[1] K.B. Yilmaz, B. Sabuncuoglu, B. Yildirim, V. V. Silberschmidt, A brief review on the mechanical behavior of nonwoven fabrics, Journal of Engineered Fibers and Fabrics, 15 (2020).
[2] S. Bais-Singh, B.C. Goswami, Theoretical Determination of the Mechanical Response of Spun-bonded Nonwovens, The Journal of The Textile Institute, 86(2) (1995) 271-288.
[3] H. Lee, M. Yanilmaz, O. Toprakci, K. Fu, X. Zhang, A review of recent developments in membrane separators for rechargeable lithium-ion batteries, Energy & Environmental Science, 7(12) (2014) 3857-3886.
[4] S. Lukić, P. Jovanić, Structural analysis of abrasive composite materials with nonwoven textile matrix, Materials Letters, 58(3-4) (2004) 439-443.
[5] G.C. Engelmayr, M.S. Sacks, A structural model for the flexural mechanics of nonwoven tissue engineering scaffolds, Journal of Biomechanical Engineering, 128(4) (2006) 610-622.
[6] A. Rawal, A. Priyadarshi, N. Kumar, S. V. Lomov, I. Verpoest, Tensile behaviour of nonwoven structures: Comparison with experimental results, Journal of Materials Science, 45(24) (2010) 6643-6652.
[7] Y. Yin, Z. Pan, J. Xiong, A tensile constitutive relationship and a finite element model of electrospun nanofibrous mats, Nanomaterials, 8(1) (2018).
[8] L.Y. Wan, H. Wang, W. Gao, F. Ko, An analysis of the tensile properties of nanofiber mats, Polymer (Guildf), 73 (2015) 62-67.
[9] A. Ridruejo, C. González, J. Llorca, A constitutive model for the in-plane mechanical behavior of nonwoven fabrics, International Journal of Solids and Structures, 49(17) (2012) 2215-2229.
[10] H.L. Cox, The elasticity and strength of paper and other fibrous materials, British Journal of Applied Physics, 3(3) (1952) 72-79.
[11] S. Backer, D.R. Petterson, Some Principles of Nonwoven Fabrics1, Textile Research Journal, 30(9) (1960) 704-711.
[12] Y. Yin, J. Xiong, Finite element analysis of electrospun nanofibrous mats under biaxial tension, Nanomaterials, 8(5) (2018).
[13] F. Farukh, E. Demirci, H. Ali, M. Acar, B. Pourdeyhimi, V. V. Silberschmidt, Nonwovens modelling: A review of finite-element strategies, The Journal of The Textile Institute, 107(2) (2016) 225-232.
[14] X. Hou, M. Acar, V. V. Silberschmidt, 2D finite element analysis of thermally bonded nonwoven materials: Continuous and discontinuous models, Computational Materials Science, 46(3) (2009) 700-707.
[15] S. Bais-Singh, R.D. Anandjiwala, B.C. Goswami, Characterizing Lateral Contraction Behavior of Spunbonded Nonwovens During Uniaxial Tensile Deformation, Textile Research Journal, 66(3) (1996) 131-140.
[16] F. Lin, W. Li, X. Du, J. Jiang, N. Chen, Structure, property and knittability of polyimide filaments with various strength and modulus, Textile Research Journal, 89(5) (2019) 771-781.
[17] F. Chen, X. Peng, T. Li, S. Chen, X. Wu, D.H. Reneker, H. Hou, Mechanical characterization of single high-strength electrospun polyimide nanofibres, Journal of Physics D: Applied Physics, 41(2) (2008).
[18] F. Lin, W. Li, Y. Tang, H. Shao, C. Su, J. Jiang, N. Chen, High-Performance Polyimide Filaments and Composites Improved by O2 Plasma Treatment, Polymers, 10(7) (2018) 695.