Automated Measurement of Near-Surface Plastic Shear Strain

Gerald Trummer, Klaus Six, Christof Marte, Alexander Meierhofer, Christof Sommitsch

Research output: Contribution to journalArticlepeer-review

Abstract

Severe plastic shear deformation and high shear strain gradients are frequently observed in the near-surface layer of tractive rolling contacts, such as in the contact between wheels and rails in railway systems. The variation of plastic shear strain with depth below the surface is important with respect to the interplay between rolling contact fatigue crack initiation and wear. To determine the distribution of plastic shear strain in a reliable and reproducible way from grayscale images of metallographic sections, an automated measurement method has been developed. This method uses local orientation information and local coherency information (a measure of structural alignment) to estimate the mean shear strain as a function of depth. No special specimen preparation is necessary prior to the measurement, such as the insertion of artificial markers or the manufacture of gratings.
The proposed method is validated by analyzing the orientation of inclusions, which have been found in parts of specimens. These inclusions serve as natural markers for the deformation process. The shear strain data from the inclusion analysis are in excellent agreement with the mean shear strain results obtained with the proposed automated method. The proposed method significantly reduces the measurement uncertainty of orientation data, compared to manual local orientation measurements. This is achieved by averaging orientation data over image areas. As an example of use, the plastic shear strain distributions in the near-surface layer of twin disc test specimens made of rail steel R260 and wheel steel R8 are analyzed with the proposed method.
Original languageEnglish
Pages (from-to)1 - 16
JournalInternational Journal of Railway Technology
DOIs
Publication statusPublished - 2014

Keywords

  • rolling contact, twin disc tests, pearlitic steel, plasticity, plastic shear strain, image analysis

ASJC Scopus subject areas

  • Materials Science(all)

Fields of Expertise

  • Advanced Materials Science

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