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轻巧-承力-功能一体化超结构:概念、设计及应用

康瑞 李雪 孟晗 高金翎 邓健 姜永烽 林国兴 卢天健

康瑞, 李雪, 孟晗, 高金翎, 邓健, 姜永烽, 林国兴, 卢天健. 轻巧-承力-功能一体化超结构:概念、设计及应用[J]. 应用数学和力学, 2024, 45(8): 949-973. doi: 10.21656/1000-0887.450196
引用本文: 康瑞, 李雪, 孟晗, 高金翎, 邓健, 姜永烽, 林国兴, 卢天健. 轻巧-承力-功能一体化超结构:概念、设计及应用[J]. 应用数学和力学, 2024, 45(8): 949-973. doi: 10.21656/1000-0887.450196
KANG Rui, LI Xue, MENG Han, GAO Jinling, DENG Jian, JIANG Yongfeng, LIN Guoxing, LU Tianjian. Ultralight, Compact, and Load-Bearing Multifunctional Metastructures: Concept, Design and Applications[J]. Applied Mathematics and Mechanics, 2024, 45(8): 949-973. doi: 10.21656/1000-0887.450196
Citation: KANG Rui, LI Xue, MENG Han, GAO Jinling, DENG Jian, JIANG Yongfeng, LIN Guoxing, LU Tianjian. Ultralight, Compact, and Load-Bearing Multifunctional Metastructures: Concept, Design and Applications[J]. Applied Mathematics and Mechanics, 2024, 45(8): 949-973. doi: 10.21656/1000-0887.450196

轻巧-承力-功能一体化超结构:概念、设计及应用

doi: 10.21656/1000-0887.450196
(我刊青年编委孟晗、编委卢天健来稿)
基金项目: 

国家自然科学基金 12032010

国家自然科学基金 12202188

国家自然科学基金 52361165626

详细信息
    作者简介:

    康瑞(1994—),男,工程师,博士(E-mail: kangrui0403@163.com)

    通讯作者:

    孟晗(1989—),女,教授,博士,博士生导师(通讯作者. E-mail: menghan@nuaa.edu.cn)

    卢天健(1964—),男,教授,博士,博士生导师(通讯作者. E-mail: tjlu@nuaa.edu.cn)

  • 中图分类号: O34

Ultralight, Compact, and Load-Bearing Multifunctional Metastructures: Concept, Design and Applications

(Contributed by MENG Han, M.AMM Youth Editorial Board & LU Tianjian, M.AMM Editorial Board)
  • 摘要: 高端装备在极端环境下的适应性和机动性是国防安全的核心保障,具有重要战略意义. 提高主承载结构的轻量化水平与功能性,是推动高端装备升级换代的关键环节. 高端装备在多场耦合极端环境下工作,对主承载构件的轻量化和多功能性提出了严苛要求. 现有装备的承力结构与功能(减振降噪、抗弹防爆、冲击吸能、散热隔热、吸波等)分离,造成结构和重量冗余,性能难以提升. 因此,亟需开发轻巧-承力-功能一体化超结构,推进高端装备的升级换代. 该文首次提出轻巧-承力-功能一体化超结构的概念并给出了明确的定义,然后结合实际工程应用需求对多种超结构的设计方案开展综述,最后对超结构未来的发展方向进行了展望.
    1)  (我刊青年编委孟晗、编委卢天健来稿)
  • 图  1  高端装备

    Figure  1.  High-end equipment

    图  2  数学桥与Michael F. Ashby教授

    Figure  2.  The Mathematical Bridge and professor Michael F. Ashby

    图  3  导热系数-热扩散系数Ashby图[14]

       为了解释图中的颜色,读者可以参考本文的电子网页版本,后同.

    Figure  3.  The Ashby selection map of thermal conductivity and thermal diffusivity[14]

    图  4  Anthony G. Evans教授和John W. Hutchinson教授

    Figure  4.  Professor Anthony G. Evans and professor John W. Hutchinson

    图  5  轻巧-承力-功能一体化超结构的研究思路

    Figure  5.  Scientific problems of ultralight, compact, and load-bearing multifunctional metastructures

    图  6  设计阶段的科学问题

    Figure  6.  Scientific issues in design processes

    图  7  制造阶段的科学问题

    Figure  7.  Scientific issues in manufacturing processes

    图  8  评价体系的科学问题

    Figure  8.  Scientific issues in evaluation processes

    图  9  轻质多孔金属夹芯结构的Ashby图[60]

    Figure  9.  The Ashby plot of lightweight porous metallic sandwich structures[60]

    图  10  微穿孔波纹-蜂窝混杂结构示意图

    Figure  10.  Schematic of microperforated corrugated-honeycomb hybrid structure

    图  11  微穿孔波纹-蜂窝混杂芯体超结构(PHCH)与传统微穿孔蜂窝芯体结构(honeycomb) 及波纹未穿孔混杂芯体超结构(HCH)的吸声性能对比

    Figure  11.  Comparison of sound absorption performance between the microperforated corrugated-honeycomb hybrid metastructure (PHCH) and the conventional microperforated honeycomb structure and the hybrid-cored metastructure with microperforated corrugation only (HCH)

    图  12  弹丸以1 700 m/s速度侵彻陶瓷-金字塔金属混杂夹芯结构的过程(有限元模拟)[13]

    Figure  12.  A projectile penetrating into a ceramic prism-filled metallic pyramid hybrid sandwich at 1 700 m/s (finite element simulation)[13]

    图  13  蜂窝夹芯板的侵彻失效模式:面板种类的影响[98]

    Figure  13.  A penetration failure mode of the honeycomb sandwich panel: influence of the face sheet type[98]

    图  14  微波吸收/传输集成夹芯超结构[100]

    Figure  14.  The microwave absorption/transmission integrated sandwich metastructure[100]

    图  15  不同夹芯结构的微波吸收/传输特性对比[100]

    Figure  15.  Comparison of microwave absorption/transmission characteristics among different sandwich structures[100]

    图  16  典型夹芯结构的面外压缩强度Ashby图[100]

    Figure  16.  The Ashby plot of out-of-plane compressive strengths of selected sandwich structures[100]

    图  17  兼具轻巧、承载及电磁波吸收能力的复合材料超结构[101]

    Figure  17.  The ultralight composite honeycomb metastructure for simultaneous load-bearing and electromagnetic wave absorption[101]

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  • 收稿日期:  2024-07-03
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