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Element Transfer Behaviors of Fused CaF2-SiO2 Fluxes Subject to High Heat Input Submerged Arc Welding

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Abstract

A series of fused CaF2-SiO2 binary fluxes have been developed to investigate element transfer behaviors under high heat input submerged arc welding. Transfer of elements is quantified by Δ quantities, which demonstrate respective contributions from the flux to the weld metal. Effects of SiO2 contents on the transfer of Si, Mn, and O have been thoroughly evaluated. Thermodynamic considerations have been attempted for constraining chemical reactions and mechanisms involved in welding.

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We thank the National Natural Science Foundation of China (Grant Nos. 51622401, 51861130361, 51861145312, and 51850410522), Newton Advanced Fellowship by the Royal Society (Grant No. RP12G0414), Research Fund for Central Universities (Grant No. N172502004), Xingliao Talents Program (XLYC1807024 and XLYC1802024), and Global Talents Recruitment Program endowed by the Chinese government for their financial support. We also thank the State Key Laboratory of Solidification Processing, Northwestern Polytechnical University (Grant No. SKLSP201805), Shagang Steel, and Lincoln Electric China.

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Correspondence to Cong Wang.

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Manuscript submitted August 19, 2019.

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Zhang, J., Coetsee, T. & Wang, C. Element Transfer Behaviors of Fused CaF2-SiO2 Fluxes Subject to High Heat Input Submerged Arc Welding. Metall and Materi Trans B 51, 16–21 (2020). https://doi.org/10.1007/s11663-019-01753-3

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