论文信息 - Mixed Mode (I+II) Fatigue Crack Growth of Long Term Operating Bridge Steel☆

Mixed Mode (I+II) Fatigue Crack Growth of Long Term Operating Bridge Steel☆

Abstract The structural components from structures such as bridge members are subjected to a long operating period of time. The problem of fatigue cracks is more interesting in existing bridge structures with existing cracks. In case of the structures erected at the turn of the 19 th and 20 th centuries, the cracks are natural elements of the old steel metallic structures. The uniaxial fatigue crack growth description lead us often to significant errors in predicting of a residual lifetime. As a good example, it can be a residual lifetime of the riveted joints in such a type of structures. On the other hand, the 19 th century structures were erected with puddled iron or low carbon mild rimmed steel. The experimental results [1,2] obtained by authors, have shown that the fatigue cracks grow much faster than its modern equivalent. This phenomenon is supported by microstructural degradation processes [2] . In this paper some examples of degenerated microstructures have been presented. In order to fill a lack in experimental data in the literature, the results of a mixed mode (I+II) fatigue crack growth have been presented and discussed within the background of Fracture Mechanics models. All the results have been implemented into the Abaqus environment.

[1] Abílio M. P. De Jesus,et al. Strain-life and crack propagation fatigue data from several Portuguese old metallic riveted bridges , 2011 .

[2] José A.F.O. Correia,et al. Fatigue crack propagation behavior of old puddle iron including crack closure effects , 2016 .

[3] G. C. Sih,et al. Discussion: ‘Some observations on Sih's strain energy density approach for fracture prediction’, by I. Finnie and H. O. Weiss , 1974 .

[4] F. Erdogan,et al. On the Crack Extension in Plates Under Plane Loading and Transverse Shear , 1963 .

[5] G. Sih. Mechanics of fracture initiation and propagation , 1990 .

[6] T. K. Hellen,et al. The calculation of stress intensity factors for combined tensile and shear loading , 1975 .

[7] Jože Flašker,et al. Evaluation of stress intensity factors using finite elements , 2002 .

[8] Miroslaw Bocian,et al. The mechanical properties and the microstructural degradation effect in an old low carbon steels after 100-years operating time , 2015 .

[9] Alain Nussbaumer,et al. Assessment of existing steel structures. A guideline for estimation of the remaining fatigue life , 2007 .

[10] L. P. Borrego,et al. Mixed-mode fatigue crack growth behaviour in aluminium alloy , 2006 .

[11] Keisuke Tanaka,et al. Fatigue crack propagation from a crack inclined to the cyclic tensile axis , 1974 .

[12] S. Suresh. Fatigue of materials , 1991 .

[13] Tobias Larsson,et al. Fatigue assessment of riveted bridges , 2009 .