4.4 Article

A Numerical Approach to Study the Oxide Layer Effect on Adhesion in Cold Spray

期刊

JOURNAL OF THERMAL SPRAY TECHNOLOGY
卷 30, 期 7, 页码 1777-1791

出版社

SPRINGER
DOI: 10.1007/s11666-021-01245-4

关键词

cold gas dynamic spraying < processing; cold spray < processing; cold work < processing; finite element modeling < modeling; modeling of splat formation < modeling; process modeling < modeling; particle velocity < processing

资金

  1. FAPESP-CALDO SPRINT agreement [2017/50151-6]

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A novel finite element method was proposed in this study to predict the occurrence of localized metallurgical bonding in the cold spray process, taking into account the native oxide layer covering the particles. Experimental data validated the predicted critical velocity and showed consistency between predicted and observed bonding locations. The study also investigated the effects of oxide thickness and impact velocity on particle deposition, with comparisons to experimental data highlighting the model's ability to predict material behavior during deposition.
Due to the high strain rate deformation of particles in cold spray (CS), in situ investigation is challenging. It has been shown that metallurgical bonding is one of the main adhesion mechanisms of particles during coating buildup. Although several numerical studies have been done to study CS particle impact, very few were able to predict the occurrence of bonding based on the process physics. In this study, a novel finite element method is proposed to predict the occurrence of localized metallurgical bonding in the CS process that accounts for the native oxide layer which covers copper particles. The predicted critical velocity of was compared to experimental data to validate the proposed model. In addition, it was shown that the predicted bonding locations at the particle/substrate interface are consistent with experimental observations. The oxide removal process during impact was observed, and its effects on particle deformation/deposition were explained. Moreover, the effects of the oxide thickness and the impact velocity on the particle deposition were investigated and compared with experimental data. This comparison again illustrated the ability of the proposed model in predicting the material behavior during the deposition process.

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