生理环境腐蚀导致镁-钆的强度和延性损失:实验和模型。

D. Steglich, J. Besson, Inken Reinke, H. Helmholz, M. Luczak, V. Garamus, B. Wiese, D. Höche, C. Cyron, R. Willumeit-Römer
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引用次数: 0

摘要

我们提出了一个计算框架来研究腐蚀对镁(Mg)样品机械强度的影响。我们的工作的动机是需要预测生物医学Mg植入物在生理环境中降解一段时间后的剩余强度。为了模拟腐蚀,使用了一个质量扩散型模型,该模型使用威布尔统计来解释局部腐蚀。总质量损失是规定的(例如,根据实验数据)。Mg试样的力学行为采用最先进的Cazacu-Plunkett-Barlat塑性模型和耦合损伤模型来模拟。这使我们能够研究Mg在浸入样品中的降解如何随着时间的推移降低机械强度。我们进行了大量的体外腐蚀实验和力学测试来验证我们的计算框架。我们的框架可以预测实验观察到的机械强度和延性的损失,因为腐蚀的拉伸和压缩试验。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Strength and ductility loss of Magnesium-Gadolinium due to corrosion in physiological environment: Experiments and modeling.
We propose a computational framework to study the effect of corrosion on the mechanical strength of magnesium (Mg) samples. Our work is motivated by the need to predict the residual strength of biomedical Mg implants after a given period of degradation in a physiological environment. To model corrosion, a mass-diffusion type model is used that accounts for localised corrosion using Weibull statistics. The overall mass loss is prescribed (e.g., based on experimental data). The mechanical behaviour of the Mg samples is modeled by a state-of-the-art Cazacu-Plunkett-Barlat plasticity model with a coupled damage model. This allowed us to study how Mg degradation in immersed samples reduces the mechanical strength over time. We performed a large number of in vitro corrosion experiments and mechanical tests to validate our computational framework. Our framework could predict both the experimentally observed loss of mechanical strength and the ductility due to corrosion for both tension and compression tests.
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