An investigation of forming of Ti-6Al-4V at lower temperatures

Superplasticity in Advanced Materials Pub Date : 2023-07-10 DOI:10.21741/9781644902615-5

Hosam Elrakayby, Diego Gonzalez, P. Mandal, Paul Blackwell

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Abstract

Abstract. Forming components of titanium alloys via superplastic forming at elevated temperatures while being exposed to oxygen leads to surface oxidation. The hard oxide layer formed on the surface of components is referred to as the alpha case. This alpha case layer requires post-form processing to remove it, thus increasing overall manufacturing costs and times. Superplastic forming at lower temperatures can significantly reduce the formation of the alpha case and has other benefits, such as life extension of tooling and less energy consumption. This paper shows the work done in terms of forming non-commercial components at temperatures significantly lower than the traditional ones, proving that forming at those temperatures is readily achievable. Forming pressures and tonnage need to be readjusted because of the increase in the flow stresses of the material. This paper also illustrates the implementation of a microstructural-based model to predict the hot forming behaviour of commercial titanium alloy Ti-6Al-4V (Ti64) during forming at 800°C. The material model is implemented into a commercial finite element software, Abaqus, and PAM-STAMP to obtain the optimal pressure cycle to form a non-commercial research component at 800 °C with a view to minimizing alpha case formation.

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Ti-6Al-4V低温成形的研究

摘要在高温下通过超塑性成形的钛合金部件暴露在氧气中会导致表面氧化。在元件表面形成的硬氧化层称为α层。这个alpha外壳层需要进行后期处理来移除它，从而增加了总体制造成本和时间。在较低温度下进行超塑性成形可以显著减少α壳的形成，并具有其他好处，例如延长模具寿命和降低能耗。本文展示了在明显低于传统温度下成形非商业部件方面所做的工作，证明在这些温度下成形是容易实现的。由于材料的流动应力增加，需要重新调整成形压力和吨位。本文还介绍了一种基于显微组织的模型的实现，用于预测商用钛合金Ti-6Al-4V (Ti64)在800°C下的热成形行为。材料模型被实现到商业有限元软件，Abaqus和PAM-STAMP中，以获得在800°C下形成非商业研究组件的最佳压力循环，以最小化alpha case形成。

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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Superplasticity in Advanced Materials

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