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Progressive Failure Analysis of Composites

Department of Mechanical Engineering, National University of Singapore, mpetayte{at}nus.edu.sg

G. Liu

Department of Mechanical Engineering, National University of Singapore

V.B.C. Tan

Department of Mechanical Engineering, National University of Singapore

X.S. Sun

Department of Mechanical Engineering, National University of Singapore

D.C. Pham

Department of Mechanical Engineering, National University of Singapore

Recent developments in the aircraft industry towards substantially improving fuel economy and extending flight range have accelerated interest in the use of advanced composites as primary structural materials. The airframes of next-generation airliners will have substantial parts made of light-weight composites. This means that the engineering demands on the performance of fiber-reinforced composites will become greater. There is therefore a need to better understand and predict the multiple complex failure mechanisms in composite structures, and to devise more reliable failure theories and damage progression models. There is a large body of literature on progressive damage analysis in composites, much of which employs damage mechanics and material stiffness degradation methods. This article reviews some of the more recent work in this area and describes the issues pertinent to application in composite structures. The authors' ongoing research efforts in modeling and prediction of progressive damage through the relatively novel element-failure method (EFM), which has been coded into a user-defined UEL code in Abaqus, are discussed. In particular, results for notched composite laminates and pin-loaded (PL) analyses are shown and compared to experimental data. Although EFM is the computational platform on which the damage is advanced in the structure, the results are dependent on the choice of the failure criterion. Various failure criteria are used throughout the cases discussed herein, from the more traditional Tsai—Wu (TW) criterion to the very recently proposed micromechanics-based failure (MMF) criterion. The EFM may also be used with cohesive elements, with the former intended for modeling in-plane damage progression, while the latter for delamination onset and propagation. This hybrid EFM-cohesive element approach is illustrated with an analysis of double-notched composite laminate. The computational models are relatively robust up to and including ultimate load, and enable the mapping of extensive damage patterns in composite structures. They represent a suite of computational tools that extend the capability to model damage and failure propagation beyond initial failure prediction.

Key Words: progressive failure analysis • failure criteria • notched composites • delamination • element-failure method (EFM) • material property degradation method (MPDM).

References

• Hinton, M.J., Soden, P.D. and Kaddour, A.S. (2004). Failure Criteria in Fiber-Reinforced-Polymer Composites, Elsevier, Oxford.
• Hinton, M.J., Kaddour, A.S. and Soden, P.D. (2002). A Comparison of the Predictive Capabilities of Current Failure Theories for Composite Laminates, Judged against Experimental Evidence, Composites Science and Technology, 62(12-13): 1725-1797.
• Daniel, I.M. (2007). Failure of Composite Materials, Strain, 43(1): 4-12.[CrossRef][Web of Science]
• Icardi, U., Locatto, S., Student, G. and Longo, A. (2007). Assessment of Recent Theories for Predicting Failure of Composite Laminates, Applied Mechanics Reviews, 60(2): 76-86.[CrossRef][Web of Science]
• Herakovich, C.T. (1998). Mechanics of Fibrous Composite, John Wiley & Sons, Inc., New York.
• Tsai, S.W. and Wu, E.M. (1971). A General Theory of Strength for Anisotropic Materials, Journal of Composite Materials, 5(1): 58-80.[Abstract]
• Sun, C.T. (2000). Strength Analysis of Unidirectional Composites and Laminates, Comprehensive Composite Materials, Elsevier Science, Ltd., Oxford.
• Pinho, S.T., Iannucci, L. and Robinson, P. (2006). Physically Based Failure Models and Criteria for Laminated Fibre-Reinforced Composites with Emphasis on Fibre Kinking, Part II: FE Implementation, Composites Part A: Applied Science and Manufacturing, 37(5): 766-777.
• Pinho, S.T., Iannucci, L. and Robinson, P. (2006). Physically Based Failure Models and Criteria for Laminated Fibre-Reinforced Composites with Emphasis on Fibre Kinking: Part I: Development, Composites Part A: Applied Science and Manufacturing, 37(1): 63-73.[CrossRef][Web of Science]
• Laurin, F., Carrère, N. and Maire, J.F. (2007). A Multiscale Progressive Failure Approach for Composite Laminates Based on Thermodynamical Viscoelastic and Damage Models, Composites Part A: Applied Science and Manufacturing, 38(1): 198-209.[CrossRef][Web of Science]
• Hashin, Z. (1980). Failure Criteria for Unidirectional Fiber Composites, Journal of Applied Mechanics, 47(1): 58-80.
• Puck, A. and Schürmann, H. (1998). Failure Analysis of FRP Laminates by Means of Physically Based Phenomenological Models, Composites Science and Technology, 58: 1045-1067.[CrossRef][Web of Science]
• Kuraishi, A., Tsai, S.W. and Liu, K.K.S. (2002). A Progressive Quadratic Failure Criterion, Part B. Composites Science and Technology, 62(12-13): 1683-1695.[CrossRef][Web of Science]
• Gosse, J.H. and Christensen, S. (2001). Strain Invariant Failure Criteria for Polymers in Composite Materials, AIAA-2001-1184.
• Mayes, J.S. and Hansen, A.C. (2004). A Comparison of Multicontinuum Theory Based Failure Simulation with Experimental Results, Composites Science and Technology, 64(3-4): 517-527.[CrossRef][Web of Science]
• Ha, S.K., Jin, K.K. and Huang, Y. (2008). Micro-Mechanics of Failure (MMF) for Continuous Fiber Reinforced Composites, Journal of Composite Materials (this issue).
• Christensen, R.M. (2008). Failure Criteria for Anisotropic Fiber Composite Materials [cited 2008 February 25]; Available from: www.failurecriteria.com.
• Tan, S.C. and Nuismer, R.J. (1989). A Theory for Progressive Matrix Cracking in Composite Laminates, Journal of Composite Materials, 23(10): 1029-1047.[Abstract]
• Tan, S.C. and Perez, J. (1993). Progressive Failure of Laminated Composites with a Hole under Compressive Loading, Journal of Reinforced Plastics and Composites, 12(10): 1043-1057.[Abstract]
• Tan, S.C. (1991). A Progressive Failure Model for Composite Laminates Containing Openings, Journal of Composite Materials, 25(5): 556-577.[Abstract/Free Full Text]
• Camanho, P.P. and Matthews, F.L. (1999). A Progressive Damage Model for Mechanically Fastened Joints in Composite Laminates, Journal of Composite Materials, 33(24): 2248-2280.[Abstract/Free Full Text]
• Apalak, Z.G., Apalak, M.K. and Genc, M.S. (2006). Progressive Damage Modeling of an Adhesively Bonded Unidirectional Composite Single-Lap Joint in Tension at the Mesoscale Level, Journal of Thermoplastic Composite Materials, 19(6): 671-702.[Abstract/Free Full Text]
• Apalak, Z.G., Apalak, M.K. and Genc, M.S. (2007). Progressive Damage Modeling of an Adhesively Bonded Composite Single Lap Joint Under Flexural Loads at the Mesoscale Level, Journal of Reinforced Plastics and Composites, 26(9): 903-953.[Abstract/Free Full Text]
• Qing, X., Sun, H.T., Dagba, L. and Chang, F.K. (2000). Damage-Tolerance-Based Design of Bolted Composite Joints, In: Grant, P. and Rousseau, C.Q. (eds). Composite Structures: Theory and Practice, ASTM STP 1383, American Society for Testing and Materials, West Conshohocken, PA: 243-272.
• Ahn, J. and Waas, A.M. (2005). The Failure Of Notched Composite Laminates Under Compression Using Integrated Macro-Micromechanics Model, 46th AIAA/ASME/ASCE/AHS/ ASC Structures, Structural Dynamics, and Materials Conference, 18-21 April 2005, Austin, Texas, AIAA 2005-1954: 1-14.
• Ahn, J.H. and Waas, A.M. (2000). Micromechanics-Based Predictive Model for Compressively Loaded Angle-Ply Composite Laminates, AIAA Journal, 38(12): 2299-2304.[CrossRef][Web of Science]
• Chamis, C.C., Murthy, P.L.N. and Minnetyan, L. (1997). Progressive Fracture in Composite Structures, In: Armanios, E.A. (eds). Composite Materials: Fatigue and Fracture 6th Volume, ASTM STP 1285, American Society for Testing and Materials, pp. 70-84.
• Kwon, Y.W. and Craugh, L.E. (2001). Progressive Failure Modeling in Notched Cross-Ply Fibrous Composites, Applied Composite Materials, 8(1): 63-74.[CrossRef][Web of Science]
• Kortschot, M.T. and Beaumont, P.W.R. (1990). Damage Mechanics of Composite Materials: II - A Damaged-Based Notched Strength Model, Composites Science and Technology, 39(4): 303-326.[CrossRef][Web of Science]
• Reddy, Y.S.N., Moorthy, C.M.D. and Reddy, J.N. (1995). Non-Linear Progressive Failure Analysis of Laminated Composite Plates, International Journal of Non-Linear Mechanics, 30(5): 629-649.[CrossRef]
• Chu, G.D. and Sun, C.T. (1993). Failure Initiation and Ultimate Strength of Composite Laminates Containing a Center Hole, Composite Materials: Fatigue and Fracture, Fourth Volume, ASTM STP 1156, Stinchcomb, W.W. and Ashbaugh, N.E. (Eds)., American Society for Testing and Materials, Philadelphia, pp. 35-54.
• Pal, P. and Ray, C. (2002). Progressive Failure Analysis of Laminated Composite Plates by Finite Element Method, Journal of Reinforced Plastics and Composites, 21(16): 1505-1513.[Abstract/Free Full Text]
• Prusty, B.G. (2005). Progressive Failure Analysis of Laminated Unstiffened and Stiffened Composite Panels, Journal of Reinforced Plastics and Composites, 24(6): 633-642.[Abstract]
• Kim, Y., Davalos, J.F. and Barbero, E.J. (1996). Progressive Failure Analysis of Laminated Composite Beams, Journal of Composite Materials, 30(5): 536-560.[Abstract]
• Chang, F.K., Lessard, L. and Tang, J.M. (1988). Compression Response of Laminated Composites Containing an Open Hole, SAMPE Quarterly, 19(4): 46-51.
• Liu, K.S. and Tsai, S.W. (1998). A Progressive Quadratic Failure Criterion for a Laminate, Composites Science and Technology, 58(7): 1023-1032.[CrossRef][Web of Science]
• Sandhu, R.S., Sendeckyj, G.P. and Gallo, R.L. (1983). Modeling of the Failure Process in Notched Laminates, In: Hashin, Z. and Herakovich, C.T. (eds), Mechanics of Composite Materials: Recent Advances, pp. 179-189, Pergamon Press, Oxford.
• Petit, P.H. and Waddoups, M.E. (1969). A Method of Predicting the Nonlinear Behavior of Laminated Composites, Journal of Composite Materials, 3(1): 2-19.[Abstract]
• Zhao, G. and Cho, C. (2004). On Impact Damage of Composite Shells by a Low-Velocity Projectile, Journal of Composite Materials, 38(14): 1231-1254.[Abstract/Free Full Text]
• Kress, G., Siau, M. and Ermanni, P. (2005). Iterative Solution Methods for Damage Progression Analysis, Composite Structures, 69(1): 21-33.[CrossRef][Web of Science]
• Greif, R. and Chapon, E. (1993). Investigation of Successive Failure Modes in Graphite/ Epoxy Laminated Composite Beams, Journal of Reinforced Plastics and Composites, 12(5): 602-620.[Abstract]
• Turon, A., Camanho, P.P., Costa, J. and Davila, C.G. (2006). A Damage Model for the Simulation of Delamination in Advanced Composites under Variable-Mode Loading, Mechanics of Materials, 38(11): 1072-1089.[CrossRef][Web of Science]
• Allen, D.H., Harris, C.E. and Groves, S.E. (1987). A Thermomechanical Constitutive Theory for Elastic Composites with Distributed Damage - Part I: Theoretical Development, International Journal of Solids and Structures, 23(9): 1301-1318.[CrossRef][Web of Science]
• Allen, D.H., Harris, C.E. and Groves, S.E. (1987). A Thermomechanical Constitutive Theory for Elastic Composites with Distributed Damage - Part II: Application to Matrix Cracking in Laminated Composites, International Journal of Solids and Structures, 23(9): 319-1338.
• Feih, S. and Shercliff, H.R. (2005). Adhesive and Composite Failure Prediction of Single-L Joint Structures under Tensile Loading, International Journal of Adhesion and Adhesives, 25(1): 47-59.[CrossRef][Web of Science]
• Feih, S. and Shercliff, H.R. (2005). Composite Failure Prediction of Single-L Joint Structures under Bending, Composites Part A: Applied Science and Manufacturing, 36(3): 381-395.[CrossRef][Web of Science]
• Barbero, E.J. and Lonetti, P. (2002). An Inelastic Damage Model for Fiber Reinforced Laminates, Journal of Composite Materials, 36(8): 941-962.[Abstract/Free Full Text]
• Coats, T.W., Harris, C.E., Lo, D.C. and Allen, D.H. (1998). Progressive Damage Analysis of Laminated Composite(PDALC) (A Computational Model Implemented in the NASA COMET Finite Element Code). NASA, (19990017734).
• Voyiadjis, G.Z. and Kattan, P.I. (1993). Damage of Fiber-Reinforced Composite Materials with Micromechanical Characterization, International Journal of Solids and Structures, 30(20): 2757-2778.[CrossRef][Web of Science]
• Voyiadjis, G.Z. and Park, T. (1995). Anisotropic Damage of Fiber-Reinforced MMC Using Overall Damage Analysis, Journal of Engineering Mechanics, 121(11): 1209-1217.[CrossRef][Web of Science]
• Voyiadjis, G.Z. and Park, T. (1995). Local and Interfacial Damage Analysis of Metal Matrix Composites, International Journal of Engineering Science, 33(11): 1595-1621.[CrossRef][Web of Science]
• Robbins, D.H., Reddy, J.N. and Rostam-Abadi, F. (2005). Layerwise Modeling of Progressive Damage in Fiber-Reinforced Composite Laminates, International Journal of Mechanics and Materials in Design, 2(3): 19-36.[CrossRef]
• Talreja, R. (1985). Transverse Cracking and Stiffness Reduction in Composite Laminates, Journal of Composite Materials, 19(4): 355-375.[Abstract]
• Lee, S., Scott, R.F., Gaudert, P.C., Ubbink, W.H. and Poon, C. (1988). Mechanical Testing of Toughened Resin Composite Materials, Composites, 19(4): 300-310.[CrossRef][Web of Science]
• Allix, O. and Ladeveze, P. (1992). Interlaminar Interface Modelling for the Prediction of Delamination, Composite Structures, 22(4): 235-242.[CrossRef][Web of Science]
• Allix, O., Ladeveze, P. and Corigliano, A. (1995). Damage Analysis of Interlaminar Fracture Specimens, Composite Structures, 31(1): 61-74.[CrossRef][Web of Science]
• Ladeveze, P. and Le Dantec, E. (1992). Damage Modeling of the Elementary Ply for Laminated Composites, Composites Science and Technology, 43(3): 257-267.[CrossRef][Web of Science]
• Ladeveze, P.E.A., Ladevèze, P., Allix, O., Deu, J.-F. and Levêque, D. (2000). A Mesomodel for Localisation and Damage Computation in Laminates, Computer Methods in Applied Mechanics and Engineering, 183: 105-122.[CrossRef][Web of Science]
• Xiao, Y. and Ishikawa, T. (2002). Bearing Failure in Bolted Composite Joints: Analytical Tools Development, Advanced Composite Materials, 11(4): 375-391.[CrossRef][Web of Science]
• Chen, J., Crisfield, M., Kinloch, A.J., Busso, E.P., Matthews, F.L. and Qiu, Y. (1999). Predicting Progressive Delamination of Composite Material Specimens via Interface Elements, Mechanics of Advanced Materials and Structures, 6(4): 301-317.
• McCarthy, C.T., McCarthy, M.A. and Lawlor, V.P. (2005). Progressive Damage Analysis of Multi-Bolt Composite Joints with Variable Bolt-Hole Clearances, Composites Part B. 36(4): 290-305.[CrossRef]
• Basu, S., Waas, A.M. and Ambur, D.R. (2007). Prediction of Progressive Failure in Multidirectional Composite Laminated Panels, International Journal of Solids and Structures, 44(9): 2648-2676.[CrossRef][Web of Science]
• Goswami, S. (2005). A Finite Element Investigation on Progressive Failure Analysis of Composite Bolted Joints Under Thermal Environment, Journal of Reinforced Plastics and Composites, 24(2): 161-171.[Abstract]
• Riccio, A. (2005). Effects of Geometrical and Material Features on Damage Onset and Propagation in Single-lap Bolted Composite Joints under Tensile Load: Part II - Numerical Studies, Journal of Composite Materials, 39(23): 2091-2112.[Abstract]
• McGregor, C.J., Vaziri, R., Poursartip, A. and Xiao, X. (2007). Simulation of Progressive Damage Development in Braided Composite Tubes under Axial Compression, Composites Part A: Applied Science and Manufacturing, 38(11): 2247-2259.[CrossRef][Web of Science]
• Tao, J. and Sun, C.T. (1998). Influence of Ply Orientation on Delamination in Composite Laminates, Journal of Composite Materials, 32(21): 1933-1947.[Abstract]
• Kweon, J.H., Shin, S.Y. and Choi, J.H. (2007). A Two-Dimensional Progressive Failure Analysis of Pinned Joints in Unidirectional-Fabric Laminated Composites, Journal of Composite Materials, 41(17): 2083-2104.[Abstract/Free Full Text]
• Wolford, G.F. and Hyer, M.W. (2005). Failure Initiation and Progression in Internally-Pressurized Elliptical Composite Cylinders, Mechanics of Advanced Materials and Structures, 12(6): 437-455.[CrossRef][Web of Science]
• Reddy, Y.S. and Reddy, J.N. (1993). Three-Dimensional Finite Element Progressive Failure Analysis of Composite Laminates under Axial Extension, Journal of Composites Technology and Research, 15(2): 73-87.
• Krueger, R. and O'Brien, T.K. (2001). A Shell/3D Modeling Technique for the Analysis of Delaminated Composite Laminates, Composites Part A: Applied Science and Manufacturing, 32(1): 25-44.[CrossRef][Web of Science]
• Robbins Jr, D.H. and Reddy, J.N. (2008). Adaptive Hierarchical Kinematics in Modeling Progressive Damage and Global Failure in Fiber-reinforced Composite Laminates, Journal of Composite Materials, 42(2): 143-172.[Abstract/Free Full Text]
• Tay, T.E. (2003). Characterization and Analysis of Delamination Fracture in Composites - an Overview of Developments from 1990 to 2001. Applied Mechanics Reviews, 56(1): 1-31.[CrossRef]
• Krueger, R. (2004). Virtual Crack Closure Technique: History, Approach and Applications, Applied Mechanics Reviews, 57(2): 109-43.[CrossRef]
• Brewer, J.C. and Lagace, P.L. (1988). Quadratic Stress Criterion for Initiation of Delamination, Journal of Composite Materials, 22(12): 1141-1155.[Abstract]
• Hou, J.P., Petrinic, N., Ruiz, C. and Hallett, S.R. (2000). Prediction of Impact Damage in Composite Plates, Composites Science and Technology, 60(2): 273-281.[CrossRef][Web of Science]
• Camanho, P.P., Davila, C.G., Pinho, S.T., Iannucci, L. and Robinson, P. (2006). Prediction of In Situ Strengths and Matrix Cracking in Composites under Transverse Tension and In-Plane Shear, Composites Part A. 37(2): 165-176.[CrossRef]
• Dugdale, D.S. (1960). Yielding of Steel Sheets Containing Slits, Journal of Mechanics and Physics of Solids, 8(2): 100-104.[CrossRef]
• Barenblatt, G.I. (1962). Mathematical Theory of Equilibrium Cracks in Brittle Failure, Advances in Applied Mechanics, 7: 55-129.[CrossRef]
• Camanho, P.P., Davila, C.G. and Ambur, D.R. (2001). Numerical Simulation of Delamination Growth in Composite Materials, NASA-TP-211041.
• Cui, W. and Wisnom, M.R. (1993). A Combined Stress-Based and Fracture-Mechanics-Based Model for Predicting Delamination in Composites, Composites, 24(6): 467-474.[CrossRef][Web of Science]
• Wisnom, M.R. (1996). Modelling the Effect of Cracks on Interlaminar Shear Strength, Composites Part A, 27(1): 17-24.[CrossRef]
• Petrossian, Z. and Wisnom, M.R. (1998). Prediction of Delamination Initiation and Growth from Discontinuous Plies Using Interface Elements, Composites Part A. 29(5-6): 503-515.[CrossRef]
• Wisnom, M.R. and Chang, F.K. (2000). Modelling of Splitting and Delamination in Notched Cross-Ply Laminates, Composites Science and Technology, 60(15): 2849-2856.[CrossRef][Web of Science]
• Hallett, S.R. and Wisnom, M.R. (2006). Numerical Investigation of Progressive Damage and the Effect of Layup in Notched Tensile Tests, Journal of Composite Materials, 40(14): 1229-1245.[Abstract/Free Full Text]
• Borg, R., Nilsson, L. and Simonsson, K. (2001). Simulation of Delamination in Fiber Composites with a Discrete Cohesive Failure Model, Composites Science and Technology, 61(5): 667-677.[CrossRef][Web of Science]
• Meo, M. and Thieulot, E. (2005). Delamination Modeling in a Double Cantilever Beam, Composite Structures, 71(3-4): 429-434.[CrossRef][Web of Science]
• Xie, D. and Waas, A.M. (2006). Discrete Cohesive Zone Model for Mixed-Mode Fracture Using Finite Element Analysis, Engineering Fracture Mechanics, 73(13): 1783-1796.[CrossRef][Web of Science]
• Crisfield, M.A., Mi, Y., Davies, G.A.O. and Hellweg, H.B. (1997). Finite Element Methods and the Progressive Failure Modelling of Composite Structures, In: Owen, D.E.J., Onate, E. and Hinton, E. (eds). Computational Plasticity, Barcelona, 1: 239-254.
• Hallett, S.R. and Wisnom, M.R. (2006). Experimental Investigation of Progressive Damage and the Effect of Layup in Notched Tensile Tests, Journal of Composite Materials, 40(2): 119-141.[Abstract/Free Full Text]
• Chen, J. and New, A. (2001). Application of Decohesive Model with Mixed Damage Scale in Fracture Analysis of Composite Materials, Fatigue and Fracture of Engineering Materials and Structures, 24(11): 761-769.[CrossRef]
• Alfano, G. and Crisfield, M.A. (2001). Finite Element Interface Models for the Delamination Analysis of Laminated Composites: Mechanical and Computational Issues, International Journal for Numerical Methods in Engineering, 50(7): 1701-1736.[CrossRef][Web of Science]
• Tenchev, R.T. and Falzon, B.G. (2006). A Pseudo-Transient Solution Strategy for the Analysis of Delamination by Means of Interface Elements, Finite Elements in Analysis and Design, 42(8-9): 698-708.[CrossRef][Web of Science]
• Schellekens, J.C.J. and Borst, R. (1991). Application of Linear and Nonlinear Fracture Mechanics Options to Free Edge Delamination in Laminated Composites, Heron, 36(2): 37-48.
• Schellekens, J.C.J. and Borst, R. (1993). On the Integration of Interface Elements, International Journal for Numerical Methods in Engineering, 36(1): 43-66.[Medline] [Order article via Infotrieve]
• Schellekens, J.C.J. and Borst, R. (1992). Simulation of Free Edge Delamination via Finite Element Techniques, In: Ladeveze, P. and Zienkiewicz, O.C. (eds). New Advances in Computational Structural Mechanics, pp. 397-410, Elsevier, London and New York.
• Schellekens, J.C.J. and Borst, R. (1994). Free Edge Delamination in Carbon-Epoxy Laminates: a Novel Numerical/Experimental Approach, Composite Structures, 28(4): 357-373.[CrossRef][Web of Science]
• Schellekens, J.C.J. and Borst, R. (1991). Numerical Simulation of Free Edge Delamination in Graphite Epoxy Specimen under Uniaxial Tension, Composite Structures, Elsevier, London and New York.
• Schellenkens, J.C.J. and Borst, R. (1993). A Non-Linear Finite Element Approach for the Analysis of Mode-I Free Edge Delamination in Composites, International Journal of Solids and Structures, 30(9): 1239-1253.[CrossRef][Web of Science]
• Camanho, P.P., Davila, C.G. and de Moura, M.F. (2003). Numerical Simulation of Mixed-Mode Progressive Delamination in Composite Materials, Journal of Composite Materials, 37(16): 1415-1438.[Abstract]
• Camanho, P.P., Davila, C.G. and Pinho, S.T. (2004). Fracture Analysis of Composite Co-Cured Structural Joints Using Decohesion Elements, Fatigue and Fracture of Engineering Materials and Structures, 27(9): 745-757.
• Allix, O. and Blanchard, L. (2006). Mesomodeling of Delamination: Towards Industrial Applications, Composites Science and Technology, 66(6): 731-744.[CrossRef][Web of Science]
• Daudeville, L., Allix, O. and Ladeveze, P. (1995). Delamination Analysis by Damage Mechanics: Some Applications, Composites Engineering, 5(1): 17-24.[CrossRef][Web of Science]
• Daudeville, L. and Ladeveze, P. (1993). A Damage Mechanics Tool for Laminate Delamination, Composite Structures, 25(1): 547-555.[CrossRef][Web of Science]
• Benzeggagh, M.L. and Kenane, M. (1996). Measurement of Mixed-Mode Delamination Fracture Toughness of Unidirectional Glass/Epoxy Composites with Mixed-Mode Bending Apparatus, Composites Science and Technology, 56(4): 439-449.[CrossRef][Web of Science]
• Maimí, P., Camanho, P.P., Mayugo, J.A. and Davila, C.G. (2007). A Continuum Damage Model for Composite Laminates: Part I-Constitutive Model, Mechanics of Materials, 39(10): 897-908.[CrossRef][Web of Science]
• Maimí, P., Camanho, P.P., Mayugo, J.A. and Davila, C.G. (2007). A Continuum Damage Model for Composite Laminates: Part II-Computational Implementation and Validation, Mechanics of Materials, 39(10): 909-919.[CrossRef][Web of Science]
• Lopes, C.S., Camanho, P.P., Gürdal, Z. and Tatting, B.F. (2007). Progressive Failure Analysis of Tow-Placed, Variable-Stiffness Composite Panels, International Journal of Solids and Structures, 44(25-26): 8493-8516.[CrossRef][Web of Science]
• de Moura, M., Goncalves, J.P.M., Marques, A.T. and de Castro, P. (1997). Modeling Compression Failure after Low Velocity Impact on Laminated Composites Using Interface Elements, Journal of Composite Materials, 31(15): 1462-1470.[Abstract]
• Goncalves, J.P., de Moura, M., de Castro, P. and Marques, A.T. (2000). Interface Element Including Point-to-Surface Constraints for Three-Dimensional Problems with Damage Propagation, Engineering Computations, 17(1): 28-47.[CrossRef][Web of Science]
• Camanho, P.P. and Matthews, F.L. (1997). Stress Analysis and Strength Prediction of Mechanically Fastened Joints in FRP: a Review, Composites Part A., 28(6): 529-547.[CrossRef]
• Tserpes, K.I., Papanikos, P. and Kermanidis, T. (2001). A Three-Dimensional Progressive Model for Bolted Joints in Composite Laminates Subjected to Tensile Loading, Fatigue and Fracture of Engineering Materials and Structures, 24(10): 663-675.[CrossRef]
• Chang, F.K. and Chang, K.Y. (1987). A Progressive Damage Model for Laminated Composites Containing Stress Concentrations, Journal of Composite Materials, 21(9): 834-855.[Abstract]
• Riccio, A. and Marciano, L. (2005). Effects of Geometrical and Material Features on Damage Onset and Propagation in Single-lap Bolted Composite Joints under Tensile Load: Part I - Experimental Studies, Journal of Composite Materials, 39(23): 2071-2090.[Abstract]
• Eisenmann, J.R. and Rousseau, C.Q. (2004). IBOLT: A Composite Bolted Joint Static Strength Prediction Tool, Joining and Repair of Composite Structures, ASTM STP 1455, K.T. Kedward and H. Kim (eds), ASTM International, West Conshohocken, PA, pp. 161-181.
• Liu, X. and Wang, G. (2007). Progressive Failure Analysis of Bonded Composite Repairs, Composite Structures, 81(3): 331-340.[CrossRef][Web of Science]
• Ambur, D.R., Jaunky, N. and Hilburger, M. (2004). Progressive Failure Analyses of Compression-Loaded Composite Curved Panels with and without Cutouts, Composite Structures, 65(2): 143-155.[CrossRef][Web of Science]
• Tang, X. and Whitcomb, J.D. (2003). Progressive Failure Behaviors of 2D Woven Composites, Journal of Composite Materials, 37(14): 1239-1259.[Abstract]
• Hochard, C., Lahellec, N. and Bordreuil, C. (2007). A Ply Scale Non-Local Fibre Rupture Criterion for CFRP Woven Ply Laminated Structures, Composite Structures, 80(3): 321-326.[CrossRef][Web of Science]
• Gorbatikh, L.I.D., Lomov, S. and Verpoest, I. (2007). On Modeling of Damage Evolution in Textile Composites on Meso-Level via Property Degradation Approach, Composites Part A: Applied Science and Manufacturing, 38(12): 2433-2442.[CrossRef][Web of Science]
• Zhao, L.G., Warrior, N.A. and Long, A.C. (2006). Finite Element Modelling of Damage Progression in Non-Crimp Fabric Reinforced Composites, Composites Science and Technology, 66(1): 36-50.[CrossRef][Web of Science]
• Costa, J., Turon, A., Trias, D., Blanco, N. and Mayugo, J.A. (2005). A Progressive Damage Model for Unidirectional Fibre-Reinforced Composites Based on Fibre Fragmentation, Part II: Stiffness Reduction in Environment Sensitive Fibres under Fatigue, Composites Science and Technology, 65(14): 2269-2275.[CrossRef][Web of Science]
• Tay, T.E., Liu, G. and Tan, V.B.C. (2006). Damage Progression in Open-hole Tension Laminates by the SIFT-EFM Approach, Journal of Composite Materials, 40(11): 971-992.[Abstract/Free Full Text]
• Tay, T.E., Tan, S.H.N., Tan, V.B.C. and Gosse, J.H. (2005). Damage Progression by the Element-Failure Method, (EFM) and Strain Invariant Failure Theory (SIFT). Composites Science and Technology, 65(6): 935-944.[CrossRef][Web of Science]
• Tay, T.E., Tan, V.B.C. and Deng, M. (2003). Element-Failure Concepts for Dynamic Fracture and Delamination in Low-Velocity Impact of Composites, International Journal of Solids and Structures, 40(3): 555-571.[CrossRef][Web of Science]
• Tay, T.E., Tan, V.B.C. and Tan, S.H.N. (2005). Element-Failure: An Alternative to Material Property Degradation Method for Progressive Damage in Composite Structures, Journal of Composite Materials, 39(18): 1659-1675.[Abstract]
• Beissel, S.R., Johnson, G.R. and Popelar, C.H. (1998). An Element-Failure Algorithm for Dynamic Crack Propagation in General Directions, Engineering Fracture Mechanics, 61(3-4): 407-425.[CrossRef][Web of Science]
• Tay, T.E. and Lim, E.H. (1996). Analysis of Composite Laminates with Transverse Cracks, Composite Structures, 34(4): 419-426.[CrossRef][Web of Science]
• Coats, T.W. and Harris, C.E. (1998). A Progressive Damage Methodology for Residual Strength Predictions of Notched Composite Panels, NASA TM-1998-207646.
• Shen, F., Lee, K.H. and Tay, T.E. (2001). Modeling Delamination Growth in Laminated Composites, Composites Science and Technology, 61(9): 1239-1251.[CrossRef][Web of Science]
• Abaqus Analysis User's Manual, Version 6.7 (2007).

This version was published on September 1, 2008

Journal of Composite Materials, Vol. 42, No. 18, 1921-1966 (2008)
DOI: 10.1177/0021998308093912


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