1-
[1] Bullock, R. E., “Strength Ratios of Composite Materials in Flexure and in Tension” Journal of Composite Materials, Vol. 8, pp. 200-206, 1974.
[2] Whitney, J. M. and Knight, M., “The Relationship between Tensile Strength and Flexure Strength in Fiber-Reinforced Composites” Experimental Mechanics, Vol. 20(6), pp. 211-216, 1980.
[3] Ullah, H. Harland, A. R. Lucas, T. et al., “Finite Element Modelling of Bending of CFRP Laminates: Multiple Delaminations” Compsite Materials Science, Vol. 52, pp. 147–156, 2012.
[4] Cattell, M. K. and Kibble, K. A., “Determination of the Relationship Between Strength and Test Method for Glass Fibre Epoxy Composite Coupons Using Weibull Analysis” Materials and Design, Vol. 22, pp. 245-250, 2001.
[5] Zweben, C., “Is There a Size Effect in Composite Materials and Structures?” Composites, Vol. 25, pp. 451-454, 1994.
[6] Smith, D. L. Wardle M. W. Zweben, C., “Test Methods for Fiber Tensile Strength, Composite Flexural Modulus and Properties of Fabric-Reinforced Laminates” In: SW Tsai (ed) Composite Materials: Testing and Design (Fifth Conference), ASTM STP 674, West Conshohocken: American Society for Testing and Materials, pp. 228-262, 1979.
[7] Tolf, G. and Clarin, P., “Comparison between Flexural and Tensile Modulus of Fibre Composites” Fibre Science Technolgy, Vol. 21, pp. 319-326, 1984.
[8] Roopa, T. S. Murthy, H. N. Sudarshan, K., et al. “Mechanical Properties of Vinylester/Glass and Polyester/Glass Composites Fabricated by Resin Transfer Molding and Hand Lay-up” Journal of Vinyl Additive Technolgy, Doi: 11.1002/vnl.21393, 2014.
[9] Standard Test Methods for Flexural Properties of Unreinforced and Reinforced Plastics and Electrical Insulating Materials. ASTM, Designation: D790–07, 2007.
[10] Echaabi, J. Trochu, F. Pham, X. T., et al. “Theoretical and Experimental Investigation of Failure and Damage Progression of Graphite-Epoxy Composites in Flexural Bending Test” Journal of Reinforced Plastics and Composites, Vol. 15, pp. 740–755, 1996.
[11] Tehrani-Dehkordi, M., “Numerical modeling of bending behavior of intra-ply hybrid composites using finite element method” Journal of Science and Technology of Composites, Vol. 2, No. 4, pp. 59-66, 2016. (In Persian)
[12] Huang, Z. M., “Progressive flexural failure analysis of laminated composites with knitted fabric reinforcement,” Mechanics of Materials, Vol. 36, pp. 239-260, 2004.
[13] Santiuste, C. Sánchez-Sáez, S. Barbero, E., “A comparison of progressive-failure criteria in the prediction of the dynamic bending failure of composite laminated beams,” Composite Structures Vol. 92, pp. 2406–2414, 2010.
[14] Shokrieh, M. M. Ghajar, M. Salamattalab, M. and Madoliat, R., “Progressive damage modeling of laminated composites by considering simultaneous effects of interlaminar and intralaminar damage mechanisms” Journal of Science and Technology of Composites, Vol. 2, No. 2, pp. 1-8, 2015. (In Persian)
[15] Nazari, A. R., “Investigation of load carrying and progressive failure in the composite sandwich panels with elastomeric foam core under biaxial bending,” Ph.D. Thesis, Amirkabir University of Technology, Iran, 2016.
[16] Standard Test Method for Tensile Properties of Polymer Matrix Composite Materials, ASTM, D3039/D3039M – 00.
[17] ABAQUS, “Analysis user’s manual. Version 6.10” ABAQUS Inc, 2010.
[18] Batra, R. C. Gopinath, G. and Zheng, J. Q., “Damage and failure in low energy impact of fiber-reinforced polymeric composite laminates” Composite Structures, Vol. 94, pp. 540–547, 2012.
[19] Hashin, Z., “On Elastic Behaviour of Fibers Reinforced Materials of Arbitrary Transverse Phase Geometry” Journal of Mechanics of Physics and Solids, Vol. 13, pp. 119–134, 1965.
[20] Hashin, Z. and Rotem, A., “A Fatigue Criterion for Fiber-Reinforced Materials,” Journal of Composite Materials, Vol. 7, pp. 448–464, 1973.
[21] Soden, P. D. Hinton, M. J. and Kaddour, A. S. A., “Comparison of the Predictive Capabilities of Current Failure Theories for Composite Laminates” Composite Science Technology, Vol. 58, pp. 1225-1254, 1998.
[22] Maimi, P. Camanho P. P. Mayugo J. A. Da´vila C. G., “A continuum damage model for composite laminates: Part I – Constitutive model”, Mechanics of Materials, Vol. 39: pp. 897-908, 2007.
[23] Lapczyk, I. and Hurtado, J. A., “Progressive Damage Modeling in Fiber-Reinforced Materials” Composites Part A-Applications, Vol. 38: pp. 2333–2341, 2007.
[24] Maimi, P. Camanho, P. P. Mayugo, J. A., et al. “A Continuum Damage Model for Composite Laminates: Part I – Constitutive Model” Mechanics of Materials, Vol. 39, pp. 897–908, 2007.
[25] Doudican, B. M. Zand, B. Amaya, P., et al. “Strain Energy Based Failure Criterion: Comparison of Numerical Predictions and Experimental Observations for Symmetric Composite Laminates Subjected to Triaxial Loading” Journal of Compos Materials, Vol. 47, No. 6–7, pp. 847–866, 2012.
[26] Wolfe W. E. and Butalia, T. S., “A Strain-Energy Based Failure Criterion for Non-Linear Analysis of Composite Laminates Subjected to Biaxial Loading” Composite Science Technology, Vol. 58, pp. 1107-1124, 1998.
[27] Jones, R. M., “Mechanics of Composite Materials with Different Moduli in Tension and Compression” Final Scientific Report, Air Force Office of Scientific Research, 1978.
[28] Mujika, F. Carbajal, N. Arrese, A. Mondragon, I., “Determination of Tensile and Compressive Moduli by Flexural Tests” Polymer Testing, Vol. 25, pp. 766–771, 2006.
[29] Roopa, T. S. Murthy, H. N. Sudarshan, K., et al. “Mechanical Properties of Vinylester/glass and Polyester/glass Composites Fabricated by Resin Transfer Molding and Hand lay-up” Journal of Vinyl Additive and Technology, doi: 11.1002/vnl.21393, 2014.