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The FEM simulation of mechanical properties characterization of the stent under the quasi-static loading/unloading

✍ Scribed by Y.H. Zhi; X.M. Wang; M. Frotscher; G. Eggeler; Z.F. Yue

Publisher
John Wiley and Sons
Year
2007
Tongue
English
Weight
369 KB
Volume
38
Category
Article
ISSN
0933-5137

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✦ Synopsis

Abstract

In this paper, the detailed stress distributions of NiTi stents have been studied. The primary object of this study is to set up a cell model to reveal the cause of crack initiation for stents. Auricchio’s super‐elastic model is used to analyze the essential stent cell. Two different kinds of models are analyzed. One model is the stent without defect and the other model is a stent with defects caused by laser burrs or TiC inclusions. The structural stress distribution is not only related to a specimen without defect but also to the material of a bulge defect. The maximum stresses of the stent without defect are near the knots, while the one with defects possesses the maximum stress near the surrounding of the bulge defect. It was found that cracks/fractures can easily appear within a distance of 1/3 of the knot to knot spacing. In particular, a stent with TiC inclusion defects is likely to fail near the bulge face defect. Our simulations agree with experimental results.

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