1] F.T. Peirce, “The geometry of cloth structure”, J. Text.
Inst. Trans., vol. 12, no. 3, pp. T45-T96, 193[2] G. Leaf and A. Glaskin, “The geometry of a plain
knitted loop”, J. Text. Inst. Transactions, vol. 46, no.
9, pp. T587-T605, 1955.
[3] A. Kemp, “An extension of Peirce’s cloth geometry to
the treatment of non-circular threads”, J. Text. Inst.
Trans., vol. 49, no. 1, pp. T44-T48, 1958.
[4] D. Munden, “The geometry and dimensional properties
of plain-knit fabrics”, J. Text. Inst. Trans., vol. 50, no.
7, pp. T448-T71, 1959.
[5] J. Hearle and W. Shanahan, “An energy method for
calculations in fabric mechanics. Part I: principles of
the method”, J. Text. Inst., vol. 69, no. 4, pp. 81-91,
1978.
[6] S.G. Vassiliadis, A.E. Kallivretaki, and C.G. Provatidis,
“Geometrical modelling of plain weft knitted fabrics”,
Indian J. Fibre Text. Res., vol. 32, pp. 62-71, 2007.
[7] M.K. Dolatabadi and R. Kovař, “Geometry of plain
weave fabric under shear deformation. Part II: 3D
model of plain weave fabric before deformation”, J.
Text. Inst., vol. 100, no. 5, pp. 381-386, 2009.
[8] A.A.A. Jeddi, H.R. Karimi, and A. Rastgoo, “Theoretical
analysis of load-extension behaviour of plain-weft-
knitted fabric”, J. Text. Inst., vol. 100, no. 1, pp. 18-
27, 2009.
[9] H. Dabiryan and A.A.A. Jeddi, “Analysis of warp
knitted fabric structure. Part I: a 3D straight line model
for warp knitted fabrics”, J. Text. Inst., vol. 102, no.
12, pp. 1065-74, 2011.
[10] Y. Kyosev, “Generalized geometric modeling of
tubular and flat braided structures with arbitrary
floating length and multiple filamentsˮ, Text. Res. J.,
vol. 86, no. 12, pp. 1270, 2015.
[11] A. Kurbak, “Geometrical models for weft-knitted
spacer fabrics”, Text. Res. J., vol. 87, no. 4, pp. 409-
423, 2017.
[12] K. Delavari and H. Dabiryan, “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., vol. 268,
pp. 113952, 2021.
[13] D.M. Schwaber, “Impact behavior of polymeric
foams: a review”, Polym. Plast. Technol. Eng., vol. 2,
no. 2, pp. 231-249, 1973.
[14] L.J. Gibson, M.F. Ashby, G.S. Schajer, and C.I.
Robertson, “The mechanics of two-dimensional
cellular materials”, Proc. R. Soc. Loud. A, vol. 382,
pp. 25-42, 1982.
[15] T. Allen, J. Shepherd, T.A.M. Hewage, T. Senior, L.
Foster, and A. Alderson, “Low-kinetic energy impact
response of auxetic and conventional open-cellpolyurethane foams”, Phys. Status Solidi Basic Res.,
vol. 252, no. 7, pp. 1631-1639, 2015.
[16] H. Dabiryan, F. Hasanalizade, and M. Sadighi, “Low-
velocity impact behavior of composites reinforced
with weft-knitted spacer glass fabrics”, J. Ind. Text.,
vol. 49, no. 4, pp. 465-483, 2019.
[17] N.W. Li, K.L. Yick, and A. Yu, “Novel weft-knitted
spacer structure with silicone tube and foam inlays for
cushioning insoles”, J. Ind. Text., vol. 51, no. 4, pp.
6463S-6483S, 2022.
[18] F. Hasanalizade and H. Dabiryan, “Theoretical
modeling of low-velocity impact behavior of
sandwich-structured composites reinforced with weft-
knitted spacer fabric”, J. Ind. Text., vol. 52, pp. 1-21,
2022.
[19] C. Zhi, M. Du, Z. Sun, M. Wu, X. He, J. Meng, and L.
Yu, “Warp-knitted spacer fabric reinforced syntactic
foam: a compression modulus meso-mechanics
theoretical model and experimental verification”,
Polymers (Basel), vol. 12, no. 2, 2020.
[20] K. Delavari and H. Dabiryan, “Effect of Z-fiber
orientation on the bending behavior of sandwich-
structured composite: Numerical and experimental
study”, Compos. Struct., vol. 256, pp. 113140, 2021.
[21] V. Ghorbani, A.A.A. Jeddi, and H. Dabiryan,
“Theoretical and experimental investigation of tensile
properties of net warp-knitted spacer fabrics”, J. Text.
Inst., vol. 111, no. 4, pp. 518-528, 2020