Effect of a laser pre-quenched steel substrate surface on the crack driving force in a coating–steel substrate system

International Journal of Solids and Structures

2008

Self Cite

a b s t r a c tA cyclic bending experiment is designed to investigate the interface fracture behaviour of a hard chromium coating on a ductile substrate with periodic surface hardened regions. The unique deflection pattern of the vertical cracks after they run through the coating and impinge at the interface is revealed experimentally. A simple double-layer elastic beam model is adopted to investigate the interfacial shear stresses analytically. A FE model is employed to compute the stresses of the tri-phase structure under a single round of bending, and to investigate the effect of the loading conditions on the deflection pattern of the vertical cracks at the interface.

Section: Resultsmentioning

confidence: 60%

Section: Numerical Resultsmentioning

confidence: 77%

Section: Introductionmentioning

confidence: 99%

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On the cyclic bending behaviour of a hard coating on a ductile substrate with periodic surface hardened regions

Zhang

International Journal of Solids and Structures

2008

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“…Apart from the wear and erosion experiments, it should be emphasized that most of the experiments in the studies mentioned above were restricted to the fatigue property research under dynamic loads. Recently, a mechanical model was developed to quantify the effect of laser quenching on crack driving force in terms of J-integral, and it could be obtained that the dominant factor influencing the crack driving force was the residual stress (Yang et al, 2006(Yang et al, , 2007. However, the residual stress is approximated as a mean value over the crack length, and the residual stress gradient effect was not considered in (Yang et al, 2006(Yang et al, , 2007.…”

Section: Introductionmentioning

confidence: 99%

A mechanical model for the quantification of the effect of laser quenching on CTOD in steels

Yang

Journal of Materials Processing Technology

Zhang

et al. 2009

Self Cite

Crack tip opening displacement (CTOD) Residual stress gradient effect Micro-hardness Steels a b s t r a c tThe technology of laser quenching is widely used to improve the surface properties of steels in surface engineering. Generally, laser quenching of steels can lead to two important results. One is the generation of residual stress in the surface layer. In general, the residual stress varies from the surface to the interior along the quenched track depth direction, and the residual stress variation is termed as residual stress gradient effect in this work. The other is the change of mechanical properties of the surface layer, such as the increases of the micro-hardness, resulting from the changes of the microstructure of the surface layer. In this work, a mechanical model of a laser-quenched specimen with a crack in the middle of the quenched layer is developed to quantify the effect of residual stress gradient and the average micro-hardness over the crack length on crack tip opening displacement (CTOD). It is assumed that the crack in the middle of the quenched layer is created after laser quenching, and the crack can be a pre-crack or a defect due to some reasons, such as a void, cavity or a micro-crack. Based on the elastic-plastic fracture mechanics theory and using the relationship between the micro-hardness and yield strength, a concise analytical solution, which can be used to quantify the effect of residual stress gradient and the average micro-hardness over the crack length resulting from laser quenching on CTOD, is obtained. The concise analytical solution obtained in this work, cannot only be used as a means to predict the crack driving force in terms of the CTOD, but also serve as a baseline for further experimental investigation of the effect after laser-quenching treatment on fracture toughness in terms of the critical CTOD of a specimen, accounting for the laser-quenching effect. A numerical example presented in this work shows that the CTOD of the quenched can be significantly decreased in comparison with that of the unquenched.

“…[7,8]. Some mechanisms responsible for the improvement have been reported, such as the hardness improvement of the steel substrate surface [8], the finer microstructure of the interface as well as the coating itself [7] and the decrease of the crack driving force in the hardened layer by residual compressive stress and yield strength improvement by the technology [9][10][11]. In this work, a comparative investigation on the initial micro-crack density of the Cr coating on the laser pre-quenched steel substrate surface and original steel substrate surface is investigated.…”

mentioning

confidence: 99%

Research on the Micro-Crack Density of a Chromium Coating/Steel Substrate with and without Laser Pre-Quenching Treatment

Yang

2011

AMR

The initial micro-crack density of a chromium coating/steel substrate with and without laser pre-quenching treatment was investigated in this work. It was found the micro-crack density of Cr coating on the pre-quenched substrate surface was much lower than that of the Cr coating on the original substrate surface. Based on the results presented in this work and in the literature, the find presented in this work indicates the lower crack density of the chromium coating on the pre-quenched substrate may improve the mechanical properties of this material system, and it may be an important mechanism responsible for the prolonged lives of workpieces in practice.