In-situ 3D temperature field modeling and characterization using eddy current for metal additive manufacturing process monitoring.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-03-22 DOI:10.1038/s41598-025-94553-6

Lei Peng, Edward Benavidez, Saptarshi Mukherjee, Rosa E Morales, Joseph W Tringe, David Stobbe, Yiming Deng

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Abstract

Metal additive manufacturing (AM) is a critical capability for Industry 4.0, with particular potential in the aerospace and medical industries. Its ability to create dense metal parts with intricate geometries makes it appealing for demanding environments requiring specific thermal and mechanical properties, as well as long-term reliability. Despite its potential, challenges such as low surface quality and buried porosity have impeded the widespread adoption of metal AM. Therefore, advances such as real-time monitoring of AM processes are necessary to realize the full capability of these new manufacturing methods. Here we examine the feasibility of one promising approach: eddy current (EC) measurements for in-situ LPBF AM temperature monitoring, which is different from existing EC method to monitor near surface porosity or crack. The temperature-dependent electrical conductivity of many materials used in AM processes suggests it may be possible to measure the internal temperature using an eddy current probe. These measurements of the temperature history could then inform the quality of build layers, such as internal stress, which would otherwise be inaccessible to characterization. We first developed a thermally-coupled electromagnetic simulation to examine this phenomenon. Our model reveals a complex internal temperature distribution created during dynamic laser heating processes. Notably, the simulation also indicates that the EC response can dynamically reflect the temperature of the AM material during both the heating and cooling processes. We performed experiments to validate our simulations, using a soldering iron tip as a point heating source on a metal plate, together with a commercial EC apparatus. The results showed that this method can achieve real-time temperature monitoring in the range 420-700 K, suggesting potential for addressing a critical need process monitoring need for enhancing metal AM processes.

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基于涡流的金属增材制造过程现场三维温度场建模与表征。

金属增材制造（AM）是工业4.0的一项关键能力，在航空航天和医疗行业尤其具有潜力。它能够制造具有复杂几何形状的致密金属部件，这使得它对需要特定热学和机械性能以及长期可靠性的苛刻环境具有吸引力。尽管具有潜力，但表面质量低和埋藏孔隙率等挑战阻碍了金属增材制造的广泛采用。因此，为了实现这些新的制造方法的全部能力，需要诸如实时监控增材制造过程之类的进步。本文研究了一种有前景的方法的可行性：涡流测量（EC）用于LPBF AM的原位温度监测，它不同于现有的EC方法来监测近表面孔隙度或裂缝。在增材制造过程中使用的许多材料的温度依赖电导率表明，使用涡流探头测量内部温度是可能的。这些温度历史的测量可以告知构建层的质量，例如内应力，否则将无法进行表征。我们首先开发了一种热耦合电磁模拟来研究这种现象。我们的模型揭示了动态激光加热过程中产生的复杂内部温度分布。值得注意的是，模拟还表明，在加热和冷却过程中，EC响应可以动态地反映AM材料的温度。我们进行了实验来验证我们的模拟，使用烙铁头作为金属板上的点热源，以及商用EC设备。结果表明，该方法可以实现420-700 K范围内的实时温度监测，这表明该方法有可能解决提高金属增材制造工艺的关键过程监测需求。

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

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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