Fatigue Crack Propagation in Biaxial Stress Fields

Tanaka, Keisuke; Hoshide, Toshihiko; Yamada, Akira; Taira, Shuji

doi:10.1111/j.1460-2695.1979.tb01354.x

Cited by 52 publications

(25 citation statements)

References 15 publications

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“…In the author's opinion for each ductile metal or alloy there exists a unique relation between ΔCTOD and da / dN as long as the static fracture does not dominate the processes in front of the crack tip. There are materials, where there exists a simple linear relation between da / dN and ΔCTOD as shown in examples in this paper; however, there may be materials with a progressive increase of da / dN with increasing ΔCTOD, 55 the crack tip blunting angle and the ratio of the part of CTOD, which generates the new fracture surface and the part of CTOD, which is caused by a deformation of the crack flanks in the vicinity of the crack tip may cause a deviation from the linear relation between ΔCTOD and da / dN .…”

Section: Discussionmentioning

confidence: 87%

On the mechanism of fatigue crack propagation in ductile metallic materials

Pippan

Zelger

Gach

et al. 2010

Fatigue &Amp; Fracture of Engineering Materials &Amp; Structures

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A B S T R A C T An overview of our research performed during the last 15 years is presented to improve the understanding of fatigue crack propagation mechanisms. The focus is devoted to ductile metals and the material separation process at low and intermedial crack propagation rates. The effect of environment, short cracks, small-scale yielding as well as large-scale yielding are considered. It will be shown that the dominant intrinsic propagation mechanism in ductile metallic materials is the formation of new surface due to blunting and the resharpening during unloading. This process is affected by the environment, however, not by the length of the crack and it is independent of large-or small-scale yielding.a = crack length c = Manson-Coffin exponent CTOD = crack tip opening displacement da/dN = fatigue crack propagation rate K max , K min = maximum and minimum stress intensity factor N f = number of cycles to failure R = stress ratio K min /K max CTOD = cyclic crack tip opening displacement ε pl = plastic strain range J = cyclic J-integral J eff = effective cyclic J-integral K = stress intensity rang W e = elastic component of the remote strain energy density range W p = plastic component of the remote strain energy density range σ y = yield stress Figure 1 shows the fatigue crack propagation behaviour of austenitic steel. Such fatigue crack propagation rate, da/dN , versus stress intensity range, K, curves are typical for ductile metals. The fatigue crack propagation behaviour of such materials is characterized by: a steep drop of the crack propagation rate at the threshold of stress intensity range, K th , an extended Paris regime with a Correspondence: R. Pippan. I N T R O D U C T I O N

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Section: Discussionmentioning

confidence: 87%

On the mechanism of fatigue crack propagation in ductile metallic materials

Pippan

Zelger

Gach

et al. 2010

Fatigue &Amp; Fracture of Engineering Materials &Amp; Structures

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“…Therefore, a stress biaxiality factor in a pipe wall λ= σ ln /σ hp can be more and less than zero; for the majority of spherical tank wall points (for example, in the point A) under an excessive pressure the biaxiality factor is The formula for the assessment of the fatigue crack growth rate under biaxial loading was suggested in the paper [20]. This formula was developed based on the well-proved Paris formula and looks like n I da dN C 1 k K , (1) where x y is the load biaxiality factor defined as the relationship of stresses parallel to the crack plane…”

Section: Study Subjectmentioning

confidence: 99%

“…From early papers, Tanaka et al [1] carried out the most serious research examining the fatigue crack growth rate under biaxial loadings. Biaxial fatigue tests were conducted on cross-shaped samples by a hydraulic test machine.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Stress State Characteristics on the Surface Fatigue Cracks Growth Rate Taking into Account Plastic Deformations

Vansovich¹,

Yadrov²,

Beseliya³

2015

Procedia Engineering

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The technique of fatigue tests of steel cross-shaped samples with a surface crack under biaxial loading is described. The sample and equipment for the implementation a biaxial tension and compression-tension in a working part of the sample are proposed. The sample and equipment for the implementation a biaxial tension and compression-tension in a working part of the sample are offered. Test results of structural steel 20 samples are presented. A stress effect parallel to a crack plane on its growth rate is determined. Crack tip plastic zone shape and sizes under various loading conditions are studied. The relationship of a fatigue crack growth rate and a plastic deformation area size is established. The formula to determine the growth rate of a surface crack under biaxial loading taking into account a plastic deformation is proposed.

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“…Linear elastic fracture mechanics predicts that the component of stress parallel to the crack does not contribute to the singular terms and thus has no effect on fatigue crack growth. However, experimental evidence has provided conflicting indications; the effect of an applied static or cyclic tensile stress parallel to the crack is sometimes considered to increase, decrease or have no effect on the growth rate [1][2][3][4][5][6][7][8][9][10]. Similar conflicting observations were reported for the application of a compressive stress parallel to the crack [4-113. One of the factors responsible for these anomalies is that nominal stress for each arm of a cruciform specimen are used for the correlation of experimental data.…”

Section: Introductionmentioning

confidence: 99%

“…For a cruciform specimen, the nominal stress in the x-direction could introduce a local stress in the y-direction, and vice versa. When local stresses, such as those at the centre of an uncracked specimen, were used for correlation purposes, the effect of different biaxial stress ratios on crack growth rate was found to be small [4,6,7,10]. However, it must be noted that even with the so-called local stresses they are reference stresses only.…”

Section: Introductionmentioning

confidence: 99%

Fatigue Crack Growth Under Biaxial Loading

Lam¹

1993

Fatigue Fract Eng Mat Struct

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Fatigue crack growth under biaxial loading for long cracks subjected to low cyclic stress levels was investigated. The biaxial stress ratio I ranging from -0.5 to + 1.0 was considered. The strain energy density factor range was used as the criterion for predicting the crack growth rates and crack path. The agreement between prediction and experimental results was reasonable for crack growth rates and marginal for crack paths. The investigation highlighted the inherent difficulties for crack path prediction and indicated the increased sensitivity to initial crack angle and biaxiaI stress ratio when the biaxial stress ratio approaches unity. 429

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Fatigue Crack Propagation in Biaxial Stress Fields

Cited by 52 publications

References 15 publications

On the mechanism of fatigue crack propagation in ductile metallic materials

On the mechanism of fatigue crack propagation in ductile metallic materials

The Effect of Stress State Characteristics on the Surface Fatigue Cracks Growth Rate Taking into Account Plastic Deformations

Fatigue Crack Growth Under Biaxial Loading

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