Chen Cai scite author profile

Experimental backtracking technique and finite element analysis have been employed to evaluate the stress intensities along the front of an elliptical surface crack in a cylindrical rod. The finite element solution covers a wide range of crack shapes loaded under end-free and end-constrained axial tension and pure bending. Convenient closed form stress intensity expressions along the whole crack front for each of the loading cases have been given in terms of the crack aspect ratio, crack depth ratio and place ratio.The closed form solutions have been compared against a number of representative solutions collected from the literature. It has been found that different finite element results for the interior points are generally in good mutual agreement, while solutions derived from other methods may sometimes indicate different trends. At the surface interception point agreement is less good because of a complication in the interpretation of stress intensity there.Experimental backtracking results on the end-constrained axial tension case corroborate well with the closed form solution presented. It suggests that the current closed form solution is adequate in describing the stress intensities along the whole crack front of real surface cracks in cylindrical rods.

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A model for evaluating the effect of fatigue crack repair by the infiltration method

Shin

Cai

2000

Fatigue Fract Eng Mat Struct

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Infiltration of foreign materials into a fatigue crack has previously been shown to be able to retard the crack and extend fatigue life. Most of the related studies were empirical and phenomenological in nature. To aid engineering decisions, it would be advantageous if the possible outcome of a repair can be evaluated beforehand. To this end, a crack closure model taking into account the additional closure effect of the infiltrant has been developed and verified against experimental results. With this model, the sensitivity of the repair effect to various parameters such as mechanical properties of the infiltrant, depth of penetration and infiltration load level can be assessed.

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The mechanics of High Pressure Compressive Shearing with application to ARMCO® steel

Tóth

Dhinwal

et al. 2019

Materials Characterization

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A normalized area-compliance method for monitoring surface crack development in a cylindrical rod

Cai

Shin

2005

International Journal of Fatigue

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Surface fatigue crack growth suppression in cylindrical rods by artificial infiltration

Shin¹,

Cai²

2008

International Journal of Fatigue

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Chen Cai

Experimental and finite element analyses on stress intensity factors of an elliptical surface crack in a circular shaft under tension and bending

A model for evaluating the effect of fatigue crack repair by the infiltration method

The mechanics of High Pressure Compressive Shearing with application to ARMCO® steel

A normalized area-compliance method for monitoring surface crack development in a cylindrical rod

Surface fatigue crack growth suppression in cylindrical rods by artificial infiltration

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