A new multi-axial fatigue model for fiber-reinforced composite laminates based on Puck’s criterion is proposed in this article. In the fatigue model, fatigue master curves from the ATM are used to determine the uniaxial ply fatigue strengths and the multi-axial fatigue failure is then determined by Puck’s criterion with the fatigue strengths at the ply level. The fatigue master curves from ATM are generated with limited uniaxial fatigue tests and can be applied to fatigue loading conditions with various frequencies and stress ratios. Both uniaxial and multi-axial S-N curves can be derived from thefatigue model. Fatigue failure envelopes are also generated from the model to better interpret the multi-axial fatigue failure in multi-axial stress spaces. The proposed multi-axial fatigue model is based on ply-level predictions, but it can beextended to laminate-level predictions with the CLT or numerical methods such as the FEM. Multi-axial fatigue failures caused by either local or global multi-axiality can be predicted by the model. Both uniaxial and biaxial fatigue experimentswere carried out to provide test data for establishing and validating the proposed fatigue model. The application oftheproposed multi-axial fatigue model is demonstrated with predictions of S-N curves and fatigue failure envelopes of unidirectional laminates and multi-directional laminates with typical lay-up configurations. The predictions from the proposed fatigue model are also compared with various experimental results and reasonably good agreement is observed.
FawazZEllyinF. Fatigue failure model for fiber-reinforced materials under general loading conditions. JCompos Mater1994; 28: 1432–1451.
3.
FawazZEllyinF. A new methodology for the prediction of fatigue failure in multidirectional fiber-reinforced laminates. Compos Sci Technol1995; 53: 47–55.
HuangZM. Fatigue life prediction of a woven fabric composite subjected to biaxial cyclic loads. Compos Part A-Appl S2002; 33: 253–266.
6.
GudeMHufenbachWKochIProtzR. Fatigue failure criteria and degradation rules for composites under multiaxial loadings. Mech Compos Mater2006; 42: 443–450.
7.
KawakamiHFujiiTJMoritaY. Fatigue degradation and life prediction of glass fabric polymer composite under tension/torsion biaxial loading. J Reinf Plast Comp1996; 15: 183–195.
8.
Van PaepegemWDegrieckJ. Modelling damage and permanent strain in fiber-reinforced composites under in-plane fatigue loading. Compos Sci Technol2003; 63: 677–694.
9.
KawaiM. A phenomenological model for off-axis fatigue behavior of unidirectional polymer matrix composites under different stress ratios. Compos Part A-Appl S2004; 35: 955–963.
10.
PassipoularidisVAPhilippidisTP. Strength degradation due to fatigue in fiber dominated glass/epoxy composites: a statistical approach. J Compos Mater2009; 43: 997–1013.
11.
ShokriehMMLessardLB. Multiaxial fatigue behaviour of unidirectional plies based on uniaxial fatigue experiments – I. Modelling. Int J Fatigue1997; 19: 201–207.
12.
ShokriehMMLessardLB. Multiaxial fatigue behaviour of unidirectional plies based on uniaxial fatigue experiments – II. Experimental evaluation. Int J Fatigue1997; 19: 209–217.
13.
ShokriehMMLessardLB. Progressive fatigue damage modeling of composite materials, Part I: Modeling. J Compos Mater2000; 34: 1056–1080.
14.
ShokriehMMLessardLB. Progressive fatigue damage modeling of composite materials, Part II: Material characterization and model verification. JCompos Mater2000; 34: 1081–1116.
15.
DiaoXLessardLBShokriehMM. Statistical model for multiaxial fatigue behavior of unidirectional plies. Compos Sci Technol1999; 59: 2025–2035.
16.
LiuYMahadevanS. Probabilistic fatigue life prediction of multidirectional composite laminates. Compos Struct2005; 69: 11–19.
17.
QuaresiminMSusmelLTalrejaR. Fatigue behaviour and life assessment of composite laminates under multiaxial loadings. Int J Fatigue2010; 32: 2–16.
18.
PassipoularidisVAPhilippidisTPBrondstedP. Fatigue life prediction in composites using progressive damage modeling under block and spectrum loading. Int J Fatigue2011; 33: 132–144.
19.
MiyanoYNakadaMCaiH. Formulation of long-term creep and fatigue strengths of polymer composites based on accelerated testing methodology. J Compos Mater2008; 42: 1897–1919.
20.
PuckASchürmannH. Failure analysis of FRP laminates by means of physically based phenomenological models. Compos Sci Technol1998; 58: 1045–1067.
21.
PuckASchürmannH. Failure analysis of FRP laminates by means of physically based phenomenological models. Compos Sci Technol2002; 62: 1633–1662.
22.
PuckAKoppJKnopsM. Guidelines for the determination of the parameters in Puck’s action plane strength criterion. Compos Sci Technol2002; 62: 371–378.
23.
TsaiSW. Theory of composites design. In: TsaiSW (eds). Strength & life of composites2008, CA, USA: Stanford University, A9-8–A9-17.
24.
EN ISO 527-4. Plastics – Determination of tensile properties – Part 4: test conditions for isotropic and orthotropic fiber-reinforced plastic composites1997, Geneve, Switzerland: International Organization for Standardization.
25.
ASTM D3410/D3410M. Standard test method for compressive properties of polymer matrix composite materials with unsupported gage section by shear loading2003, Philadelphia, PA, USA: American Society for Testing and Materials.
26.
SodenPDHintonMJKaddourAS. Lamina properties, lay-up configurations and loading conditions for a range of fiber-reinforced composite laminates. Compos Sci Technol1998; 58: 1011–1022.
27.
SmitsAVan HemelrijckDPhilippidisTPCardonA. Design of a cruciform specimen for biaxial testing of fiber reinforced composite laminates. Compos Sci Technol2006; 66: 964–975.
28.
LamkanfiEVan PaepegemWDegrieckJRamaultCMakrisAVan HemelrijckD. Strain distribution in cruciform specimens subjected to biaxial loading conditions. Part 1: Two-dimensional vs. three-dimensional finite element model. Polym Test2010; 29: 7–13.
29.
LamkanfiEVan PaepegemWDegrieckJRamaultCMakrisAVan HemelrijckD. Strain distribution in cruciform specimens subjected to biaxial loading conditions. Part 2: Influence of geometrical discontinuities. Polym Test2010; 29: 132–138.
30.
MakrisAVandenberghTRamaultCVan HemelrijckDLamkanfiEVan PaepegemW. Shape optimisation of a biaxially loaded cruciform specimen. Polym Test2010; 29: 216–223.
31.
LekouDJ. Test Results of Benchmark Static Tests on UD and MD Coupons, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG1_R007,http://www.wmc.eu/public_docs/10154_000.pdf (2003, accessed 16 July 2011).
32.
LekouDJ. Test Results of CA Fatigue Tests on UD Coupons, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG1_R011, http://www.wmc.eu/public_docs/10197_001.pdf (2004, accessed 16 July 2011).
33.
PhilippidisTPVassilopoulosAPAssimakopoulouTTPassipoularidisV. Static and Fatigue Tests of OPTIMAT UD Coupons: Benchmark Tests, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG2_R012, http://www.wmc.eu/public_docs/10120_000.pdf (2003, accessed 16 July 2011).
34.
PhilippidisTPPassipoularidisVAAssimakopoulouTTAntoniouAE. Fatigue Tests in the Fiber Direction ofUD OB Standard Specimen: Main Test Phase I, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG1_R013,http://www.wmc.eu/public_docs/10219_001.pdf (2006, accessed 16 July 2011).
35.
PhilippidisTPAssimakopoulouTTAntoniouAEPassipoularidisVA. Fatigue Tests on OB Standard Coupons at 90°: Main Test Phase I, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG2_R021, http://www.wmc.eu/public_docs/10253_000.pdf (2005, accessed 16 July 2011).
36.
PhilippidisTPAntoniouAEAssimakopoulouTTPassipoularidisVA. Static Tests on the Standard OB UD and MD Off-axis Coupons: Main Test Phase I, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG2_R022,http://www.wmc.eu/public_docs/10254_000.pdf (2005, accessed 15 July 2011).
37.
PhilippidisTPAntoniouAEAssimakopoulouTTPassipoularidisVA. Fatigue Tests on OB Unidirectional & Multidirectional Off-axis Coupons: Main Test Phase I, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG2_R030, http://www.wmc.eu/public_docs/10350_000.pdf (2006, accessed 15 July 2011).
38.
PhilippidisTPAssimakopoulouTTPassipoularidisVAAntoniouAE. Static and Fatigue Tests on ISO Standard ±45° Coupons: Main Test Phase I, OPTIMAT BLADES, ENK6-CT2001-00552, OB_TG2_R020,http://www.wmc.eu/public_docs/10207_000.pdf (2004, accessed 15 July 2011).
