Corrosion-Fatigue of Ti-6Al-4V Coupons Manufactured by Directed Energy Deposition

Fatigue & Fracture of Engineering Materials & Structures Pub Date : 2022-01-21 DOI:10.22541/au.164277431.14120940/v1

D. Hattingh, Sheldyn Botha, D. Bernard, M. James, A. Plessis

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引用次数: 4

Abstract

Titanium is a versatile biocompatible metal that is desirable in additively manufactured medical implant devices. However, additively manufactured parts have particular microstructures, porosity, residual stress and surface conditions which can have a strong impact on fatigue performance. Implants have an added complexity from the saline operating environment and the associated impact on the safe design life. Equally, direct energy deposition induces a complex thermal history which, if not carefully controlled, can significantly alter the mechanical/material properties of the component. This study investigates the decrease in fatigue life, in an in-vitro body fluid simulation using Ringer’s solution, observed in Ti-6Al-4V specimens extracted from coupons manufactured by directed energy deposition. An interrupted deposition strategy was employed to control build regularity, which appeared to influence certain mechanical properties, including corrosion fatigue life. An ≈50% decrease in fatigue life was observed in Ringer’s solution at 6 Hz loading frequency, clearly important in designing implants.

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定向能沉积Ti-6Al-4V片的腐蚀疲劳研究

钛是一种多功能的生物相容性金属，是理想的添加制造的医疗植入装置。然而，增材制造的零件具有特殊的微观结构、孔隙度、残余应力和表面条件，这些都可能对疲劳性能产生强烈影响。植入物由于盐水操作环境和对安全设计寿命的相关影响而增加了复杂性。同样，直接能量沉积引起复杂的热历史，如果不仔细控制，可以显著改变组件的机械/材料性能。本研究在体外体液模拟中用林格溶液观察了定向能沉积法提取的Ti-6Al-4V试样疲劳寿命的降低。采用中断沉积策略来控制构建规则，这似乎会影响某些机械性能，包括腐蚀疲劳寿命。在6 Hz加载频率的林格溶液中观察到疲劳寿命降低约50%，这在设计植入物时显然很重要。

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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Fatigue & Fracture of Engineering Materials & Structures

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