References
- Naslain R. Design, preparation and properties of non-oxide CMCs for application in engines and nuclear reactors: an overview. Compos Sci Technol. 2004;64:155–170.
- Meyer P, Waas A. FEM predictions of damage in continous fiber ceramic matrix composites under transverse tension using the crack band method. Acta Mater. 2016;102:292–303.
- Juhong L, Yanqing Y, Xian L. Effects of fiber volume fraction on transverse tensile properties of SiC/Ti-6Al-4V composites. Rare Met Eng. 2011;40(4):575–579.
- Mahmoodia MJ, Aghdamb MM. Damage analysis of fiber reinforced Ti-alloy subjected to multi-axial loading a micromechanical approach. Mater Sci Eng A. 2011;528(27):7983–7990.
- Correa E, Mantic V, París F. Effect of thermal residual stresses on matrix failure under transverse tension. Compos Sci Technol. 2011;71:622–629.
- Trias D, Costa J, Mayugo J, et al. Random models versus periodic models for fibre reinforced composites. Comput Mater Sci. 2006;38(2):316–324.
- Weng J, Wen W, Cui H, et al. Micromechanical analysis of composites with fibers distributed randomly over the transverse cross-section. Acta Astronaut. 2018;147:133–140.
- Kim HG, Ji W, Cho NC, et al. Effects of nonuniform fiber geometries on the microstructural fracture behavior of ceramic matrix composites. Math Probl Eng. 2019;2019(2):1–15.
- Mayer CR, Molina-Aladareguia J, Chawla N. Three dimensional (3D) microstructure-based finite element modeling. Mater Charact. 2016;120:369–376.
- Romanov V, Lomov SV, Swolfs Y, et al. Statistical analysis of real and simulated fibre arrangements in unidirectional composites. Compos Sci Technol. 2013;87:126–134.
- Corso FD, Deseri L. Residual stresses in random elastic composites: nonlocal micromechanics-based models and first estimates of the representative volume element size. Meccanica. 2013;48(8):1901–1923.
- Soni G, Singh R, Mitra M, et al. Modelling matrix damage and Fibre–matrix interfacial decohesion in composite laminates via a multi-fibre multi-layer representative volume element (m2rve). Int J Solids Struct. 2014;51(2):449–461.
- Kanit T, Forest S, Galliet I, et al. Determination of the size of the representative volume element for random composites: statistical and numerical approach. Int J Solids Struct. 2003;40(13-14):3647–3679.
- González C, Lorca J. Mechanical behavior of unidirectional fiber-reinforced polymers under transverse compression. Microscopic mechanisms and modeling. Compos Sci Technol. 2007;67(13):2795–2806.
- Song L, Meng S, Xu C, et al. Finite element-based phase-field simulation of interfacial damage in. Modell Simul Mater Sci Eng. 2019;27(5):1–20.
- Zhi J, Zhao L, Zhang J, et al. A numerical method for simulating the microscopic damage evolution in composites under uniaxial transverse tension. Appl Compos Mater. 2015;23; doi:10.1007/s10443-015-9459-y.
- Bhuiyan FH, Sanei SHR, Iii RSF. Predicting variability in transverse effective elastic moduli and failure initiation strengths in UD composite microstructures due to randomness in fiber location and morphology. Compos Struct. 2020;237:111887.
- Pai P, Meiying Z, Wang W. Transverse strength prediction of composite materials via micromechanics model. Mech Sci Technol Aerosp Eng. 2017;36(10):1611–1618. (in Chinese).
- Yang L, Yan Y, Liu Y, et al. Microscopic failure mechanisms of fiber-reinforced polymer composites under transverse tension and compression. Compos Sci Technol. 2012;72(15):1818–1825.
- Palizvan M, Homayuon Sadr M, Tahaye Abadi M. Effect of interface properties on micromechanical damage behavior of fiber reinforced composites. Mater Today Commun. 2019; doi:10.1016/j.mtcomm.2019.100856.
- Zhenyu X, Ruojing Z, Lu Y. Global elastic constants of fiber reinforced composites with random distribution cracks in matrix. Fiber ReinfPlast/Compos. 2002;5:7–9. 33. (in Chinese).
- Huang H, Talreja R. Effects of void geometry on elastic properties of unidirectional fiber reinforced composites. Compos Sci Technol. 2005;65(13):1964–1981.
- Kim RY, Pagano NJ. Crack initiation in unidirectional brittle-matrix composites. J Ceram Soc Am. 1991;74:1082–1090.
- Garret KW, Bailey JE. Multiple transverse fracture in 90° cross-ply laminates of a glass fiber-reinforced polyester. J Mater Sci. 1977;12:157–168.
- Hyde A, He J, Cui X, et al. Effects of microvoids on strength of unidirectional fiber-reinforced composite materials. Compos B: Eng. 2020;187:107844.
- Ashouri Vajari D, González C, Llorca J, et al. A numerical study of the influence of microvoids in the transverse mechanical response of unidirectional composites. Compos Sci Technol. 2014;97:46–54.
- Yongdong X, Laifei C, Litong Z, et al. Research on continuous fiber reinforced sil icon carbid e composites. J Chin Ceram Soc. 2002;30(2):184–188. (in Chinese).
- Zhilong Z, Qizhi W, Fei S. Numerical simulation of C/SiC Plain Weave composites with defects under unidirectional tension. J Aeronaut Mater. 2017;37(4):61–68.
- Zhen-Bang K. Stress analysis of polygonal defects with plane curvature of only sharp points. Chin J Theor Appl Mech. 1979;02:118–128. (in Chinese).
- Muskhelishvili NI. Some basic problems of the mathematical theory of elasticity, 4th edn. Noordhoff, Groningen. 1954; 526.
- Jialin L, Yumin W, Guoxing Z, et al. Research on single SiC fiber reinforced TC17 composites under transverse tension. Acta Metall Sinica. 2018;54(12):1809–1817. (in Chinese).
- Sandino C, Correa E, París F. Numerical analysis of the influence of a nearby fibre on the interface crack growth in composites under transverse tensile load. Eng Fract Mech. 2016: S0013794416000503.
- Hailong X. Crack propagation of weak interface of continuous ceramic matrix composites. Tianjin, Civil Aviation University of China. 2020;23–44. (in Chinese).
- Wang X, Zhang J, Wang Z, et al. Effects of interphase properties in unidirectional fiber reinforced composite materials. Mater Des. 2011;32(6):3486–3492.