Full-field microscale strain measurements of a nitinol medical device using digital image correlation.

K. Aycock, J. Weaver, H. Paranjape, K. Senthilnathan, C. Bonsignore, B. Craven
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引用次数: 11

Abstract

Computational modeling and simulation are commonly used during the development of cardiovascular implants to predict peak strains and strain amplitudes and to estimate the associated durability and fatigue life of these devices. However, simulation validation has historically relied on comparison with surrogate quantities like force and displacement due to barriers to direct strain measurement-most notably, the small spatial scale of these devices. We demonstrate the use of microscale two-dimensional digital image correlation (2D-DIC) to directly characterize full-field surface strains on a nitinol medical device coupon under emulated physiological and hyperphysiological loading. Experiments are performed using a digital optical microscope and a custom, temperature-controlled load frame. Following applicable recommendations from the International DIC Society, hardware and environmental heating studies, noise floor analyses, and in- and out-of-plane rigid body translation studies are first performed to characterize the microscale DIC setup. Uniaxial tension experiments are also performed using a polymeric test specimen to characterize the strain accuracy of the approach up to nominal stains of 5%. Sub-millimeter fields of view and sub-micron displacement accuracies (9nm mean error) are achieved, and systematic (mean) and random (standard deviation) errors in strain are each estimated to be approximately 1,000μϵ. The system is then demonstrated by acquiring measurements at the root of a 300μm-wide nitinol medical device strut undergoing fixed-free cantilever bending motion. Lüders-like transformation bands are observed originating from the tensile side of the strut that spread toward the neutral axis at an angle of approximately 55°. Despite the inherent limitations of optical microscopy and 2D-DIC, simple and relatively economical setups like that demonstrated herein could provide a practical and accessible solution for characterizing cardiovascular implant micromechanics, validating computational model strain predictions, and guiding the development of next-generation material models for simulating superelastic nitinol.
使用数字图像相关性对镍钛诺医疗设备进行全场微尺度应变测量。
在心血管植入物的开发过程中,计算建模和仿真通常用于预测峰值应变和应变幅值,并估计这些设备的相关耐久性和疲劳寿命。然而,由于直接应变测量的障碍,模拟验证历来依赖于与替代量(如力和位移)的比较-最值得注意的是,这些设备的小空间尺度。我们展示了使用微尺度二维数字图像相关(2D-DIC)来直接表征镍钛诺医疗器械在模拟生理和超生理载荷下的全场表面应变。实验使用数字光学显微镜和定制的温控负载框架进行。根据国际DIC协会的适用建议,首先进行了硬件和环境加热研究,噪声底分析以及平面内和平面外刚体平移研究,以表征微尺度DIC装置。单轴拉伸实验也使用聚合物试样进行,以表征该方法的应变精度高达5%的标称污渍。该系统实现了亚毫米视场和亚微米位移精度(平均误差为9nm),应变的系统(平均)和随机(标准偏差)误差均约为1000 μ λ。然后,通过在300μm宽的镍钛诺医疗器械支柱根部进行无固定悬臂弯曲运动来验证该系统。观察到从支柱的拉伸侧开始的l德尔斯样转变带,以约55°的角度向中性轴扩散。尽管光学显微镜和2D-DIC存在固有的局限性,但本文所展示的简单且相对经济的设置可以为表征心血管植入物的微观力学,验证计算模型应变预测以及指导下一代模拟超弹性镍钛诺材料模型的开发提供实用且可访问的解决方案。
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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