|
|
- 2018
天然和仿生柔性生物结构的设计
|
Abstract:
自然界中生物材料表现出的力学性能与其结构设计形式紧密相关。柔性生物材料多为多级结构设计,其独特的功能梯度特征使其具备优异的变形能力及良好的断裂韧性。本文借鉴工程结构设计基本单元的思想提出柔性结构仿生元素理念,根据几何形态将结构仿生元素分为:线元素、梁元素、柱元素、板壳元素、薄膜元素及组合元素。根据系统论的观点建立仿生柔性结构设计体系,归纳总结出柔性仿生结构的设计准则,并基于鱼鳞梯度结构设计新型仿生功能梯度板。通过有限元的方法对功能梯度板归一化自然频率进行分析。结果表明,类鱼鳞功能梯度板具有柔韧性及刚度软化特性。阐述了仿生柔性结构的设计方法,包括模仿设计、组合设计及选择匹配设计。 The mechanical properties of biomaterials are closely related to their structural design in nature. The flexible biological materials mostly are designed as hierarchical structure that has the unique feature of gradient, which makes the materials have good deformation capacity as well as toughness. In this paper, the concept of bioinspired flexible structural elements was put forward that based on the basic elements of engineering structural design. The bionic elements were divided into line elements, beam elements, column elements, plate and shell elements, thin film elements and composite elements according to the geometrical morphology. The design system of bioinspired flexible structure was developed from the point of view of system theory. The design criterion of flexible bionic structure was summarized. A novel bionic functionally gradient plate was design based on the gradient structure of fish scale. The normalized-dimensionless natural frequencies of functionally graded plate were computed by the finite element method, the results show that the functionally graded plate, inspired by the structure of fish scale, has the characteristics of flexibility and stiffness softening. Finally, the natural function of flexible biomimetic methods is discussed in detail, including imitation design, combinatorial design and matching design. 装备预研教育部联合基金(青年人才)项目(6141A02033602);国防科技创新特区项目(7-H863-03-ZT-003-008-06);湖南省重点研发计划项目(2017GK2130)
| [1] | BROWNING A A R. Mechanics and design of flexible composite fish armor[D]. Massachusetts:Massachusetts Institute of Technology, 2012. |
| [2] | SONG J. Multiscale materials design of natural exoskeletons:Fish armor[D]. Massachusetts:Massachusetts Institute of Technology, 2011. |
| [3] | DURO R J, ZOLOTOVSKY K, MOGAS S L, et al. MetaMesh:A hierarchical computational model for design and fabrication of biomimetic armored surfaces[J]. Computer-Aided Design, 2015, 60:14-27. |
| [4] | 吴宇怀. 3D打印:三维智能数字化创造[M]. 北京:电子工业出版社, 2014. WU Yuhuai. 3D printing:Three-dimensional creation via intelligent digitization[M]. Beijing:Publishing House of Electronics Industry, 2014(in Chinese). |
| [5] | PABLO R M. Natural organic fiber meshes as reinforcements in cement-mortar matrix[J]. International Journal of Engineering Research & Innovation, 2011, 3(2):14-19. |
| [6] | ZHANG J, RAJKHOWA R, LI J L, et al. Silkworm cocoon as natural material and structure for thermal insulation[J]. Materials & Design, 2013, 49(49):842-849. |
| [7] | GERBODE S J, PUZEY J R, MCCORMICK A G, et al. How the cucumber tendril coils and overwinds[J]. Science, 2012, 337(6098):1087-1091. |
| [8] | 杨瑞珍. Glubam材料的性能研究与应用[D]. 长沙:湖南大学, 2013. YANG Ruizhen. Research on material properties of glubam and its application[D]. Changsha:Hu'nan University, 2013(in Chinese). |
| [9] | 章静波. 细胞生物学[J]. 中华医学杂志, 1998, 82(12):1722-1724. ZHANG Jingbo. Cell biology[J]. National Medical Journal of China, 1998, 82(12):1722-1724(in Chinese). |
| [10] | LI Q, ZENG Q, SHI L, et al. Bio-inspired sensors based on photonic structures of morpho butterfly wings:A review[J]. Journal of Materials Chemistry C, 2016, 4(9):1752-1763. |
| [11] | CAO C, FENG Y, ZANG J, et al. Tunable lotus-leaf and rose-petal effects via graphene paper origami[J]. Extreme Mechanics Letters, 2015, 4:18-25. |
| [12] | MITCHELL F L, LASSWELL J. A dazzle of dragonflies[M]. Texas:A & M University Press, 2005. |
| [13] | ARMON S, EFRATI E, KUPFERMAN R, et al. Geometry and mechanics in the opening of chiral seed pods[J]. Science, 2011, 333(6050):1726-1730. |
| [14] | KESAVRAMAN S. Studies on metakaolin based banana fiber reinforced concrete[J]. International Journal of Civil Engineering and Technology (IJCIET) 2017, 8(1):532-543. |
| [15] | REICHERT S, MENGES A, CORREA D. Meteorosensitive architecture:Biomimetic building skins based on materially embedded and hygroscopically enabled responsiveness[J]. Computer-Aided Design, 2015, 60:50-69. |
| [16] | MARTINEZ R V, FISH C R, CHEN X, et al. Elastomeric origami:Programmable paper-elastomer composites as pneumatic actuators[J]. Advanced Functional Materials, 2012, 22(7):1376-1384. |
| [17] | YU T, BUI T Q, LIU P, et al. A stabilized discrete shear gap extended finite element for the analysis of cracked Reissner-Mindlin plate vibration problems involving distorted meshes[J]. International Journal of Mechanics and Materials in Design, 2016, 12(1):85-107. |
| [18] | YANG W, SHERMAN V R, GLUDOVATZ B, et al. Protective role of Arapaima gigas fish scales:Structure and mechanical behavior[J]. Acta Biomaterialia, 2014, 10(8):3599-3614. |
| [19] | YANG W, CHEN I H, GLUDOVATZ B, et al. Natural flexible dermal armor[J]. Advanced Materials, 2013, 25(1):31-48. |
| [20] | WANG B, YANG W, SHERMAN V R, et al. Pangolin armor:Overlapping, structure, and mechanical properties of the keratinous scales[J]. Acta Biomaterialia, 2016, 41:60-74. |
| [21] | PORTER M M, ADRIAENS D, HATTON R L, et al. Why the seahorse tail is square[J]. Science, 2015, 349(6243):aaa6683, 1-7. |
| [22] | TAN T, RAHBAR N, ALLAMEH S, et al. Mechanical properties of functionally graded hierarchical bamboo structures[J]. Acta Biomaterialia, 2011, 7(10):3796-3803. |
| [23] | ZOLOTOVSKY K. BioConstructs:Methods for bio-inspired and bio-fabricated design[D]. Massachusetts:Massachusetts Institute of Technology, 2012. |
| [24] | HABIBI M K, SAMAEI A T, GHESHLAGHI B, et al. Asymmetric flexural behavior from bamboo's functionally graded hierarchical structure:Underlying mechanisms[J]. Acta Biomaterialia, 2015, 16:178-186. |
| [25] | XIAO Y, SHAN B, YANG R Z, et al. Glue laminated bamboo (glubam) for structural applications[M]. Netherlands:Springer, 2014. |
| [26] | 刘鹏, 汪俊文, 朱德举. 草鱼鳞片的多级结构及力学性能[J]. 复合材料学报, 2016, 33(3):657-665. LIU Peng, WANG Junwen, ZHU Deju. Hierarchical structure and mechanical properties of scales from grass carp[J]. Acta Materiae Compositae Sinica, 2016, 33(3):657-665(in Chinese). |
| [27] | 任露泉, 梁云虹. 耦合仿生学[M]. 北京:科学出版社, 2012. REN Luquan, LIANG Yunhong. Coupling bionics[M]. Beijing:Science Press, 2012(in Chinese). |
| [28] | STUDART A R, ERB R M. Bioinspired materials that self-shape through programmed microstructures[J]. Soft Matter, 2014, 10(9):1284-1294. |
| [29] | LIU P, BUI T Q, ZHU D, et al. Buckling failure analysis of cracked functionally graded plates by a stabilized discrete shear gap extended 3-node triangular plate element[J]. Composites Part B:Engineering, 2015, 77(1):179-193. |
| [30] | 陈斌, 彭向和, 范镜泓. 生物自然复合材料的结构特征及仿生复合材料的研究[J]. 复合材料学报, 2000, 17(3):59-62. CHEN Bin, PENG Xianghe, FAN Jinghong. Microstructure of natural biocomposites and research of biomimetic compo-sites[J]. Acta Materiae Compositae Sinica, 2000, 17(3):59-62(in Chinese). |
| [31] | MEYERS M A, MCKITTRICK J, CHEN P Y. Structural biological materials:Critical mechanics-materials connections[J]. Science, 2013, 339(6121):773-779. |
| [32] | GOEL A K, MCADAMS D A, STONE R B. Biologically inspired design:Computational methods and tools[M]. Germany:Springer Science & Business Media, 2013. |
| [33] | VINCENT J F, BOGATYREVA O A, BOGATYREV N R, et al. Biomimetics:Its practice and theory[J]. Journal of the Royal Society Interface, 2006, 3(9):471-482. |
| [34] | CHAKRABARTI A, SARKAR P, LEELAVATHAMMA B, et al. A functional representation for aiding biomimetic and artificial inspiration of new ideas[J]. AIE EDAM, 2005, 19(2):113-132. |
| [35] | CRANFORD S W. Increasing silk fibre strength through heterogeneity of bundled fibrils[J]. Journal of the Royal Society Interface, 2013, 10(82):20130148. |
| [36] | MURCIA S, MCCONVILLE M, LI G, et al. Temperature effects on the fracture resistance of scales from Cyprinus carpio[J]. Acta Biomaterialia, 2015, 14:154-163. |
| [37] | 李秀娟. 蜻蜓翅膀功能特性力学机制的仿生研究[D]. 吉林:吉林大学, 2013. LI Xiujuan. Bionic research on the mechanical mechanism of the functional characteristics of dragonfly wings[D]. Jilin:Jilin University, 2013(in Chinese). |
| [38] | ALLEN R D. Mechanism of the seismonastic reaction in mimosa pudica[J]. Plant Physiology, 1969, 44(8):1101-1107. |
| [39] | FILHO R D T, GHAVAMI K, SANJUáN M A, et al. Free, restrained and drying shrinkage of cement mortar composites reinforced with vegetable fibres[J]. Cement & Concrete Composites, 2005, 27(5):537-546. |
| [40] | WEN L, WEAVER J C, LAUDER G V. Biomimetic shark skin:Design, fabrication and hydrodynamic function[J]. The Journal of Experimental Biology, 2014, 217(10):1656-1666. |
| [41] | DU J, NIU X, RAHBAR N, et al. Bio-inspired dental multilayers:Effects of layer architecture on the contact-induced deformation[J]. Acta Biomaterialia, 2013, 9(2):5273-5279. |
| [42] | BRUET B J F, SONG J, BOYCE M C, et al. Materials design principles of ancient fish armour[J]. Nature Materials, 2008, 7(9):748. |
| [43] | ZHU D, ORTEGA C F, MOTAMEDI R, et al. Structure and mechanical performance of a "modern" fish scale[J]. Advanced Engineering Materials, 2012, 14(4):B185-B194. |
| [44] | HUANG M, WANG R, THOMPSON V, et al. Bioinspired design of dental multilayers[J]. Journal of Materials Science:Materials in Medicine, 2007, 18(1):57-64. |
| [45] | Database of information for the online biomimicry community[EB/OL].[2017/06/21]. http://www.asknature.org/. |
| [46] | Design analogy to nature engine[EB/OL].[2017/06/21]. http://dilab.cc.gatech.edu/dane/. |
| [47] | TORGAL F P, JALALI S. Vegetable fibre reinforced concrete composites:A review[J]. Construction & Building Materials, 2011, 25(2):575-581. |
| [48] | GOSLINE J, GUERETTE P, ORTLEPP C, et al. The mechanical design of spider silks:From fibroin sequence to mechanical function[J]. Journal of Experimental Biology, 1999, 202(23):3295-3303. |
| [49] | JEAN-MARC Sheitoyan. Flotspotting:Biomimetic personal equipment[EB/OL].[2017/06/21]. http://www.core77.com/posts/23748/flotspotting-biomimetic-personal-equipment-by-jean-marc-sheitoyan-23748. |
