Effects of carbon content on precipitate evolution and crack susceptibility in additively manufactured IN738LC

Materials Science in Additive Manufacturing Pub Date : 2024-02-19 DOI:10.36922/msam.2264

Zhongji Sun, Verner Soh, Coryl Jing Jun Lee, Delvin Wuu, Desmond Lau, Siyuan Wei, Chee Koon Ng, S. Sing, Dennis Tan, Pei Wang

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Abstract

Hot cracking is a major bottleneck preventing the additive manufacturing community from adopting precipitation-strengthened nickel-base superalloys, such as the IN738LC. Prior literature demonstrates the beneficial outcome of increasing the carbon content within IN738LC to alleviate its hot cracking problem. However, the effect of carbon content on the gamma prime precipitation and grain recrystallization was not fully addressed. Here, we fabricated five sample sets of IN738LC with different carbon contents and subjected these samples to two separate heat treatment processes. The precipitate and grain evolution were monitored under the backscattered electron imaging and electron backscattered diffraction studies. While the carbon addition could assist in addressing the hot cracking problem, horizontal delamination cracks were detected during the fabrication of large samples when the overall carbon content was above 0.4 wt.%, highlighting the need for care when introducing carbon for the purpose of resolving hot cracking.

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碳含量对添加剂制造的 IN738LC 中沉淀演变和裂纹易感性的影响

热裂纹是阻碍增材制造领域采用沉淀强化镍基超级合金（如 IN738LC）的主要瓶颈。先前的文献表明，增加 IN738LC 中的碳含量可以缓解热裂纹问题。然而，碳含量对伽马素析出和晶粒再结晶的影响尚未得到充分研究。在此，我们制作了五套不同碳含量的 IN738LC 样品，并对这些样品分别进行了两次热处理。在反向散射电子成像和电子反向散射衍射研究中对沉淀和晶粒演变进行了监测。虽然添加碳有助于解决热裂纹问题，但当总体碳含量超过 0.4 wt.%时，在制作大型样品时发现了水平分层裂纹，这突出表明在引入碳以解决热裂纹问题时需要小心谨慎。

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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Materials Science in Additive Manufacturing

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