . Advances and prospects in application of key structural technologies for intelligent ammunition[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2026 , 47(4) : 232351 -232351 . DOI: 10.7527/S1000-6893.2025.32351
| [1] | 刘钧圣. 创新引领智能化弹药高水平发展,助力实现建军一百年奋斗目标[J]. 前瞻科技, 2022, 1(4): 5-7. |
| LIU J S. Innovation-driven high-level development of intelligent ammunition, a boost for achieving the goals set for the centenary of the people’s liberation army[J]. Science and Technology Foresight, 2022, 1(4): 5-7 (in Chinese). | |
| [2] | 钱立志. 弹载任务设备抗高过载方法研究[J]. 兵工学报, 2007, 28(8): 1017-1020. |
| QIAN L Z. Study of projectile-loaded equipment against high overload[J]. Acta Armamentarii, 2007, 28(8): 1017-1020 (in Chinese). | |
| [3] | 钱立志. 电视末制导炮弹武器系统关键技术研究[D]. 合肥: 中国科学技术大学, 2006. |
| QIAN L Z. Research on key technologies of TV terminal guided projectile weapon system[D]. Hefei: University of Science and Technology of China, 2006 (in Chinese). | |
| [4] | 宁全利, 蒋滨安, 梁希, 等. 火炮发射环境下弹载光电器件结构动态响应研究[J]. 兵工学报, 2015, 36(11): 2185-2189. |
| NING Q L, JIANG B A, LIANG X, et al. The structural dynamic response of projectile-borne optoelectronic devices during launching[J]. Acta Armamentarii, 2015, 36(11): 2185-2189 (in Chinese). | |
| [5] | 李俊伟, 张丽敏, 朱晓凯. 激光制导炮弹导引头的抗高过载方法研究[J]. 郑州轻工业学院学报(自然科学版), 2014, 29(3): 65-67. |
| LI J W, ZHANG L M, ZHU X K. Study on laser-guided projectile seeker against high overload[J]. Journal of Zhengzhou University of Light Industry (Natural Science Edition), 2014, 29(3): 65-67 (in Chinese). | |
| [6] | 李杰, 刘俊. 制导弹药用微惯性测量单元结构设计[J]. 兵工学报, 2013, 34(6): 711-717. |
| LI J, LIU J. Design of micro-electromechanical systems inertial measurement unit structure for guided ammunition[J]. Acta Armamentarii, 2013, 34(6): 711-717 (in Chinese). | |
| [7] | 惠江海, 高敏, 李鑫鹏. 引信自旋式微电机旋转机架抗高过载结构设计[J]. 北京理工大学学报, 2018, 38(10): 991-999. |
| HUI J H, GAO M, LI X P. Design of structure resisting high overloads for spinning micro-machine’s rotating rack in fuse[J]. Transactions of Beijing Institute of Technology, 2018, 38(10): 991-999 (in Chinese). | |
| [8] | 吴树雄, 蒋学乔, 赵双双, 等. 折叠翼展开机构设计仿真及试验分析[J]. 兵工自动化, 2023, 42(3): 71-76. |
| WU S X, JIANG X Q, ZHAO S S, et al. Design simulation and experimental analysis of folding wing deployment mechanism[J]. Ordnance Industry Automation, 2023, 42(3): 71-76 (in Chinese). | |
| [9] | 王竟, 陈永红. 微型伺服机构折叠弹翼设计和优化[J]. 自动化与仪器仪表, 2020(12): 254-258. |
| WANG J, CHEN Y H. Design a realization of folding wing of micro-servo mechanism against large overload[J]. Automation & Instrumentation, 2020(12): 254-258 (in Chinese). | |
| [10] | 孙栋, 王新杰, 王炅, 等. 旋转型超声电机在冲击环境下的失效模式研究[J]. 振动与冲击, 2018, 37(9): 32-36, 85. |
| SUN D, WANG X J, WANG J, et al. Failure modes for rotary ultrasonic motors under shock environment[J]. Journal of Vibration and Shock, 2018, 37(9): 32-36, 85 (in Chinese). | |
| [11] | 钱立志, 蒋滨安, 宁全利, 等. 弹载器件的过载时间累积效应研究[J]. 振动与冲击, 2017, 36(24): 237-241. |
| QIAN L Z, JIANG B A, NING Q L, et al. Overload time cumulative effect of projectile-based components[J]. Journal of Vibration and Shock, 2017, 36(24): 237-241 (in Chinese). | |
| [12] | 褚伟航, 李孟委, 王宾, 等. 抗过载微陀螺结构的高灵敏设计与仿真[J]. 压电与声光, 2016, 38(5): 833-836. |
| CHU W H, LI M W, WANG B, et al. High-sensitivity design and simulation of a high overload MEMS gyroscope structure[J]. Piezoelectrics & Acoustooptics, 2016, 38(5): 833-836 (in Chinese). | |
| [13] | 钱立志, 李俊, 宁全利. 高过载环境下弹载器件结构动态响应研究[J]. 科技导报, 2011, 29(1): 40-43. |
| QIAN L Z, LI J, NING Q L. Structural dynamical response of projectile-based equipment under high overload[J]. Science & Technology Review, 2011, 29(1): 40-43 (in Chinese). | |
| [14] | BAPANAPALLI S, MARTINEZ O, GOGU C, et al. (student paper) analysis and design of corrugated-core sandwich panels for thermal protection systems of space vehicles[C]∥47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference. Reston: AIAA, 2006. |
| [15] | SEEDHOUSE E. Dragon design, development, and test[M]∥SpaceX’s Dragon: America’s Next Generation Spacecraft. Cham: Springer International Publishing, 2016: 23-44. |
| [16] | 关春龙, 李壵, 赫晓东. 可重复使用热防护系统防热结构及材料的研究现状[J]. 宇航材料工艺, 2003, 33(6): 7-11, 42. |
| GUAN C L, LI Y, HE X D. Research status of structures and materials for reusable TPS[J]. Aerospace Materials & Technology, 2003, 33(6): 7-11, 42 (in Chinese). | |
| [17] | 王一凡. 面向高速飞行器的波纹夹芯型一体化热防护设计及热力耦合分析方法研究[D]. 西安: 西北工业大学, 2017. |
| WANG Y F. Design and thermal-mechanical analysis of corrugated-core integrated thermal protection system for hypersonic vehicle[D]. Xi’an: Northwestern Polytechnical University, 2017 (in Chinese). | |
| [18] | 闪志刚. 复合材料与金属混合的热防护波纹夹芯结构设计[D]. 南京: 南京航空航天大学, 2018. |
| SHAN Z G. The design of thermal protection corrugated sandwich mixed structure of composites and metal[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2018 (in Chinese). | |
| [19] | 徐宁鑫, 许英杰, 张卫红, 等. 陶瓷基复合材料/点阵夹芯薄壁曲率结构热防护系统设计与分析[C]∥2018年全国固体力学学术会议论文集. 北京: 中国复合材料学会, 2018: 111. |
| XU N X, XU Y J, ZHANG W H, et al. Design and analysis of thermal protection system based on ceramic matrix composite/lattice core thin-walled curved structures[C]∥Proceedings of 2018 National Conference on Solid Mechanics. Beijing: Chinese Society for Composite Materials, 2018: 111 (in Chinese). | |
| [20] | 罗晓波, 杨艳静, 杨泽南, 等. 晶格阵列结构与主流高超声速气膜冷却交互作用的数值研究[J]. 航天器环境工程, 2021, 38(2): 115-121. |
| LUO X B, YANG Y J, YANG Z N, et al. Numerical study of the interactions between lattice array structure and mainstream hypersonic film cooling[J]. Spacecraft Environment Engineering, 2021, 38(2): 115-121 (in Chinese). | |
| [21] | 丁晨, 牛智玲, 单亦姣, 等. 多层热防护结构烧蚀传热模型研究[J]. 导弹与航天运载技术, 2021(1): 24-28. |
| DING C, NIU Z L, SHAN Y J, et al. Heat transfer and ablation model for multi-layer thermal protection system[J]. Missiles and Space Vehicles, 2021(1): 24-28 (in Chinese). | |
| [22] | 党勇. 硅橡胶泡沫/芳纶复合织物的制备与热防护性能研究[D]. 天津: 天津理工大学, 2024. |
| DANG Y. The preparation and thermal protection performance study of silicone rubber foam/aramid composite fabric[D]. Tianjin: Tianjin University of Technology, 2024 (in Chinese). | |
| [23] | 张思严. 消防服用蜂窝夹芯结构织物的热防护性能优化研究[D]. 上海: 东华大学, 2019. |
| ZHANG S Y. Study of optimization on thermal protective performance of honeycomb sandwich structure fabrics for firefighter protective clothing[D]. Shanghai: Donghua University, 2019 (in Chinese). | |
| [24] | 胡凯明. 仿生热防护结构选区激光熔化成形及热学/力学性能研究[D]. 南京: 南京航空航天大学, 2020. |
| HU K M. Thermal/mechanical performance analysis of bio-inspired thermal protection structures manufactured by selective laser melting[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2020 (in Chinese). | |
| [25] | FAHRENHOLTZ W G, HILMAS G E. Ultra-high temperature ceramics: Materials for extreme environments[J]. Scripta Materialia, 2017, 129: 94-99. |
| [26] | FU Q G, ZHANG P, ZHUANG L, et al. Micro/nano multiscale reinforcing strategies toward extreme high-temperature applications: Take carbon/carbon composites and their coatings as the examples[J]. Journal of Materials Science & Technology, 2022, 96: 31-68. |
| [27] | LUO R Y, LIU T, LI J S, et al. Thermophysical properties of carbon/carbon composites and physical mechanism of thermal expansion and thermal conductivity[J]. Carbon, 2004, 42(14): 2887-2895. |
| [28] | NI D W, CHENG Y, ZHANG J P, et al. Advances in ultra-high temperature ceramics, composites, and coatings[J]. Journal of Advanced Ceramics, 2022, 11(1): 1-56. |
| [29] | MUKHERJEE R, BASU B. Opportunities and challenges in processing and fabrication of ultra high temperature ceramics for hypersonic space vehicles: a case study with ZrB2-SiC[J]. Advances in Applied Ceramics, 2018, 117(sup1): s2-s8. |
| [30] | NIETO A, KUMAR A, LAHIRI D, et al. Oxidation behavior of graphene nanoplatelet reinforced tantalum carbide composites in high temperature plasma flow[J]. Carbon, 2014, 67: 398-408. |
| [31] | GUO C, XING Y, WU P, et al. Super tensile ductility in an as-cast TiVNbTa refractory high-entropy alloy[J]. Progress in Natural Science: Materials International, 2024, 34(5): 1076-1084. |
| [32] | PACCHIONI G. Designing ductile refractory high-entropy alloys[J]. Nature Reviews Materials, 2025, 10(1): 763. |
| [33] | SHEN X, SUN B R, XIN S W, et al. Creep in a nanocrystalline VNbMoTaW refractory high-entropy alloy[J]. Journal of Materials Science & Technology, 2024, 187: 221-229. |
| [34] | 蒋园园. 光纤光栅传感器应用于复合材料损伤监测的研究[D]. 武汉: 武汉理工大学, 2012. |
| JIANG Y Y. Damage monitoring of composities using FBG sensors[D]. Wuhan: Wuhan University of Technology, 2012 (in Chinese). | |
| [35] | 姜德生, 何伟. 光纤光栅传感器的应用概况[J]. 光电子·激光, 2002, 13(4): 420-430. |
| JIANG D S, HE W. Review of applications for fiber Bragg grating sensors[J]. Journal of Optoelectronics Laser, 2002, 13(4): 420-430 (in Chinese). | |
| [36] | DERKEVORKIAN A, MASRI S F, ALVARENGA J, et al. Strain-based deformation shape-estimation algorithm for control and monitoring applications[J]. AIAA Journal, 2013, 51(9): 2231-2240. |
| [37] | DI SANTE R. Fibre optic sensors for structural health monitoring of aircraft composite structures: recent advances and applications[J]. Sensors, 2015, 15(8): 18666-18713. |
| [38] | 袁新华, 陈燕秋, 张倩, 等. 自修复微胶囊型环氧树脂复合材料的制备及其性能[J]. 江苏大学材料科学与工程学院, 2017, 38(4): 461-5, 71. |
| YUAN X H, CHEN Y Q, ZHANG Q, et al. Preparation and properties of self-healing microcapsule-type epoxy resin composites[J]. School of Materials Science and Engineering, Jiangsu University, 2017, 38(04): 461-465, 471 (in Chinese). | |
| [39] | 顾海超, 杨涛, 杜宇. 中空纤维型自修复复合材料的修复效率及力学性能[J]. 宇航材料工艺, 2017, 47(4): 75-78. |
| GU H C, YANG T, DU Y. Repair efficiency and mechanical properties of hollow fiber self-healing composite[J]. Aerospace Materials & Technology, 2017, 47(4): 75-78 (in Chinese). | |
| [40] | 刘远. 基于NSGA-Ⅱ的树脂基自修复复合材料中管网载体的拓扑优化及研制[D]. 南昌: 华东交通大学, 2017. |
| LIU Y. Topology optimization and prepare of networks in self-healing composites using NSGA-Ⅱ[D]. Nanchang: East China Jiaotong University, 2017 (in Chinese). | |
| [41] | XU C C, DONG S, MA Y F, et al. Conductive polymer composites-enable self-sensing twisted string actuators[J]. Modern Physics Letters B, 2025, 39(5): 2442002. |
| [42] | XU Z P, LU H T, CHEN Q Y, et al. Additive manufacturing of self-sensing carbon fiber composites[J]. Advanced Engineering Materials, 2025, 27(11): 2301249. |
| [43] | YIN H P, LI Y T, HUANG H. Triggering probability of self-healing mechanisms in microencapsulated self-healing composites[J]. Applied Mathematical Modelling, 2025, 145: 116101. |
| [44] | 郭斐然, 张旭辉, 路鹰, 等. 导弹系统柔性设计技术[J]. 战术导弹技术, 2024(4): 92-102. |
| GUO F R, ZHANG X H, LU Y, et al. Flexible design technology for missile systems[J]. Tactical Missile Technology, 2024(4): 92-102 (in Chinese). | |
| [45] | 刘晶晶, 谢翔, 沈欣, 等. 国外空空导弹派生武器系统发展研究[J].航空兵器, 2019(6): 60-67. |
| LIU J J, XIE X, SHEN X, et al. Research on the development of foreign air-to-air missile derived weapon system[J]. Aero Weaponry, 2019(6): 60-67 (in Chinese). | |
| [46] | 任淼, 刘晶晶, 赵鸿燕, 等. 2015年国外空空导弹发展动态研究[J]. 航空兵器, 2016, 23(2): 9-16. |
| REN M, LIU J J, ZHAO H Y, et al. Research on foreign air-to-air missiles’ development in 2015[J]. Aero Weaponry, 2016, 23(2): 9-16 (in Chinese). | |
| [47] | 刘钧圣, 王刚, 王琨, 等. 考虑不确定性的模块化战术导弹优化设计[J]. 兵工学报, 2020, 41(2): 270-279. |
| LIU J S, WANG G, WANG K, et al. Optimization design of modular tactical missile under uncertainty[J]. Acta Armamentarii, 2020, 41(2): 270-279 (in Chinese). | |
| [48] | MOLAS‐GALLART J. Missile systems: “Flexible modularity” and incremental technological change in military production[J]. Defence and Peace Economics, 1995, 6(2): 141-158. |
| [49] | 黄谋华, 梁宁宁, 谢瑞明, 等. 无人协同作战研究浅谈[J]. 中国军转民, 2024(14): 47-48. |
| HUANG M H, LIANG N N, XIE R M, et al. On the research of unmanned cooperative operations[J]. Defense Industry Conversion in China, 2024(14): 47-48 (in Chinese). | |
| [50] | 朱继宏, 肖和业, 张永励, 等. 智能化弹药结构技术进展及发展建议[J]. 前瞻科技, 2022, 1(4): 55-68. |
| ZHU J H, XIAO H Y, ZHANG Y L, et al. Advances and suggestions on intelligent ammunition structural technology[J]. Science and Technology Foresight, 2022, 1(4): 55-68 (in Chinese). | |
| [51] | MAREK D, BIERNACKI P, SZYGU?A J, et al. Collision avoidance mechanism for swarms of drones[J]. Sensors, 2025, 25(4): 1141. |
| [52] | R K S M. The nature of Russia’s threat to NATO’s enhanced forward presence in the Baltic States[D]. Monterrey:Naval Postgraduate School, 2017. |
| [53] | 贾高伟, 侯中喜. 美军无人机集群项目发展[J]. 国防科技, 2017, 38(4): 53-56. |
| JIA G W, HOU Z X. The analysis and enlightenment about the UAV swarming project of the United States Military[J]. National Defense Science & Technology, 2017, 38(4): 53-56 (in Chinese). | |
| [54] | 王瑞杰, 王得朝, 丰璐, 等. 国外无人机蜂群作战样式进展及反蜂群策略研究[J]. 现代防御技术, 2023, 51(4): 1-9. |
| WANG R J, WANG D C, FENG L, et al. Research progress and countermeasures against UAV swarm operations abroad[J]. Modern Defence Technology, 2023, 51(4): 1-9 (in Chinese). | |
| [55] | 孙海文, 于邵祯, 周末, 等. 反无人机蜂群作战指挥控制系统[J]. 指挥控制与仿真, 2023, 45(2): 31-37. |
| SUN H W, YU S Z, ZHOU M, et al. Anti-UAV bee colony combat command and control system[J]. Command Control & Simulation, 2023, 45(2): 31-37 (in Chinese). | |
| [56] | LIU H, ZHOU J, MO Z L, et al. A novel variable topology design for a multi-flexible ejection mechanism[J]. Defence Technology, 2020, 16(2): 432-438. |
| [57] | 宋威, 艾邦成. 多体分离动力学研究进展[J]. 航空学报, 2022, 43(9): 025950. |
| SONG W, AI B C. Multibody separation dynamics: Review[J]. Acta Aeronautica et Astronautica Sinica, 2022, 43(9): 025950 (in Chinese). | |
| [58] | SONG W, DONG J G, LU W, et al. Trajectory and attitude deviations for internal store separation due to unsteady and quasi-steady test method[J]. Chinese Journal of Aeronautics, 2022, 35(2): 74-81. |
| [59] | 赵军民, 任海鹏. 智能弹药集群网链[J]. 前瞻科技, 2022, 1(4): 8-17. |
| ZHAO J M, REN H P. Internet of intelligent missiles[J]. Science and Technology Foresight, 2022, 1(4): 8-17 (in Chinese). | |
| [60] | 贺友龙, 郝汀, 梁洪灿, 等. 超宽带弹载共形天线设计[J]. 舰船电子对抗, 2020, 43(3): 89-92. |
| HE Y L, HAO T, LIANG H C, et al. Design of UWB missile-borne conformal antenna[J]. Shipboard Electronic Countermeasure, 2020, 43(3): 89-92 (in Chinese). | |
| [61] | 李得东. 若干小型化宽带共形天线设计[D]. 西安: 西安电子科技大学, 2018. |
| LI D D. Some miniaturized broadband conformal antennas design[D]. Xi’an: Xidian University, 2018 (in Chinese). | |
| [62] | 史则颖, 叶冬, 彭子寒, 等. 飞行器共形天线新型制造工艺及应用研究进展[J]. 航空学报, 2021, 42(10): 524812. |
| SHI Z Y, YE D, PENG Z H, et al. Research progress on novel manufacturing approaches of conformal antenna for aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2021, 42(10): 524812 (in Chinese). | |
| [63] | 胡志慧, 姜永华, 凌祥, 等. 共形天线技术及其在导引头中的应用[J]. 飞航导弹, 2012(11): 77-81. |
| HU Z H, JIANG Y H, LING X, et al. Conformal antenna technology and its application in seeker[J]. Aerodynamic Missile Journal, 2012(11): 77-81 (in Chinese). | |
| [64] | 朱继宏, 韩嘉诚, 谷小军, 等. 跨域飞行器结构与变构型设计技术进展与挑战[J]. 航空学报, 2025, 46(18): 275-306. |
| ZHU J H, HAN J C, GU X J, et al. Advances and challenges in cross-domain vehicle structures and morphing configuration design technologies[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(18): 275-306 (in Chinese). | |
| [65] | CASTRICHINI A, SIDDARAMAIAH V H, CALDERON D E, et al. Preliminary investigation of use of flexible folding wing tips for static and dynamic load alleviation[J]. The Aeronautical Journal, 2017, 121(1235): 73-94. |
| [66] | DUSSART G X, YUSUF S Y, LONE M M. Effect of wingtip morphing on the roll mode of a flexible aircraft[C]∥2018 AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference. Reston: AIAA, 2018: 1683. |
| [67] | 聂瑞. 变体机翼结构关键技术研究[D]. 南京: 南京航空航天大学, 2018. |
| NIE R. Research on key technologies of morphing wing structures[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2018 (in Chinese). | |
| [68] | 刘瑜, 吕凡熹, 周进. XB-70飞行器折叠机翼总体性能分析[J]. 航空科学技术, 2022, 33(12): 47-53. |
| LIU Y, LYU F X, ZHOU J. Overall performance analysis on XB-70 folding wingtip system[J]. Aeronautical Science & Technology, 2022, 33(12): 47-53 (in Chinese). | |
| [69] | KUEHME D, ALLEY N R, PHILLIPS C, et al. Flight test evaluation and system identification of the area-I prototype-technology-evaluation research aircraft (PTERA)[C]∥AIAA Flight Testing Conference. Reston, AIAA, 2014: 2577. |
| [70] | 刘箴, 吴馨远, 许洁心. 国外巡飞弹发展现状及趋势分析[J]. 弹箭与制导学报, 2024, 44(2): 42-50. |
| LIU Z, WU X Y, XU J X. Development status and trend for foreign typical loitering munitions[J]. Journal of Projectiles, Rockets, Missiles and Guidance, 2024, 44(2): 42-50 (in Chinese). | |
| [71] | 刘文法, 王旭, 米康. 一种新的变前掠翼无人机气动布局[J]. 航空学报, 2009, 30(5): 832-836. |
| LIU W F, WANG X, MI K. A new aerodynamic configuration of UAV with variable forward-swept wing[J]. Acta Aeronautica et Astronautica Sinica, 2009, 30(5): 832-836 (in Chinese). | |
| [72] | MOOSAVIAN A, XI F F, HASHEMI S M. Design and motion control of fully variable morphing wings[J]. Journal of Aircraft, 2013, 50(4): 1189-1201. |
| [73] | MORTON D, XU A, MATUTE A, et al. Autonomous material composite morphing wing[J]. Journal of Composite Materials, 2023, 57(4): 711-720. |
| [74] | CHU L L, LI Q, GU F, et al. Design, modeling, and control of morphing aircraft: A review[J]. Chinese Journal of Aeronautics, 2022, 35(5): 220-246. |
| [75] | GUO X Y, WANG Z, LU K, et al. Design and aerodynamic analysis of a morphing joined-wing aircraft with transonic flight capability[J]. Aerospace Science and Technology, 2025, 159: 109966. |
| [76] | ZHOU X H, HUANG R, YU S J, et al. High-Efficient parametric aeroelastic modeling and experimental validation for a morphing aircraft testbed[J]. Mechanical Systems and Signal Processing, 2025, 230: 112635. |
| [77] | 邢丽英, 张佐光. 结构隐身复合材料的发展与展望[J]. 材料工程, 2002, 30(4): 48-51. |
| XING L Y, ZHANG Z G. The development of structural absorbing composites[J]. Journal of Materials Engineering, 2002, 30(4): 48-51 (in Chinese). | |
| [78] | 邢丽英, 蒋诗才, 李斌太. 含电路模拟结构吸波复合材料[J]. 复合材料学报, 2004, 21(6): 27-33. |
| XING L Y, JIANG S C, LI B T. Microwave absorbing composite with circuit analogue[J]. Acta Materiae Compositae Sinica, 2004, 21(6): 27-33 (in Chinese). | |
| [79] | 侯智芸, 张武昆, 赵丽滨. 飞行器多功能结构应用研究进展和展望[C]∥第十七届北方七省市区力学学会学术会议. 北京: 中国力学学会, 2018: 51-57. |
| HOU Z Y, ZHANG W K, ZHAO L B. Research progress and prospects on multifunctional structures for aircraft[C]∥Proceedings of the 17th Academic Conference of Mechanics Societies of 17th Northern Provinces and Cities. Beijing: Chinese Society of theoretical and Applied Mechanics, 2018: 51-57 (in Chinese). | |
| [80] | LONG G, DUAN J Y, ZHOU S T, et al. Femtosecond laser processing for multi-functional hierarchical micro/nano structures on curved surfaces[J]. Applied Surface Science, 2025, 684: 161850. |
| [81] | TANG Z L, GAO M H, LI H D, et al. Facile and effective construction of superhydrophobic, multi-functional and durable coatings on steel structure[J]. Composites Part B: Engineering, 2024, 287: 111850. |
| [82] | YE C M, CHENG Y, YE M X, et al. All-in-One layer-structured multi-functional conductive polypyrrole coated polyimide aerogel[J]. Composites Part B: Engineering, 2025, 295: 112201. |
| [83] | HAASE C, TANG F, WILMS M B, et al. Combining thermodynamic modeling and 3D printing of elemental powder blends for high-throughput investigation of high-entropy alloys–Towards rapid alloy screening and design[J]. Materials Science and Engineering: A, 2017, 688: 180-189. |
| [84] | ZHU Z G, NGUYEN Q B, NG F L, et al. Hierarchical microstructure and strengthening mechanisms of a CoCrFeNiMn high entropy alloy additively manufactured by selective laser melting[J]. Scripta Materialia, 2018, 154: 20-24. |
| [85] | 李青宇, 张航, 李涤尘, 等. 激光增材制造WNbMoTa高性能高熵合金[J]. 机械工程学报, 2019, 55(15): 10-16. |
| LI Q Y, ZHANG H, LI D C, et al. Manufacture of WNbMoTa high performance high-entropy alloy by laser additive manufacturing[J]. Journal of Mechanical Engineering, 2019, 55(15): 10-16 (in Chinese). | |
| [86] | 付国太, 刘洪军, 张柏, 等. PEEK的特性及应用[J]. 2006(10): 69-71. |
| FU G T, LIU H J, ZHANG B, et al. Characteristics and application of PEEK[J]. Engineering Plastics Application, 2006(10): 69-71 (in Chinese). | |
| [87] | DENAULT J, DUMOUCHEL M. Consolidation process of PEEK/carbon composite for aerospace applications[J]. Advanced Performance Materials, 1998, 5(1): 83-96. |
| [88] | 张辉, 方良超, 陈奇海, 等. 聚醚醚酮在航空航天领域的应用[J]. 新技术新工艺, 2018(10): 5-8. |
| ZHANG H, FANG L C, CHEN Q H, et al. Application of PEEK in aerospace industry[J]. New Technology & New Process, 2018(10): 5-8 (in Chinese). | |
| [89] | HU Q X, DUAN Y C, ZHANG H G, et al. Manufacturing and 3D printing of continuous carbon fiber prepreg filament[J]. Journal of Materials Science, 2018, 53(3): 1887-1898. |
| [90] | YANG C C, TIAN X Y, LIU T F, et al. 3D printing for continuous fiber reinforced thermoplastic composites: Mechanism and performance[J]. Rapid Prototyping Journal, 2017, 23(1): 209-215. |
| [91] | UM H J, LEE J S, SHIN J H, et al. 3D printed continuous carbon fiber reinforced thermoplastic composite sandwich structure with corrugated core for high stiffness/load capability[J]. Composite Structures, 2022, 291: 115590. |
| [92] | 刘博宇, 王向明, 杨光, 等. 面向金属增材制造的拓扑优化设计研究进展[J]. 中国激光, 2023, 50(12): 1202301. |
| LIU B Y, WANG X M, YANG G, et al. Research progress on topology optimization design for metal additive manufacturing[J]. Chinese Journal of Lasers, 2023, 50(12): 1202301 (in Chinese). | |
| [93] | JIA Y B, MENG W, DU Z L, et al. Explicit design optimization of air rudders for maximizing stiffness and fundamental frequency[J]. Thin-Walled Structures, 2024, 203: 112152. |
| [94] | ZHANG W S, ZHUANG X Y, GUO X, et al. Human-augmented topology optimization design with multi-framework intervention[J]. Engineering with Computers, 2025, 41(4): 2359-2376. |
| [95] | SONG N N, PENG H J, GUO X. Sym-ML: a symplectic machine learning framework for stable dynamic prediction of mechanical system[J]. Mechanism and Machine Theory, 2025, 206: 105934. |
| [96] | LI Z H, ZHANG D Z, DONG P, et al. A lightweight and support-free design method for selective laser melting[J]. The International Journal of Advanced Manufacturing Technology, 2017, 90(9): 2943-2953. |
| [97] | 韦伟. 考虑颤振特性的导弹舵面轻质夹芯混杂构型拓扑优化设计[D]. 武汉: 华中科技大学, 2022. |
| WEI W. Topology optimization design of lightweight missile rudder hybrid core structures considering flutter characteristics[D]. Wuhan: Huazhong University of Science and Technology, 2022 (in Chinese). | |
| [98] | 郭伟超, 李辉, 李丙震, 等. 热力耦合情况下的导弹导引头多尺度并行拓扑优化设计方法[J]. 航空动力学报, 2024, 39(5): 20220359. |
| GUO W C, LI H, LI B Z, et al. Multi-scale parallel topology optimization design method for missile seeker with thermo-dynamic coupling loads[J]. Journal of Aerospace Power, 2024, 39(5): 20220359 (in Chinese). |
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