Effect of microstructural characteristics of thick steel plates on residual stress formation and cracking during flame cutting

Tuomas Jokiaho, Suvi Santa-aho, Henri Järvinen, Mari Honkanen, Pasi Peura, Minnamari Vippola

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    1 Citation (Scopus)
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    Thick wear-resistant steel plates are commonly used in demanding conditions,
    such as in the mining industry. In harsh environments, a high degree of both
    toughness and hardness is required, which extends the service life of the
    components but also makes the production of the plates difficult. Flame cutting is a generally applied cutting method in the heavy steel industry since it enables the cutting of thick steel plates at high production rates. However, flame cutting may cause cracks in the cut edge of the steel plates, leading to rejects for the steel industry and end-users. In addition, cutting generates a heat-affected zone at the cut edge, where volumetric and microstructural changes and hardness variations take place. A steep thermal gradient, generated during flame cutting, also produces high residual stresses on the cut edge. The goal of this study is to examine how microstructural features contribute to the residual stress formation and cracking probability of thick steel plates. Specific microstructural features can make the plates prone to cracking and tend to produce undesired stresses during the cutting process. The residual stress profiles of flame-cut specimens were measured using the X-ray diffraction method. In addition, the mechanical properties of steel plates
    were evaluated. The microstructures of the cut edge and the base material were
    characterized by electron microscopy. Results indicate that the shape of the prior austenite grains has an effect on both the cracking probability and residual stressformation. Longitudinally oriented prior austenite grain boundaries combined with a high residual tensile stress state provide potential sites for cracking.
    Original languageEnglish
    Number of pages20
    JournalMaterials Performance and Characterization
    Issue number4
    Publication statusPublished - Jun 2018
    Publication typeA1 Journal article-refereed


    • flame cutting
    • microstructure
    • residual stress
    • heat-affected zone
    • thick steel plate
    • X-ray diffractometer
    • electron microscopy

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    • Publication forum level 1


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