基于晶体塑性的可变型 β 钛合金变形构造模型

Peter Christie, M. Siddiq, U. Asim, R. McMeeking, M. Kartal
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摘要

由于具有诱人的机械性能,可变型 β 钛合金在航空航天、航海、生物医学等许多行业中都非常受欢迎。不同变形机制之间的复杂相互作用往往会产生许多人们所追求的特性,如增强的延展性、超弹性和形状记忆效应。应力诱导马氏体转变是这些合金的重要变形机制。了解应力诱导马氏体转变及其对材料微观结构演变的影响具有重要意义。为此,我们开发了一种基于晶体塑性的构成模型,该模型同时考虑了可变质 β 钛合金中的马氏体相变和滑移塑性。我们以物理原理和晶体塑性理论为基础,提出了马氏体转变演变的新公式。为了理解和证明模型的这一特点,我们对新开发的构成模型进行了参数评估。随后,我们首次分析了可蜕变 β 钛合金中的应力诱导马氏体转变。我们首先根据单轴加载实验对表现出应力诱导马氏体(SIM)转变的不同可变质 β 钛合金进行了验证。作为其中的一部分,我们首次使用单晶模拟来研究在无约束转变过程中各个转变体系之间的相互作用。这项研究表明,在弹性、转变和最终滑移阶段的所有变形阶段,实验和模拟反应都非常一致。观察到了相对 "强 "和 "弱 "的转变方向,这与实验研究结果一致。这项工作证明了晶体塑性有限元方法(CPFEM)捕捉物理机制的能力,同时也为我们深入了解可蜕变 β 钛合金中不同变形机制之间的相互作用提供了新的视角。
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Crystal Plasticity based Constitutive Model for Deformation in Metastable β Titanium Alloys
Due to attractive mechanical properties, metastable β titanium alloys have become very popular in many industries including aerospace, marine, biomedical, and many more. It is often the complex interplay among the different deformation mechanisms that produces many of the sought-after properties, such as enhanced ductility, super-elasticity, and shape memory effects. Stress induced martensitic transformation is an important deformation mechanism for these alloys. Understanding of it and the influence it has on the microstructural evolution of materials is of great importance. To this end we have developed a crystal plasticity based constitutive model which accounts for both martensitic phase transformation and slip based plasticity simultaneously in metastable β titanium alloys. We present a new formulation for the evolution of martensite transformation, based on physical principles and crystal plasticity theory. To understand and demonstrate this feature of the model, a parametric assessment of the newly developed constitutive model is conducted. This is followed by first of its kind analyses of stress induced martensitic transformation in metastable β titanium alloys. We firstly present validations against uniaxial loading experiments for different metastable β titanium alloys exhibiting stress induced martensite (SIM) transformation. As part of this, single crystal simulations in metastable β titanium alloys are used for the first time to investigate the interaction of individual transformation systems during unconstrained transformation. This study shows good agreement between the experimental and simulated responses during all stages of deformation in which elastic, transformation and finally the slip stage are exhibited. Relatively “strong” and “weak” orientations for transformation are observed, consistent with experimental studies. The work done here demonstrates the ability of this crystal plasticity finite element method (CPFEM) to capture physical mechanisms while bringing new insight about the interaction of different deformation mechanisms in metastable β titanium alloys.
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