3D characterization of rolling contact fatigue crack networks

Jessop, Casey; Ahlström, Johan; Hammar, Lars; Fæster, Søren; Danielsen, Hilmar Kjartansson

doi:10.1016/j.wear.2016.06.027

Cited by 25 publications

(15 citation statements)

References 16 publications

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“…A discontinuous dynamic recrystallized layer was observed on the worn surface of a manganese crossing in one study, whereas the aggregation of vacancy clusters due to deformation leading to cracking has been reported in another study. Previous works [9][10][11][12] on crack formation in rail steels have almost exclusively been done on normal pearlitic steel grades. Here it is found that the microstructure changes during service due to plastic deformation, which is important for crack propagation as it influences the crack path.…”

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confidence: 99%

“…Examples include Garnham et al [12] making schematic representations of the crack geometries in pearlitic rails and Schilke et al [9] studying the crack growth on normal pearlitic grade R350HT rail steel. A non-destructive 3D X-ray computerized tomography technique was used by Jessop et al [10] and Zhou et al [11] for visualizing crack networks, where the crack and its side branches could be visualized with high resolution in 3D in pearlitic grade rail steels.…”

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Crack formation within a Hadfield manganese steel crossing nose

Dhar

Danielsen

Fæster

et al. 2019

Wear

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Switches and crossings in rail networks suffer from complex loading which may induce severe damage and defects, including formation of cracks that can result in rail breakage. This paper focuses on the microstructure and crack network in a damaged Hadfield manganese steel crossing nose. The extent of deformation has been quantified by hardness measurements, optical microscopy and scanning electron microscopy (SEM) including electron back scattering diffraction (EBSD). It is found that the wheel contact causes high deformation hardness of over 600 HV, around three times that of the base material, and the strain hardening extends up to a depth of about 10 mm from the running surface. Microscopy indicates the deformation microstructure is composed of bands of both deformation twins and deformation induced dislocation boundaries. The complex crack network within the nose of the crossing has been investigated using 3D X-ray tomography, where both surface and subsurface cracks are detected with the majority of the cracks originating from the surface. The crack network has been related to the observed deformation microstructure and it has been found that although the hardening and the deformation of the Hadfield manganese steel is quite different from that of commonly used pearlitic rail steels, the crack morphologies are found to be quite similar for the two materials.

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Crack formation within a Hadfield manganese steel crossing nose

Dhar

Danielsen

Fæster

et al. 2019

Wear

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“…The development of the scanning electron microscope (SEM) [ 1 ] and the 3D digital reconstruction techniques [ 2 – 4 ] along with the development of image processing methods, hardware and software, can significantly help in a broad range of applications such as investigation of fracture surfaces [ 5 ], surface engineering [ 6 ], 3D printing [ 7 ], and biological researches [ 8 ]. To reconstruct a 3D digital image from multiple SEM images, correct types of features should be chosen on the 2D images [ 9 ].…”

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Investigation of the Effect of Magnification, Accelerating Voltage, and Working Distance on the 3D Digital Reconstruction Techniques

2020

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In this study, the effect of Scanning Electron Microscopy (SEM) parameters such as magnification ( M ), accelerating voltage ( V ), and working distance (WD) on the 3D digital reconstruction technique, as the first step of the quantitative characterization of fracture surfaces with SEM, was investigated. The 2D images were taken via a 4-Quadrant Backscattered Electron (4Q-BSE) detector. In this study, spherical particles of Ti-6Al-4V (15-45 μm) deposited on the silicon substrate were used. It was observed that the working distance has a significant influence on the 3D digital rebuilding method via SEM images. The results showed that the best range of the working distance for our system is 9 to 10 mm. It was shown that by increasing the magnification to 1000x, the 3D digital reconstruction results improved. However, there was no significant improvement by increasing the magnification beyond 1000x. In addition, results demonstrated that the lower the accelerating voltage, the higher the precision of the 3D reconstruction technique, as long as there are clean backscattered signals. The optimal condition was achieved when magnification, accelerating voltage, and working distance were chosen as 1000x, 3 kV, and 9 mm, respectively.

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“…Although swing nose crossings with less impact levels can be used for heavy haul and high speed systems, in recent years manganese steel has been the preferred choice for fixed crossings because of superior mechanical properties. Most studies on deformation and cracks in rail steels are done for pearlitic steel taken from normal tracks [2][3][4][5][6][7][8]. Not much work has been published in the literature on the damage and degradation behaviour of manganese steel crossings, in contrast to the use of manganese steel in abrasive wear applications such as rock crushing equipment.…”

Section: Introductionmentioning

confidence: 99%

2D and 3D characterization of rolling contact fatigue cracks in manganese steel wing rails from a crossing

Dhar

Danielsen

Fæster

et al. 2019

Wear

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Rail wheel contact at switches and crossings (S&Cs) induces impact stresses along with normal and shear contact stresses, resulting in plastic deformation and eventually crack formation. Damaged and deformed wing rails of a manganese steel crossing are studied and the microstructure, hardness and 3D crack network within the steel are characterized. The surface of the rail receives the maximum deformation resulting in a hardened top layer. The deformation is manifested in a high density of twins and dislocation boundaries in the microstructure. A complex crack network is revealed in high resolution by X-ray tomography.

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3D characterization of rolling contact fatigue crack networks

Cited by 25 publications

References 16 publications

Crack formation within a Hadfield manganese steel crossing nose

Crack formation within a Hadfield manganese steel crossing nose

Investigation of the Effect of Magnification, Accelerating Voltage, and Working Distance on the 3D Digital Reconstruction Techniques

2D and 3D characterization of rolling contact fatigue cracks in manganese steel wing rails from a crossing

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