This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
1. Nilakantan, Gaurav, and Steven Nutt. Effects of ply orientation and material on the ballistic impact behavior of multilayer plain-weave aramid fabric targets. Defence technology 14.3 (2018): 165–178.NilakantanGauravStevenNutt. Effects of ply orientation and material on the ballistic impact behavior of multilayer plain-weave aramid fabric targets1. 14.3 (2018): 165178.Search in Google Scholar
2. Yang, Cheng-Chou, Tuan Ngo, and Phuong Tran. Influences of weaving architectures on the impact resistance of multi-layer fabrics. Materials & Design 85 (2015): 282-295.YangCheng-ChouTuanNgoPhuongTran. Influences of weaving architectures on the impact resistance of multi-layer fabrics. 85 (2015): 282-295.Search in Google Scholar
3. Nipanjan Nayak, Chandra Sekher, Yerramalli, AsimTewari. Experimental investigation of the impact resistance on KEVLAR XP S308® fabric impacted with truncated ogive projectile subjected to pre-tension. Int J Impact Eng 2022,163, 104165.NipanjanNayakChandraSekherYerramalliAsimTewari. Experimental investigation of the impact resistance on KEVLAR XP S308® fabric impacted with truncated ogive projectile subjected to pre-tension. 2022, 163, 104165.Search in Google Scholar
4. Hongxu Wang, DakshithaWeerasinghe, DamithMohotti, Paul J.Hazell, V.P.W.Shim, KrishnaShankar, Evgeny V. Morozov. On the impact response of UHMWPE woven fabrics: Experiments and simulations. International Journal of Mechanical Sciences. 2021,204, 106574.HongxuWangDakshithaWeerasingheDamithMohottiPaul J.HazellV.P.W.ShimKrishnaShankarEvgeny V.Morozov. On the impact response of UHMWPE woven fabrics: Experiments and simulations. 2021, 204, 106574.Search in Google Scholar
5. Yanfei Yang, Yanchen Liu, Sainan Xue, Xiangling Sun. Multi-scale finite element modeling of ballistic impact onto woven fabric involving fiber bundles. Composite Structures,2021,267, 113856.YanfeiYangYanchenLiuSainanXueXianglingSun. Multi-scale finite element modeling of ballistic impact onto woven fabric involving fiber bundles. , 2021, 267, 113856.Search in Google Scholar
6. Haolei Mou, Jiang Xie, Hui Pei, Zhenyu Feng, Hongzhang Geng. Ballistic impact tests and stacked shell simulation analysis of aramid fabric containment system. Aerospace Science and Technology. 2020, 107, 106344.HaoleiMouJiangXieHuiPeiZhenyuFengHongzhangGeng. Ballistic impact tests and stacked shell simulation analysis of aramid fabric containment system. 2020, 107, 106344.Search in Google Scholar
7. Xu, Wanli, Zhijia Dong, and Pibo Ma. Finite element analyses of auxetic warp-knitted fabric deformation behaviors under low-velocity impact loading. The Journal of The Textile Institute 111.11 (2020): 1578-1586.XuWanliZhijiaDongPiboMa. Finite element analyses of auxetic warp-knitted fabric deformation behaviors under low-velocity impact loading. 111.11 (2020): 1578-1586.Search in Google Scholar
8. Zeng, Haoxian, Xiaogang Chen, and Yanfei Yang. Influences of Combined Section in Three-dimensional Networked Fabric against Ballistic Impact. Applied Composite Materials (2021): 1-15.ZengHaoxianXiaogangChenYanfeiYang. Influences of Combined Section in Three-dimensional Networked Fabric against Ballistic Impact. (2021): 1-15.Search in Google Scholar
9. Palta Emre, Fang Howie. On a multi-scale finite element model for evaluating ballistic performance of multi-ply woven fabrics. Composite Structures 2019; 207:488–580.PaltaEmreFangHowie. On a multiscale finite element model for evaluating ballistic performance of multi-ply woven fabrics. 2019; 207:488-580.Search in Google Scholar
10. Giannaros, E, Kotzakolios, A., Sotiriadis, G., Tsantzalis, S, & Kostopoulos, V. On fabric materials response subjected to ballistic impact using meso-scale modeling. Numerical simulation and experimental validation. Composite Structures, 204(2018), 745-754.GiannarosEKotzakoliosA.SotiriadisG.TsantzalisSKostopoulosV.On fabric materials response subjected to ballistic impact using meso-scale modeling. Numerical simulation and experimental validation. , 204(2018), 745-754.Search in Google Scholar
11. Yang, Yanfei, and Xiaogang Chen. Influence of fabric architecture on energy absorption efficiency of soft armour panel under ballistic impact. Composite Structures 224 (2019): 111015.YangYanfeiXiaogangChen. Influence of fabric architecture on energy absorption efficiency of soft armour panel under ballistic impact. 224 (2019): 111015.Search in Google Scholar
12. Chu, Y, Rahman, M. R, Min, S., & Chen, X. Experimental and numerical study of inter-yarn friction affecting mechanism on ballistic performance of Twaron® fabric. Mechanics of Materials, 148(2020), 103421.ChuYRahmanM. RMinS.ChenX.Experimental and numerical study of inter-yarn friction affecting mechanism on ballistic performance of Twaron® fabric. , 148(2020), 103421.Search in Google Scholar
13. Miao, H., Wu, Z., Ying, Z., & Hu, X.. The numerical and experimental investigation on low-velocity impact response of composite panels: Effect of fabric architecture. Composite Structures, 227(2019), 111343.MiaoH.WuZ.YingZ.HuX.. The numerical and experimental investigation on low-velocity impact response of composite panels: Effect of fabric architecture. , 227(2019), 111343.Search in Google Scholar
14. Yadav, K., Upadhyay, A. K., & Shukla, K. K. Effect of obliquity on ballistic impact response of plain-woven fabric. International Journal of Materials and Structural Integrity, (2019)13(1-3), 93–109.YadavK.UpadhyayA. K.ShuklaK. K.Effect of obliquity on ballistic impact response of plain-woven fabric. ,(2019)13(1-3), 93109.Search in Google Scholar
15. Feito, N., Loya, J. A., Muñoz-Sánchez, A., & Das, R. Numerical modelling of ballistic impact response at low velocity in aramid fabrics. Materials, (2019)12(13), 2087.FeitoN.LoyaJ. A.Muñoz-SánchezA.DasR.Numerical modelling of ballistic impact response at low velocity in aramid fabrics. , (2019)12(13), 2087.Search in Google Scholar
16. Palta, Emre, and Howie Fang. On a multi-scale finite element model for evaluating ballistic performance of multi-ply woven fabrics.Composite Structures 207 (2019): 488-508.PaltaEmreHowieFang. On a multiscale finite element model for evaluating ballistic performance of multi-ply woven fabrics. 207 (2019): 488-508.Search in Google Scholar
17. Grujicic M, Hariharan a, Pandurangan B, Yen CF, Cheeseman Ba, Wang Y, Zheng JQ. Fiber-level modeling of dynamic strength of kevlar® KM2 ballistic fabric. J Mater Eng Perform 2012;21(7):1107–19.GrujicicMHariharanaPanduranganBYenCFCheesemanBaWangYZhengJQ. Fiber-level modeling of dynamic strength of kevlar® KM2 ballistic fabric. 2012;21(7):1107-19.Search in Google Scholar
18. Zhang, Y, Ju, J. W, Zhu, H, Guo, Q, & Yan, Z. Micromechanics based multi-level model for predicting the coefficients of thermal expansion of hybrid fiber reinforced concrete. Construction and Building Materials, 190(2018), 948-963.ZhangYJuJ. W.ZhuH.GuoQ.YanZ.Micromechanics based multi-level model for predicting the coefficients of thermal expansion of hybrid fiber reinforced concrete. , 190(2018), 948-963.Search in Google Scholar
19. Ivanov I, Tabiei A. Loosely woven fabric model with viscoelastic crimped fibers for ballistic impact simulations. Int J Numer Meth Eng 2004;61(10):1565–83.IvanovITabieiA.Loosely woven fabric model with viscoelastic crimped fibers for ballistic impact simulations. 2004;61(10):1565-83.Search in Google Scholar
20. Shahkarami a, Vaziri R. A continuum shell finite element model for impact simulation of woven fabrics. Int J Impact Eng 2007;34(1):104–19.ShahkaramiaVaziriR.A continuum shell finite element model for impact simulation of woven fabrics. 2007;34(1):104-19.Search in Google Scholar
21. Fang H, Gutowski M, Disogra M, Wang Q. A numerical and experimental study of woven fabric material under ballistic impacts. Adv Eng Softw (2016), 96:14–28.FangHGutowskiMDisograMWangQ.A numerical and experimental study of woven fabric material under ballistic impacts. (2016), 96:14-28.Search in Google Scholar
22. Liu, L, Yang, Z., Liu, X, Chen, W, Zhao, Z, & Luo, G. Yarn dynamic tensile behavior and meso-scale numerical simulation method for STF-Kevlar fabrics. Thin-Walled Structures, 159 (2021), 107319.LiuLYangZ.LiuX.ChenW.ZhaoZ.LuoG.Yarn dynamic tensile behavior and meso-scale numerical simulation method for STF-Kevlar fabrics. , 159 (2021), 107319.Search in Google Scholar
23. Zeng, H., Chen, X., & Yang, Y.. Influences of Combined Section in Three-dimensional Networked Fabric against Ballistic Impact. Applied Composite Materials, (2021)1-15.ZengH.ChenX.YangY.. Influences of Combined Section in Three-dimensional Networked Fabric against Ballistic Impact. , (2021)1-15.Search in Google Scholar
24. Giannaros, E., Kotzakolios, A., Sotiriadis, G., Tsantzalis, S., & Kostopoulos, V. On fabric materials response subjected to ballistic impact using meso-scale modeling. Numerical simulation and experimental validation. Composite Structures, 204, (2018) 745-754.GiannarosE.KotzakoliosA.SotiriadisG.TsantzalisS.KostopoulosV.On fabric materials response subjected to ballistic impact using meso-scale modeling. Numerical simulation and experimental validation. , 204, (2018) 745-754.Search in Google Scholar
25. Priyanka, P, Mali, H. S, & Dixit, A. Mesoscale numerical characterization of Kevlar and carbon–Kevlar hybrid plain-woven fabric compression behavior. Journal of Materials Engineering and Performance, (2019)28(9), 5749-5762.PriyankaPMaliH. S.DixitA.Mesoscale numerical characterization of Kevlar and carbon-Kevlar hybrid plain-woven fabric compression behavior. , (2019)28(9), 5749-5762.Search in Google Scholar
26. Feito, N., Loya, J. A., Muñoz-Sánchez, A., & Das, R. Numerical modelling of ballistic impact response at low velocity in aramid fabrics. Materials, (2019)12(13), 2087.FeitoN.LoyaJ. A.Muñoz-SánchezA.DasR.Numerical modelling of ballistic impact response at low velocity in aramid fabrics. , (2019)12(13), 2087.Search in Google Scholar
27. Canyi Huang, Lina Cui, Hong Xia, Yiping Qiu, Qing-Qing Ni. A numerical study on the influence of hole defects on impact behavior of Twaron® fabric subjected to low-velocity impacts. Journal of Engineered Fibers and Fabrics, 2021,16: 1–18.CanyiHuangLinaCuiHongXiaYip-ingQiuQing-QingNi. A numerical study on the influence of hole defects on impact behavior of Twaron® fabric subjected to low-velocity impacts. ,2021,16: 1-18.Search in Google Scholar
28. Wang, H, Weerasinghe, D, Mohotti, D, Hazell, P. J, Shim, V. P. W, Shankar, K., & Morozov, E. V. On the Impact Response of UHMWPE Woven Fabrics: Experiments and Simulations. International Journal of Mechanical Sciences, (2021)106574.WangHWeerasingheD.MohottiD.HazellP. J.ShimV. P. W.ShankarK.MorozovE. V.On the Impact Response of UHMWPE Woven Fabrics: Experiments and Simulations. , (2021)106574.Search in Google Scholar
29. Canyi Huang, Lina Cui, Yajun Liu, Hong Xia, Yiping Qiu, Qing-Qing Ni. Low-velocity drop weight impact behavior of Twaron® fabric investigated using experimental and numerical simulations. Int J Impact Eng, (2021)149, 103796.CanyiHuangLinaCuiYajunLiuHongXiaYipingQiuQing-QingNi. Low-velocity drop weight impact behavior of Twaron® fabric investigated using experimental and numerical simulations. , (2021)149, 103796.Search in Google Scholar
30. Canyi Huang, Lina Cui, Hong Xia, Yiping Qiu, Qing-Qing Ni. A numerical study on the low-velocity impact behavior of the Twaron® fabric subjected to oblique impact. Reviews on Advanced Materials Science, 2021,60:980-994.CanyiHuangLinaCuiHongXiaYipingQiuQing-QingNi. A numerical study on the low-velocity impact behavior of the Twaron® fabric subjected to oblique impact. , 2021,60:980-994.Search in Google Scholar
31. Hairong Miao, Zhenyu Wu, Zhiping Ying, Xudong Hu. The numerical and experimental investigation on low-velocity impact response of composite panels: Effect of fabric architecture. Composite Structures 227 (2019) 111343.HairongMiaoZhenyuWuZhipingYingXudongHu. The numerical and experimental investigation on low-velocity impact response of composite panels: Effect of fabric architecture. 227 (2019) 111343.Search in Google Scholar
32. Canyi Huang, Lina Cui, Hong Xia, Yiping Qiu, Qing-Qing Ni. Influence of crimp and inter-yarn friction on the mechanical properties of woven fabric under uniaxial/biaxial tensile loading. FIBRES & TEXTILES in Eastern Europe, 2020(28): 43-52.CanyiHuangLinaCuiHongXiaYipingQiuQing-QingNi. Influence of crimp and inter-yarn friction on the mechanical properties of woven fabric under uniaxial/biaxial tensile loading. , 2020(28): 43-52.Search in Google Scholar
33. Yanfei Yang, Xiaogang Chen. Investigation on energy absorption efficiency of each layer in ballistic amour panel for applications in hybrid design. Composite Structure, 164 (2017), pp. 1-9.YanfeiYangXiaogangChen. Investigation on energy absorption efficiency of each layer in ballistic amour panel for applications in hybrid design. , 164 (2017), pp. 1-9.Search in Google Scholar