Large-scale Fabrication of Snake-skin-inspired Protective Composite Textiles

Qing Liu; Fengxiang Chen; Tingting Dong; Woong-Ryeol Yu; Chaoyu Chen; Gaoming Jiang; Zhijia Dong; Pibo Ma

doi:10.1007/s42765-024-00396-7

Advanced Fiber Materials ›› 2024, Vol. 6 ›› Issue (4) : 978-992. DOI: 10.1007/s42765-024-00396-7

Research Article

Large-scale Fabrication of Snake-skin-inspired Protective Composite Textiles

Author information +

History +

Abstract

Inspired by the overlapping structure of snake scales, a reinforced scale-like knitted fabric (R-SLKF) was created in this work. To achieve this, short carbon fibers in an epoxy resin (ER) matrix were incorporated into the scales of an SLKF. The resulting textile is a highly stable protective composite that is flexible, warm, and thermally insulated. In addition, superior stab-resistance is ensured through rigid protective blocks in the R-SLKF, making up a hard overlapping scale region, besides satisfactory flexibility via soft twisted ultra-high-molecular-weight polyethylene yarn-based textiles. The R-SLKF achieves high stab resistance (peak load of approximately 600 N for a single scale thickness of 2 mm), good flexibility (~ 290 mN cm), and breathability (100 MPa, 423 mm/s), coupled with good warmth retention and thermal insulation properties (0.28 ℃/s), which are superior to previously reported protective composite textiles. From the results, the combination of desirable individual protection, excellent wearability and comfort enables human beings to survive in extremely dangerous environments. Finite element simulations provided valuable insights into the factors influencing the stab resistance of R-SLKF and elucidated the underlying anti-puncture mechanism in accordance with the experimental findings. This study presents a novel strategy for the facile industrial fabrication of flexible and lightweight protective composite textiles, which is expected to enhance the structure and material design for future innovations and provide advantages for personal protective equipment in various industrial fields.

Keywords

Scale-like knitted fabric / Stab-resistance / Flexibility / Air permeability / Warmth retention and thermal insulation properties

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Qing Liu, Fengxiang Chen, Tingting Dong, Woong-Ryeol Yu, Chaoyu Chen, Gaoming Jiang, Zhijia Dong, Pibo Ma. Large-scale Fabrication of Snake-skin-inspired Protective Composite Textiles. Advanced Fiber Materials, 2024, 6(4): 978‒992 https://doi.org/10.1007/s42765-024-00396-7

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Chai GB, Manikandan P. Low velocity impact response of fibre-metal laminates-a review. Compos Struct, 2014, 107: 363-381, CrossRef Google scholar

[2]	Zhao ZN, Han B, Li FH, Zhang R, Su PB, Yang M, Zhang Q, Zhang QC, Lu TJ. Enhanced bi-layer mosaic armor: experiments and simulation. Ceram Int, 2020, 15: 23854-23866, CrossRef Google scholar

[3]	Ong CW, Boey CW, Hixson RS, Sinibaldi JO. Advanced layered personnel armor. Int J Impact Eng, 2011, 5: 369-383, CrossRef Google scholar

[4]	Zhang BW, Wang YW, Du SF, Yang ZK, Cheng HW, Fan QB. Influence of backing plate support conditions on armor ceramic protection efficiency. Materials, 2020, 15: 3427, CrossRef Google scholar

[5]	Rodriguez MM, Diaz AA, Aranda RJ, Diaz AJ, Loya JA. Experimental analysis for stabbing resistance of different aramid composite architectures. Compos Struct, 2019, 208: 525-534, CrossRef Google scholar

[6]	Li W, Xiong DS, Zhao XD, Sun LL, Liu J. Dynamic stab resistance of ultra-high molecular weight polyethylene fabric impregnated with shear thickening fluid. Mater Design, 2016, 102: 162-167, CrossRef Google scholar

[7]	Chukov DI, Stepashkin AA, Maksimkin AV, Tcherdyntsev W, Kaloshkin SD, Kuskov KV, Bugakov VI. Investigation of structure, mechanical and tribological properties of short carbon fiber reinforced UHMWPE-matrix composites. Compos Part B, 2015, 76: 79-88, CrossRef Google scholar

[8]	Guo YX, Yuan MQ, Qian XM, Wei YC, Liu Y. Rapid prediction of polymer stab-resistance performance. Mater Design, 2020, 192: 108721, CrossRef Google scholar

[9]	Zhang CH, Rawatn P, Liu P, Zhu DJ. A new design and performance optimization of bio-inspired flexible protective equipment. Bioinspir Biomim, 2020, 6: 066003, CrossRef Google scholar

[10]	Prashant P, Zhu DJ, Barthelat F. Structural and mechanical properties of fish scales for the bio-inspired design of flexible body armors: a review. Acta Biomater, 2021, 1231: 41-67

[11]	Johnson AA, Bingham GA, Majewski CE. The design and assessment of bio-inspired additive manufactured stab-resistant armour. Virtual Phys Prototy, 2018, 13: 49-57, CrossRef Google scholar

[12]	Arrigo MI, Vilaca LMD, Fofonjka A, Srikanthan AN, Debry A, Milinkovitch MC. Phylogenetic mapping of scale nanostructure diversity in snakes. BMC Ecol Evol, 2019, 19: 91

[13]	Chango AH, Vela PA. Evaluation of bio-Inspired scales on locomotion performance of snake-like robots. Robotica, 2019, 8: 1302-1319, CrossRef Google scholar

[14]	Fu SH, Wei FN, Yin C, Yao LG, Wang YX. Biomimetic soft micro-swimmers: from actuation mechanisms to applications. Biomed Microdevices, 2021, 1: 6, CrossRef Google scholar

[15]	Zheng L, Zhong YH, Gao YH, Li JY, Zhang ZH, Liu ZN, Ren LQ. Coupling effect of morphology and mechanical properties contributes to the tribological behaviors of snake scales. J Bionic Eng, 2018, 3: 481-493, CrossRef Google scholar

[16]	Liu C, Chen YT, Zheng YH, Bo J, Yang CJ, Xu S, Zhang S. Wear resistance improvement of keeled structure and overlapped distribution of snake scales. J Bionic Eng, 2023, 20: 1121-1131, CrossRef Google scholar

[17]	Gong Z, Qian XM, Yuan MQ. Structural design of a 3D printed stab resistant body armor. Rapid Prototyp J, 2019, 1: 143-151, CrossRef Google scholar

[18]	Xu JX, Fu CY, Fu QQ, Chen Y, Ma YJ, Feng X. Flexible arc-armor inspired by origami. Int J Mech Sci, 2021, 201: 106463, CrossRef Google scholar

[19]	Guo YX, Yuan MQ, Qian XM. Bionic stab-resistant body armor based on triangular pyramid structure. Def Technol, 2021, 3: 792-799, CrossRef Google scholar

[20]	Li CS, Huang XC, Li Y, Yang NC, Shen ZH, Fan XH. Stab-resistance of UHMWPE fiber composites impregnated with thermoplastics. Polym Advan Technol, 2014, 9: 1014-1019, CrossRef Google scholar

[21]	Zhang XY, Li TT, Sun F, Peng HK, Wang ZK, Lin JH, Lou CW. Stab/puncture resistance performance of needle punched nonwoven fabrics: effects of filament reinforcement and thermal bonding. Fiber Polym, 2022, 8: 2330-2339, CrossRef Google scholar

[22]	Murphy SV, Atala A. 3D bioprinting of tissues and organs. Nat Biotechnol, 2014, 32: 773-785, CrossRef Google scholar

[23]	Chen ML, Hu N, Zhou C, Lin XK, Xie H, He Q. The hierarchical structure and mechanical performance of a natural nanocomposite material: the turtle shell. Colloid Surface A, 2017, 520: 97-104, CrossRef Google scholar

[24]	Browning A, Ortiz C, Boyce MC. Mechanics of composite elasmoid fish scale assemblies and their bioinspired analogues. J Mech Behav Biomed, 2013, 19: 75-86, CrossRef Google scholar

[25]	Rudykh S, Ortiz C, Boyce MC. Flexibility and protection by design: imbricated hybrid microstructures of bio-inspired armor. Soft Matter, 2015, 11: 2547-2554, CrossRef Google scholar

[26]	Ghosh R, Ebrahimi H, Vaziri A. Contact kinematics of biomimetic scales. Appl Phys Lett, 2014, 105: 233701, CrossRef Google scholar

[27]	Shen DH, Zhang Q, Wang CJ, Wang XS, Tian MQ. Design and analysis of a snake-inspired crawling robot driven by alterable angle scales. IEEE Robot Autom Let, 2021, 6: 3744-3751, CrossRef Google scholar

[28]	Mao LZ, Zhou MJ, Yao L, Yu H, Yan XF, Shen Y, Chen WS, Ma PB, Ma Y, Zhang SL, Tan SC. Crocodile skin-inspired protective composite textiles with pattern-controllable soft-rigid unified structures. Adv Funct Mater, 2023, 33: 2213419, CrossRef Google scholar

[29]	Duro-Royo J, Zolotovsky K, Mogas-Soldevila L, Varshney S, Oxman N, Boyce MC, Ortiz C. MetaMesh: a hierarchical computational model for design and fabrication of biomimetic armored surfaces. Comput Aided Design, 2015, 60: 14-27, CrossRef Google scholar

[30]	Funk N, Vera M, Szewciw LJ, Barthelat F, Stoykovich MP, Vernerey FJ. Bioinspired fabrication and characterization of a synthetic fish skin for the protection of soft materials. ACS Appl Mater Interfaces, 2015, 10: 5972-5983, CrossRef Google scholar

[31]	Celik SB, Cobanoglu I. Comparative investigation of Shore, Schmidt, and Leeb hardness tests in the characterization of rock materials. Environ Earth Sci, 2019, 78: 554, CrossRef Google scholar

[32]

, Zhang

, Tao

, Wang

, Cheng

, Jie

, Song

, Hu

. Self-healable castor oil-based waterborne polyurethane/MXene film with outstanding electromagnetic interference shielding effectiveness and excellent shape memory performance. J Colloid Interf Sci, 2021, 588: 164-174,

CrossRef Google scholar

[33]	Jia PF, Zhu YL, Lu JY, Wang BY, Song L, Wang BB, Hu Y. Multifunctional fireproof electromagnetic shielding polyurethane films with thermal management performance. Chem Eng J, 2022, 439: 135673, CrossRef Google scholar

[34]	Jia PF, Yu FH, Tao YJ, Sun PF, Xing WY, Jie GX, Hu Y, Wang BB. Multifunctional additive: a novel regulate strategy for improving mechanical property, aging life and fire safety of EVA composites. Chem Eng J, 2023, 473: 145283, CrossRef Google scholar

[35]

Yin

, Lu

, Hong

, Cheng

, Jia

, Wang

, Hu

, Wang

, Song

, Hu

. Functionalizing Ti₃C₂T_x for enhancing fire resistance and reducing toxic gases of flexible polyurethane foam composites with reinforced mechanical properties. J Colloid Interf Sci, 2022, 607: 1300-1312,

CrossRef Google scholar

[36]	Reddy KN, Gangadharan R, Ramji M. Experimental and numerical studies on the buckling and post-buckling behavior of single blade stiffened CFRP panels. Compos Struct, 2018, 196: 135-154, CrossRef Google scholar

[37]	Li W, Xiong DS, Liu J. Dynamic stab-resistance of ultra-high molecular weight polyethylene fabric impregnated with shear thickening fluid. Mater Design, 2016, 102: 162-167, CrossRef Google scholar

[38]	Xia MM, Quan ZZ, Wang XL, Yu JY. Preparation and characterization of B4C particle coated composites for stab-resistance. Compos Struct, 2019, 228: 111370, CrossRef Google scholar

[39]	Yan BB, Zhou M, Yu YY, Xu B, Cui L, Wang Q, Wang P. Orderly self-stacking a high-stability coating of MXene@Polydopamine hybrid onto textiles for multifunctional personal thermal management. Compos Part A, 2022, 160: 107038, CrossRef Google scholar

[40]	Zhu DJ, Szewciw L, Vernerey F, Brathelat F. Puncture resistance of the scaled skin from striped bass: collective mechanisms and inspiration for new flexible armor designs. Sciverse Sci Direct, 2013, 24: 30-40

[41]	Sherman VR, Quan HC, Yang W, Ritchie RO, Meyers MA. A comparative study of piscine defense: the scales of Arapaima gigas, Latimeria chalumnae and Atractosteus spatula. J Mech Behav Biomed, 2017, 73: 1-16, CrossRef Google scholar

[42]	Yang W, Naleway SE, Porter MM, Meyers MA, Mckittrick J. The armored carapace of the boxfish. Acta Biomater, 2015, 23: 1-10, CrossRef Google scholar

[43]	Yang W, Chen IH, Gludovatz B, Zimmermann EA, Ritchie RO, Meyers MA. Natural flexible dermal armor. Adv Mater, 2013, 25: 31-48, CrossRef Google scholar

[44]	Zhao HY, Qiang YQ, Peng HK, Xing MF, Zhang XY, Lou CW. Enhancement of a novel sizing agent in mechanical properties and Stab/Puncture resistance of Kevlar fabrics. Fiber Polym, 2021, 12: 1-8

[45]	Zhang XY, Li TT, Peng HK, Lou CW, Lin JH. Enhanced sandwich structure composite with shear thickening fluid and thermoplastic polyurethanes for High-performance stab resistance. Compos Struct, 2022, 280: 114930, CrossRef Google scholar

[46]	Liu Q, Sun YX, Zhao JZ, Ma PB. Failure mechanism of weft-knitted insertion fabric/Surlyn resin flexible composite for stab-resistance. Text Res J, 2023, 93: 2473-2489, CrossRef Google scholar

[47]	Lin TR, Lin TA, Lin MC, Lin YY, Lou CW, Lin JH. Impact resistance of fiber reinforced sandwich-structured nonwoven composites: reinforcing effect of different fiber length. Mater Today Commun, 2020, 24: 101345, CrossRef Google scholar

[48]	Miao XH, Kong XY, Jiang GM. The experimental research on the stab resistance of warp-knitted spacer fabric. J Ind Text, 2013, 43: 281-301, CrossRef Google scholar

[49]	Martini R, Barthelat F. Stretch-and-release fabrication, testing and optimization of a flexible ceramic armor inspired from fish scales. Bioinspir Biomim, 2016, 11: 066001, CrossRef Google scholar

[50]	Martini R, Balit Y, Barthela F. A comparative study of bio-inspired protective scales using 3D printing and mechanical testing. Acta Biomater, 2017, 55: 360-372, CrossRef Google scholar

[51]	Martini R, Barthelat F. Stability of hard plates on soft substrates and application to the design of bioinspired segmented armor. J Mech Phys Solids, 2016, 92: 195-209, CrossRef Google scholar

[52]	Chintapalli RK, Mirkhalaf M, Dastjerdi AK, Barthelat F. Fabrication, testing and modeling of a new flexible armor inspired from natural fish scales and osteoderms. Bioinspir Biomim, 2014, 3: 036005, CrossRef Google scholar

[53]	Liu Q, Wang LL, Luo M, Wu Q, Kang Y, Ma PB. Stab-resistance of flexible composite reinforced with warp-knitted fabric like scale structure at quasi-static loading. J Ind Text, 2022, 51: 7983S-7998S, CrossRef Google scholar

[54]

Yan

, Bao

, Liao

, Wang

, Zhou

, Yu

, Yuan

, Cui

, Wang

. Sensitive micro-breathing sensing and highly-effective photothermal antibacterial cinnamomum camphora bark micro-structural cotton fabric via electrostatic self-assembly of MXene/HACC. ACS Appl Mater Inter, 2022, 1: 2132-2145,

CrossRef Google scholar

[55]	Delavari K, Dabiryan H. Mathematical and numerical simulation of geometry and mechanical behavior of sandwich composites reinforced with 1×1-Rib-Gaiting weft-knitted spacer fabric; compressional behavior. Compos Struct, 2021, 268: 113952, CrossRef Google scholar

Funding

National Natural Science Funds of China(11972172); Natural Science Foundation of Hubei Province(2023AFB828); the Fundamental Research Funds for the Central Universities(JUSRP22026); Innovative Team Program of Natural Science Foundation of Hubei Province(2023AFA027); a Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions(PAP); National Local Joint Laboratory for Advanced Textile Processing and Clean Production(17)