Fatigue behaviour of composite tubes under multiaxial loading

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An Energy-Based Fatigue Approach for Composites Combining Failure Mechanisms, Strength and Stiffness Degradation Abstract H Krüger *, R Rolfes, E Jansen Institute of Structural Analysis, Leibniz Universität Hannover, Appelstrasse 9a, 30167 Hanover, Germany In order to improve the fatigue analysis of large structures made of fibre-reinforced plastics a physically motivated fatigue assessment procedure is investigated. In contrast to the analysis procedure usually applied the novel model consists of a layer-wise continuum mechanics approach on macro scale and considers different failure modes. The approach subdivides into two analysis parts: discontinuous quasi-static degradation and continuous fatigue degradation. The discontinuous approach is based on a well-known failure mode theory. The continuous degradation approach makes use of an energy-based hypothesis, which combines strength and stiffness degradation. With the present approach stress redistributions and sequence effects can be investigated. Keywords: Fatigue modelling, reinforced composite, damage mechanics, layer-based approach, degradation, sequence effects 1. Introduction For evaluating the fatigue behaviour of structures made of fibre-reinforced plastics (FRPs) it is common practice to use SN-curves on laminate scale in combination with the simple and linear damage accumulation rule according to Palmgren and Miner [2]. This is done even though this rule has been developed for metals, which are in contrast to FRPs isotropic and ductile and have only a single failure mode. Additionally stress redistributions between layers and within the structure can occur since the material properties of FRPs, stiffness and strength degrade depending on the loading and the development of tolerable cracks. This causes a non-linear damage accumulation and shows that Palmgren´s and Miner´s rule is not valid for FRPs. Finally, the whole procedure is not really suitable, it is purely empirical and does not represent the complex failure behaviour of FRPs. Furthermore, the procedure is also costly to apply, because due to this improper approach each laminate set-up and loading situation needs to be experimentally investigated. Due to these shortcomings there has been a lot of research activity in the field of modelling the fatigue behaviour of FRPs in the last decades. The models investigated can be classified in three groups: The first group is built by the so-called “fatigue life concepts” which are, similar to the Palmgren and Miner rule, linear and of purely empirical nature [3,4]. The second group comprises the phenomenological models [5,6,7], which are based on empirically determined evolution laws concerning the stiffness or the strength of laminates. Progressive damage models [8,9], the third group, * Corresponding author. Tel: +49 (0)511 762 2266; fax: +49 (0)511 762 2366 E-mail address: H.Krueger@isd.uni-hannover.de
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Fiifth IInternatiionall Conference
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A Hosoi, K Takamura, N Sato, H Kawa
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Fatigue behaviour of composite tube
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M Quaresimin, R Talreja / Fatigue b
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F Schmidt, P Horst / Damage mechani
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Abstract An effective method for P-
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Where, ˆ, , ˆ0 deviator [3]. D Gu
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Constant Fatigue Life Diagrams for
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M Kawai, Y Matuda, etc. / Constant
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plies. K Ogi, R Kitahara, etc. / Ef
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where 1 K Ogi, R Kitahara, etc. / E
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J Lambert, A R Chambers, etc. / Fat
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Cyclic interlaminar crack growth in
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S Stelzer, G Pinter, etc. / Cyclic
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Effect of Water Uptake on the Fatig
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5. Conclusions Effect of Water Upta
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Experimental analysis and modelling
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P Nimdum, J Renard. / Experimental
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4. FEM analysis 4.1 Configuration P
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References P Nimdum, J Renard. / Ex
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F Schmidt, T J Adam, P Horst. / Fat
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Abstract Fatigue Damage initiation
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B Esmaeillou, P Fereirra, V Belleng
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F Q Wu, W X Yao. / Fatigue life pre
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Composite Glass/Epoxy [1] Graphite/
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2. Experimental procedures C S Shin
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C S Shin, S W Yang. / Post-Impact F
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Delamination detection in CFRP lami
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N Hu, Y L Liu, H Fukunaga, Y Li. /
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5. Conclusion N Hu, Y L Liu, H Fuku
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S J Zhu, M Kichise, A Usuki, M Kato
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Fatigue Behavior of Unidirectional
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2.3 Fatigue Testing H Katogi, Y Shi
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H Katogi, Y Shimamura, K Tohgo, T F
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J K Lee, S P Lee, J H Byun. / An ev
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M-H R Jen, Y-C Sung, etc. / Fabrica
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Fatigue and Fracture of Elastomeric
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C Bathias, S Y Dong. / Fatigue and
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fatigue conditions. C Bathias, S Y
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Correlation between crack propagati
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V Trappe, S Günzel / Correlation b
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Thermal fatigue of AX41 magnesium a
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Z Drozd, etc. / Thermal fatigue of
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4. Discussion Z Drozd, etc. / Therm
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Z Drozd, etc. / Thermal fatigue of
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Abstract Fatigue behaviour of woven
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Damage in thermoplastic composite s
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Abstract Residual life predictions
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H Wu, A Imad, N Benseddi / Residual
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