Eiichi Miyokawa scite author profile

When multiple cracks approach one another, the stress intensity factor is likely to change due to the interaction of the stress field. This causes change in growth rate and shape of cracks. In particular, when cracks are in parallel position to the loading direction, the shape of cracks becomes non-planar. In this study, the complex growth of interacting cracks is evaluated by using the S-Version finite element method, in which local detailed finite element mesh (local mesh) is superposed on coarse finite element model (global mesh) representing the global structure. In order to investigate the effect of interaction on the growth behavior, two parallel surface cracks are subjected to cyclic tensile or bending load.It is shown that the smaller crack is shielded by larger crack due to the interaction and stops growing when the difference in size of two cracks is significant. Based on simulations of various conditions, a procedure and criteria for evaluating crack growth for fitness-for-service assessment is proposed. According to the procedure, the interaction is not necessary to be considered in the crack growth prediction when the difference in size of two cracks exceeds the criterion.

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Study on Impact Velocity of Tsunami Debris in Consideration of Surrounding Flow

Ikesue¹,

Kushioka²,

Hirai³

et al. 2017

J. JSCE Ser. B3

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Growth Behavior of Two Interacting Surface Cracks of Dissimilar Size (Comparison for Tensile and Bending Load)

Kamaya¹,

Kikuchi

Miyokawa

2010

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When multiple cracks approach one another, the stress intensity factor is likely to change due to the interaction of the stress field. This causes change in growth rate and shape of cracks. In particular, when cracks are in parallel position to the loading direction, the shape of cracks becomes non-planar. In this study, the complex growth of interacting cracks is evaluated by using the S-Version finite element method, in which local detailed finite element mesh (local mesh) is superposed on cores finite element model (global mesh) representing the global structure. In this study, two parallel surface cracks are subjected to two types of loading; tensile and bending load. Comparisons are made on the growth behavior under two types of loading. It is shown that the smaller crack stop growing due to the interaction when the difference in size of two cracks is large. This tendency is more significant for the bending load. The procedure for evaluating crack growth for Fitness-for-Service assessment is discussed.

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1312 A prediction procedure for growth of two parallel surface cracks of dissimilar size

Kamaya

Kikuchi

Miyokawa

2009

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Eiichi Miyokawa

Growth prediction of two interacting surface cracks of dissimilar sizes

Crack Growth Prediction Method Considering Interaction between Multiple Cracks (Growth of Surface Cracks of Dissimilar Size under Cyclic Tensile and Bending Load)

Study on Impact Velocity of Tsunami Debris in Consideration of Surrounding Flow

Growth Behavior of Two Interacting Surface Cracks of Dissimilar Size (Comparison for Tensile and Bending Load)

1312 A prediction procedure for growth of two parallel surface cracks of dissimilar size

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