Constitutive Model for Ni-Ti-Fe Shape Memory Alloys Exhibiting Pronounced R-Phase Transformation

M. Frost, P. Sedlák, A. Jury, L. Heller
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Abstract

Specific heat treatment or addition of a ternary element may induce a two-stage transformation sequence in NiTi shape memory alloys (SMA). A typical example of intermediating phases is so-called R-phase, a rhombohedral distortion of the cubic austenitic phase, which exhibits much lower transformation strain and thermal hysteresis than the subsequent transition to monoclinic martensite. In specific alloys, e.g., in NiTi slightly enriched by iron, the temperature and stress intervals in which R-phase is stable are quite broad. Hence, the influence of R-phase on the macroscopic (thermo)mechanical response should be considered when developing and designing products from these alloys. Within this context, tailored constitutive models allowing to reproduce the response in complex loading scenarios without additional experimental effort can be extremely beneficial. This paper presents an enhanced constitutive model for NiTi SMA featuring the R-phase transition. The model recognizes R-phase as a distinct phase, respects the coupled influence of stress and temperature on any phase transformation, and covers reorientation (reconfiguration) of both martensite and R-phase with applied stress. The core of the model consists of two material functions: one captures the energy stored in the material at a given thermodynamic state, the other defines the energy released during dissipative processes, which are considered rate-independent. The model was validated through a direct comparison of experimental tests (isothermal tensile tests, isobaric thermal tests, recovery stress tests) with simulated counterparts.
具有明显r相变的Ni-Ti-Fe形状记忆合金的本构模型
特定热处理或三元元素的加入可诱导NiTi形状记忆合金(SMA)的两阶段转变序列。中间相的一个典型例子是所谓的r相,它是立方奥氏体相的一种菱形变形,与随后向单斜马氏体的转变相比,它表现出更低的转变应变和热滞后。在特定的合金中,例如在少量富铁的NiTi中,r相稳定的温度和应力区间相当宽。因此,在开发和设计这些合金的产品时,应考虑r相对宏观(热)力学响应的影响。在这种情况下,量身定制的本构模型可以在没有额外实验的情况下重现复杂加载场景下的响应,这是非常有益的。提出了一种具有r相变的NiTi SMA增强本构模型。该模型承认r相是一个独立的相,尊重应力和温度对任何相变的耦合影响,并涵盖了马氏体和r相在外加应力作用下的重取向(重配置)。该模型的核心由两个材料函数组成:一个捕获在给定热力学状态下储存在材料中的能量,另一个定义在耗散过程中释放的能量,这被认为是速率无关的。通过将实验测试(等温拉伸测试、等压热测试、恢复应力测试)与模拟测试进行直接比较,验证了该模型。
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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