Progressive failure analysis of notched composite plate by utilizing macro mechanics approach

Seyed M. N. GHOREISHI; Mahdi FAKOOR; Ahmad AZIZI

doi:10.1007/s11709-021-0726-8

Front. Struct. Civ. Eng. ›› 2021, Vol. 15 ›› Issue (3) : 623 -642. DOI: 10.1007/s11709-021-0726-8

RESEARCH ARTICLE

Progressive failure analysis of notched composite plate by utilizing macro mechanics approach

Author information +

History +

PDF (10222KB)

Abstract

In this study, gradual and sudden reduction methods were combined to simulate a progressive failure in notched composite plates using a macro mechanics approach. Using the presented method, a progressive failure is simulated based on a linear softening law prior to a catastrophic failure, and thereafter, sudden reduction methods are employed for modeling a progressive failure. This combination method significantly reduces the computational cost and is also capable of simultaneously predicting the first and last ply failures (LPFs) in composite plates. The proposed method is intended to predict the first ply failure (FPF), LPF, and dominant failure modes of carbon/epoxy and glass/epoxy notched composite plates. In addition, the effects of mechanical properties and different stacking sequences on the propagation of damage in notched composite plates were studied. The results of the presented method were compared with experimental data previously reported in the literature. By comparing the numerical and experimental data, it is revealed that the proposed method can accurately simulate the failure propagation in notched composite plates at a low computational cost.

Graphical abstract

Keywords

progressive failure / notched composite plate / Hashin failure criterion / macro mechanics approach / finite element method

Cite this article

Download citation ▾

Seyed M. N. GHOREISHI, Mahdi FAKOOR, Ahmad AZIZI. Progressive failure analysis of notched composite plate by utilizing macro mechanics approach. Front. Struct. Civ. Eng., 2021, 15(3): 623-642 DOI:10.1007/s11709-021-0726-8

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Cárdenas D, Elizalde H, Marzocca P, Abdi F, Minnetyan L, Probst O. Progressive failure analysis of thin-walled composite structures. Composite Structures, 2013, 95: 53–62

[2]	Rafiee R, Torabi M A. Stochastic prediction of burst pressure in composite pressure vessels. Composite Structures, 2018, 185: 573–583

[3]	Irisarri F X, Laurin F, Carrere N, Maire J F. Progressive damage and failure of mechanically fastened joints in CFRP laminates—Part II: Failure prediction of an industrial junction. Composite Structures, 2012, 94(8): 2278–2284

[4]	Jordan J B, Naito C J, Haque B Z. Progressive damage modeling of plain weave E-glass/phenolic composites. Composites. Part B, Engineering, 2014, 61: 315–323

[5]	Lee C S, Kim J H, Kim S, Ryu D M, Lee J M. Initial and progressive failure analyses for composite laminates using Puck failure criterion and damage-coupled finite element method. Composite Structures, 2015, 121: 406–419

[6]	Fakoor M, Mohammad Navid Ghoreishi S. Experimental and numerical investigation of progressive damage in composite laminates based on continuum damage mechanics. Polymer Testing, 2018, 70: 533–543

[7]	Vo-Duy T, Nguyen-Minh N, Dang-Trung H, Tran-Viet A, Nguyen-Thoi T. Damage assessment of laminated composite beam structures using damage locating vector (DLV) method. Frontiers of Structural and Civil Engineering, 2015, 9(4): 457–465

[8]	Fakoor M, Ghoreishi S M N, Khansari N M. Investigation of composite coating effectiveness on stress intensity factors of cracked composite pressure vessels. Journal of Mechanical Science and Technology, 2016, 30(7): 3119–3126

[9]	Fakoor M, Ghoreishi S M N. Verification of a micro-mechanical approach for the investigation of progressive damage in composite laminates. Acta Mechanica, 2019, 230(1): 225–241

[10]	Matzenmiller A, Lubliner J, Taylor R. A constitutive model for anisotropic damage in fiber-composites. Mechanics of Materials, 1995, 20(2): 125–152

[11]	Hamdia K M, Silani M, Zhuang X, He P, Rabczuk T. Stochastic analysis of the fracture toughness of polymeric nanoparticle composites using polynomial chaos expansions. International Journal of Fracture, 2017, 206(2): 215–227

[12]	Vu-Bac N, Lahmer T, Zhuang X, Nguyen-Thoi T, Rabczuk T. A software framework for probabilistic sensitivity analysis for computationally expensive models. Advances in Engineering Software, 2016, 100: 19–31

[13]	Lapczyk I, Hurtado J A. Progressive damage modeling in fiber-reinforced materials. Composites. Part A, Applied Science and Manufacturing, 2007, 38(11): 2333–2341

[14]	Voyiadjis G Z, Taqieddin Z N, Kattan P I. Micromechanical approach to damage mechanics of composite materials with fabric tensors. Composites. Part B, Engineering, 2007, 38(7–8): 862–877

[15]	Nobeen N S, Zhong Y, Francis B A P, Ji X, Chia E S M, Joshi S C, Chen Z. Constituent materials micro-damage modeling in predicting progressive failure of braided fiber composites. Composite Structures, 2016, 145: 194–202

[16]	Praud F, Chatzigeorgiou G, Chemisky Y, Meraghni F. Hybrid micromechanical-phenomenological modelling of anisotropic damage and anelasticity induced by micro-cracks in unidirectional composites. Composite Structures, 2017, 182: 223–236

[17]	Barbero E, Cosso F, Roman R, Weadon T. Determination of material parameters for Abaqus progressive damage analysis of E-glass epoxy laminates. Composites. Part B, Engineering, 2013, 46: 211–220

[18]	Wang L, Zheng C, Luo H, Wei S, Wei Z. Continuum damage modeling and progressive failure analysis of carbon fiber/epoxy composite pressure vessel. Composite Structures, 2015, 134: 475–482

[19]	Papanikos P, Tserpes K, Labeas G, Pantelakis S. Progressive damage modelling of bonded composite repairs. Theoretical and Applied Fracture Mechanics, 2005, 43(2): 189–198

[20]	Areias P, Msekh M, Rabczuk T. Damage and fracture algorithm using the screened Poisson equation and local remeshing. Engineering Fracture Mechanics, 2016, 158: 116–143

[21]	Areias P, Reinoso J, Camanho P, César de Sá J C, Rabczuk T. Effective 2D and 3D crack propagation with local mesh refinement and the screened Poisson equation. Engineering Fracture Mechanics, 2018, 189: 339–360

[22]	Areias P, Rabczuk T, Msekh M. Phase-field analysis of finite-strain plates and shells including element subdivision. Computer Methods in Applied Mechanics and Engineering, 2016, 312: 322–350

[23]	Areias P, Rabczuk T, Camanho P. Finite strain fracture of 2D problems with injected anisotropic softening elements. Theoretical and Applied Fracture Mechanics, 2014, 72: 50–63

[24]	Areias P, Rabczuk T, Dias-da-Costa D. Element-wise fracture algorithm based on rotation of edges. Engineering Fracture Mechanics, 2013, 110: 113–137

[25]	Areias P, Rabczuk T. Steiner-point free edge cutting of tetrahedral meshes with applications in fracture. Finite Elements in Analysis and Design, 2017, 132: 27–41

[26]	Rabczuk T, Belytschko T. Cracking particles: A simplified meshfree method for arbitrary evolving cracks. International Journal for Numerical Methods in Engineering, 2004, 61(13): 2316–2343

[27]	Rabczuk T, Belytschko T. A three-dimensional large deformation meshfree method for arbitrary evolving cracks. Computer Methods in Applied Mechanics and Engineering, 2007, 196(29–30): 2777–2799

[28]	Rabczuk T, Zi G, Bordas S, Nguyen-Xuan H. A simple and robust three-dimensional cracking-particle method without enrichment. Computer Methods in Applied Mechanics and Engineering, 2010, 199(37–40): 2437–2455

[29]	Moure M, Otero F, García-Castillo S, Sánchez-Sáez S, Barbero E, Barbero E. Damage evolution in open-hole laminated composite plates subjected to in-plane loads. Composite Structures, 2015, 133: 1048–1057

[30]	Su Z, Tay T, Ridha M, Chen B. Progressive damage modeling of open-hole composite laminates under compression. Composite Structures, 2015, 122: 507–517

[31]	Chang F K, Lessard L B. Damage tolerance of laminated composites containing an open hole and subjected to compressive loadings: Part I—Analysis. Journal of Composite Materials, 1991, 25(1): 2–43

[32]	Hashin Z, Rotem A. A fatigue failure criterion for fiber reinforced materials. Journal of Composite Materials, 1973, 7(4): 448–464

[33]	Tsai S W, Wu E M. A general theory of strength for anisotropic materials. Journal of Composite Materials, 1971, 5(1): 58–80

[34]	Sun C, Tao J. Prediction of failure envelopes and stress/strain behaviour of composite laminates1. Composites Science and Technology, 1998, 58(7): 1125–1136

[35]	Puck A, Kopp J, Knops M. Guidelines for the determination of the parameters in Puck’s action plane strength criterion. Composites Science and Technology, 2002, 62(3): 371–378

[36]	Cuntze R, Freund A. The predictive capability of failure mode concept-based strength criteria for multidirectional laminates. Composites Science and Technology, 2004, 64(3–4): 343–377

[37]	He P, Shen Y, Gu Y, Shen P. 3D fracture modelling and limit state analysis of prestressed composite concrete pipes. Frontiers of Structural and Civil Engineering, 2019, 13(1): 165–175

[38]	Nali P, Carrera E. A numerical assessment on two-dimensional failure criteria for composite layered structures. Composites. Part B, Engineering, 2012, 43(2): 280–289

[39]	Yang B, Yue Z, Geng X, Wang P, Gan J, Liao B. Effects of space environment temperature on the mechanical properties of carbon fiber/bismaleimide composites laminates. Proceedings of the Institution of Mechanical Engineers. Part G, Journal of Aerospace Engineering, 2018, 232(1): 3–16

[40]	Liu P, Zheng J. Recent developments on damage modeling and finite element analysis for composite laminates: A review. Materials & Design, 2010, 31(8): 3825–3834

[41]	Catalanotti G, Camanho P, Marques A. Three-dimensional failure criteria for fiber-reinforced laminates. Composite Structures, 2013, 95: 63–79

[42]	Weng J, Wen W, Zhang H. Study on low-velocity impact and residual strength at high temperatures of composite laminates. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering. 2017, 233(3): 1106–1123

[43]	Maimí P, Camanho P P, Mayugo J, Dávila C. A continuum damage model for composite laminates: Part I—Constitutive model. Mechanics of Materials, 2007, 39(10): 897–908

[44]	Baaran J, Kärger L, Wetzel A. Efficient prediction of damage resistance and tolerance of composite aerospace structures. Proceedings of the Institution of Mechanical Engineers, Part G, Journal of Aerospace Engineering, 2008, 222(2): 179–188

[45]	Zhang B, Zhao L. Progressive damage and failure modeling in fiber-reinforced laminated composites containing a hole. International Journal of Damage Mechanics, 2012, 21(6): 893–911

[46]	Zhang X. Impact damage in composite aircraft structures-experimental testing and numerical simulation. Proceedings of the Institution of Mechanical Engineers. Part G, Journal of Aerospace Engineering, 1998, 212(4): 245–259

[47]	Liu P F, Zheng J. Progressive failure analysis of carbon fiber/epoxy composite laminates using continuum damage mechanics. Materials Science and Engineering A, 2008, 485(1–2): 711–717

[48]	Mills A, Jones J. Investigation, manufacture, and testing of damage-resistant airframe structures using low-cost carbon fibre composite materials and manufacturing technology. Proceedings of the Institution of Mechanical Engineers. Part G, Journal of Aerospace Engineering, 2010, 224(4): 489–497

[49]	Liu P F, Chu J, Hou S, Xu P, Zheng J. Numerical simulation and optimal design for composite high-pressure hydrogen storage vessel: A review. Renewable & Sustainable Energy Reviews, 2012, 16(4): 1817–1827

[50]	Bažant Z P, Pfeiffer P A. Determination of fracture energy from size effect and brittleness number. ACI Materials Journal, 1987, 84(6): 463–480

[51]	Lange F, Radford K. Fracture energy of an epoxy composite system. Journal of Materials Science, 1971, 6(9): 1197–1203

[52]	Bažant Z P, Kazemi M T. Determination of fracture energy, process zone longth and brittleness number from size effect, with application to rock and conerete. International Journal of Fracture, 1990, 44(2): 111–131