Experimental and Computational Rotary Bend Fatigue to Characterize Very High Cycle Fatigue of Nitinol

J. Weaver, K. Aycock, G. Sena, S. Sivan, T. Woods, Charlie Yongpravat, F. Donaldson, B. Berg, A. Roiko, Anthony Bauer, W. Falk
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Abstract

The use of superelastic Nitinol in implants continues to grow as physicians, scientists, and engineers design more novel medical devices to utilize its unique characteristics. As many of these devices are expected to be long-term implants, it becomes critically important to increase our understanding of Nitinol fatigue mechanisms beyond 107 cycles. In this study, the fatigue behavior of Nitinol wire in rotary bend testing was characterized by experimental methods and computational modeling. Fractures occurred in high strain regions as predicted by computational modeling. Furthermore, fractures beyond 107 or 108 cycles were observed and seem to have been initiated by nonmetallic inclusions.
镍钛诺旋转弯曲疲劳特性的实验与计算
随着医生、科学家和工程师设计更多新颖的医疗设备来利用超弹性镍钛诺的独特特性,其在植入物中的应用不断增长。由于许多此类设备预计将长期植入,因此增加我们对超过107次循环的镍钛诺疲劳机制的理解变得至关重要。采用实验方法和计算模型对镍钛诺丝在旋转弯曲试验中的疲劳行为进行了表征。根据计算模型预测,裂缝发生在高应变区域。此外,超过107或108旋回的断裂被观察到,似乎是由非金属夹杂物引起的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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