Multi-scale modeling of fatigue crack propagation applied to random sequence of clustered loading

Abstract Fatigue crack propagation in marine structures is obviously governed by mechanics of the considerably different four levels of multi-scale problems. Problems of structural response to environmental loads have length scale of several hundred meters, whereas possible detectable size of cracks from initial defects in a weld is of the order of millimeters. Once a fatigue crack initiates, crack tip plasticity is of the order of several grain sizes, while the resulting fatigue crack growth in each load cycle is of the order of nanometers. In our previous work, the first author and their associates have developed the so-called CP-System, which can treat the first two multi-level problems as an integrated system. Furthermore, we have incorporated the third level of mechanics by using the stress intensity range corresponding to the repeated tensile plastic deformation ahead of the crack tip. In the present paper, we shall discuss a more rational integral equation-based formulation in order to integrate the third and fourth levels of micro-mechanics to the first two levels of continuum mechanics. The method is then applied to fatigue crack propagation under the effects of random sequence of clustered loading. As an example of the random sequence of clustered load, we shall use the so-called “storm model”. In the crack propagation simulation, we have to take into account of the plastic wake on the crack surfaces, whose thicknesses are influenced by the material parameters involved in the crack growth model. These parameters are first identified by the fatigue tests under combined constant and random loading using a CT specimen. Then, fatigue crack growth is investigated by numerical simulation and fatigue tests for various random sequences of clustered loading. The experimental and numerical results agree quite well with each other, and fatigue crack propagation is found to be considerably retarded under random sequence loading, so that the conventional equivalent stress approach may provide rather conservative results to the real seaway loading.

[1]  Masahiro Toyosada,et al.  Fatigue crack propagation for a through thickness crack: a crack propagation law considering cyclic plasticity near the crack tip , 2004 .

[2]  Y. Sumi,et al.  On crack branching and curving in a finite body , 1983 .

[3]  Yoichi Sumi,et al.  Simulation-based fatigue crack management of ship structural details applied to longitudinal and transverse connections , 2006 .

[4]  Yang Mu,et al.  Development of an Automatic Quadrilateral Mesh Generator for the Simulation of Curved Crack Growth , 1999 .

[5]  Yoichi Sumi,et al.  A finite-element simulation method for a system of growing cracks in a heterogeneous material , 1998 .

[6]  J. Rice,et al.  Slightly curved or kinked cracks , 1980 .

[7]  Masahiro Toyosada,et al.  Fatigue life assessment for welded structures without initial defects: an algorithm for predicting fatigue crack growth from a sound site , 2004 .

[8]  Yoichi Sumi,et al.  Fatigue crack propagation and computational remaining life assessment of ship structures , 1998 .

[9]  G. I. Barenblatt THE MATHEMATICAL THEORY OF EQUILIBRIUM CRACKS IN BRITTLE FRACTURE , 1962 .

[10]  Yoichi Sumi,et al.  Computational prediction of fatigue crack paths in ship structural details , 2005 .

[11]  Yoichi Sumi,et al.  A computational approach for fatigue crack propagation in ship structures under random sequence of clustered loading , 2008 .

[12]  Y Tomita,et al.  STOCHASTIC CHARACTERISTIC OF LONG TERM DISTRIBUTION OF WAVE-INDUCED LOADING AND SIMULATION METHOD FOR FATIGUE STRENGTH ANALYSIS OF SHIP STRUCTURAL MEMBER (3RD REPORT: FATIGUE TEST RESULT UNDER VARIABLE STRESS AMPLITUDE ACCORDING TO "STORM MODEL") , 1995 .

[13]  J. Newman A crack-closure model for predicting fatigue crack growth under aircraft spectrum loading , 1981 .

[14]  Masanori Kawahara,et al.  An Expression of Fatigue Crack Propagation Rates under Wide Ranged Stress Ratios , 1983 .

[15]  R. Salganik,et al.  Brittle fracture of solids with arbitrary cracks , 1974 .

[16]  Yoichi Sumi,et al.  A note on the first order perturbation solution of a straight crack with slightly branched and curved extension under a general geometric and loading condition , 1986 .

[17]  Yoshiyuki Yamamoto,et al.  Determination of stress intensity factors in cracked plates by the finite element method , 1973 .

[18]  D. S. Dugdale Yielding of steel sheets containing slits , 1960 .