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On the Prediction of the Damage of High Chromium White Cast Iron Under the Impact of Barite Rocks: Modeling and Experiments

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Abstract

Barite sulfate (BaSO4) is considered as a significant mineral substance used as a weighting agent for all types of drilling fluids. Meanwhile, during barite production, crushers used for the grinding step are affected by catastrophic wear damage. In this study, a three-dimension finite element (FE) model is carried out in order to analyze the effect of the barite rocks’ impact on the hammers made from High Chromium White Cast Iron (HCWCI). Brittle damage and elastoplastic material behavior are employed for both barite and HCWCI, respectively. While the latter was described as an elastoplastic model, the material removal is related to the ductile damage model. The impact wear evolution is examined based on the impact conditions, namely velocity impact, angle impact, and barite rock size. The main results show that the mass loss is strongly affected by those parameters. The numerical model is proven to be effective in predicting the damage wear mechanism. The numerical simulations and the investigation results are congruent with the focal literature of the present field of study.

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Acknowledgements

This work was supported by the Ministry of Higher Education and Scientific Research-Tunisia.

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Authors and Affiliations

  1. Laboratory of Materials Engineering and Environment (LGME), National Engineering School of Sfax, University of Sfax, B.P.W.1173, 3038, Sfax, Tunisia

    F. Zouch, A. Bahri & K. Elleuch

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  1. F. Zouch
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  2. A. Bahri
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  3. K. Elleuch
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Correspondence to A. Bahri.

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Zouch, F., Bahri, A. & Elleuch, K. On the Prediction of the Damage of High Chromium White Cast Iron Under the Impact of Barite Rocks: Modeling and Experiments. J. dynamic behavior mater. 8, 473–491 (2022). https://doi.org/10.1007/s40870-022-00353-8

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