医用增材制造钛的电化学行为

2020 IEEE International Symposium on Medical Measurements and Applications (MeMeA) Pub Date : 2020-06-01 DOI:10.1109/MeMeA49120.2020.9137205

A. Gullino, S. Grassini, E. Angelini, E. Padovano, C. Badini, L. Iannucci, M. Parvis

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引用次数: 0

摘要

由于其促进骨整合的能力和机械性能，商业纯钛是几种生物医学应用的重要材料。近年来，诸如增材制造等新的加工路线为生物医学领域中这种材料的开发开辟了新的领域，使实现新形状和减少假肢的整体重量成为可能。同时，由于这些新的成形技术，也面临着新的问题，如微结构的存在以及最终部件中孔隙率与工艺参数之间的关系。本文采用电化学测量来评估孔隙率对增材制造钛在模拟体液中的腐蚀行为的影响。具体来说，评估不同孔隙度水平的可能性与工艺参数的变化进行了讨论。

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Electrochemical behaviour of additively manufactured titanium for biomedical applications

Commercially pure titanium is an important material for several biomedical applications, thanks to its capability to promote osseointegration and its mechanical properties. In recent years, new processing routes like additive manufacturing have opened new frontiers in the exploitation of this material in the biomedical field, giving the possibility to realize new shapes and decrease the overall weight of the prostheses. At the same time, due to these new forming technologies, new issues are faced, like the presence of a fine microstructure and the relation between porosity in the final component and the process parameters. This paper employs electrochemical measurements to assess the porosity effect on the corrosion behaviour of additively manufactured titanium in simulated body fluids. Specifically, the possibility of assessing different porosity levels related to processing parameters change is discussed.

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2020 IEEE International Symposium on Medical Measurements and Applications (MeMeA)

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