Mechanism of grain boundary angle on solidification cracking in directed energy deposition Hastelloy X superalloys

IF 10.3 1区工程技术 Q1 ENGINEERING, MANUFACTURING

Additive manufacturing Pub Date : 2024-08-05 DOI:10.1016/j.addma.2024.104406

Yashan Zhang, Bojing Guo, Meirong Jiang, Junjie Li, Zhijun Wang, Lei Wang, Jincheng Wang, Xin Lin

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引用次数: 0

Abstract

Solidification cracking occurs only when the grain boundary (GB) angle ( $θ$ ) exceeds a critical value. This value, known as the critical cracked GB angle ( $θ^{*}$ ), can be predicted from the grain coalescence theory based on GB-angle-dependent GB energy. However, the calculated value ( $θ_{c}^{*}$ ) is always less than the measured value in experiments ( $θ_{e}^{*}$ ), which is also confirmed in our directed energy deposition Hastelloy X superalloys. In addition to GB energy, there are evidences showing that GB angle can affect cracking by changing dendrite spacings. We show by experiments and phase field simulations that, same as GB energy, the dendrite spacings at GBs increase with GB angle, but its effect on solidification cracking sensitivity (SCS) is opposite to GB energy. Depending on their relative contributions, three ranges can be identified. In the first range of $θ < θ_{c}^{*}$ , both dendrite spacings and GB energy have negligible effects on dendrite coalescence, compared to the case inside a grain. In the second range of $θ_{c}^{*} < θ < θ_{e}^{*}$ , dendrite spacings counteract the effect of high GB energy on SCS. It is exactly this effect that induces the gap in $θ^{*}$ between theory and experiments. In the third range of $θ > θ_{e}^{*}$ , GB energy plays a dominant role and leads to severe solidification cracking. After including the effect of dendrite spacings on SCS, we predict $θ^{*}$ =15° in directed energy deposition Hastelloy X superalloys, close to the experimental value of 18°. These new findings provide new insights for suppressing cracking by controlling the dendrite spacings near GBs.

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晶界角对定向能沉积哈氏合金 X 超合金凝固裂纹的影响机理

只有当晶界（GB）角（θ）超过临界值时，才会发生凝固开裂。这个值被称为临界开裂 GB 角 (θ*)，可以根据与 GB 角有关的 GB 能量从晶粒凝聚理论中预测出来。然而，计算值（θc*）总是小于实验测量值（θe*），这在我们的定向能沉积哈氏合金 X 超级合金中也得到了证实。除了 GB 能量外，还有证据表明 GB 角度可通过改变树枝晶间距来影响开裂。我们通过实验和相场模拟表明，与 GB 能量一样，GB 处的树枝晶间距也会随 GB 角度的增加而增加，但其对凝固开裂灵敏度（SCS）的影响与 GB 能量相反。根据它们的相对贡献，可以确定三个范围。在 θ<θc* 的第一个范围内，与晶粒内部的情况相比，树枝晶间距和 GB 能量对树枝晶凝聚的影响都可以忽略不计。在第二个 θc*<θ<θe* 范围内，树枝晶间距抵消了高 GB 能量对 SCS 的影响。正是这种效应导致了理论与实验之间在 θ* 上的差距。在θ>θe*的第三个范围内，GB能量起着主导作用，并导致严重的凝固开裂。在考虑了枝晶间距对 SCS 的影响后，我们预测定向能沉积 Hastelloy X 超级合金中的θ*=15°，接近实验值 18°。这些新发现为通过控制 GB 附近的树枝晶间距来抑制开裂提供了新的见解。

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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来源期刊

Additive manufacturing Materials Science-General Materials Science

CiteScore

19.80

自引率

12.70%

发文量

648

审稿时长

35 days

期刊介绍： Additive Manufacturing stands as a peer-reviewed journal dedicated to delivering high-quality research papers and reviews in the field of additive manufacturing, serving both academia and industry leaders. The journal's objective is to recognize the innovative essence of additive manufacturing and its diverse applications, providing a comprehensive overview of current developments and future prospects. The transformative potential of additive manufacturing technologies in product design and manufacturing is poised to disrupt traditional approaches. In response to this paradigm shift, a distinctive and comprehensive publication outlet was essential. Additive Manufacturing fulfills this need, offering a platform for engineers, materials scientists, and practitioners across academia and various industries to document and share innovations in these evolving technologies.