基于深度学习的增材制造熔池实时分类研究

Zhuo Yang, Yan Lu, H. Yeung, S. Krishnamurty
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引用次数: 36

摘要

一致的熔池几何是稳定的激光粉末床熔融(L-PBF)增材制造工艺的一个指标。熔池大小和形状反映了工艺参数和扫描路径对激光与粉末材料相互作用、过程中材料的相变和流动动力学的影响。目前的L-PBF工艺是基于预定的工具路径和加工参数进行操作的,因此缺乏对意外熔池变化做出反应的能力。本文研究了如何对熔池进行实时表征以进行反馈控制。为了快速准确地分析熔池大小,提出了一种基于深度学习的熔池分类方法。该分类器基于卷积神经网络,使用蛇形扫描策略从激光熔化粉末融合构建中捕获的2763张熔池图像进行训练。该模型通过使用“岛”蛇形策略从同一构建的不同部分收集的2926张新图像进行验证,预测准确率为91%。与传统的图像分析方法相比,验证图像的处理时间缩短了90%,从9.72 s减少到0.99 s,反馈控制的反应时间窗口为0.34 ms/图像。结果表明,该方法对L-PBF过程的实时闭环控制是可行的。
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Investigation of Deep Learning for Real-Time Melt Pool Classification in Additive Manufacturing
Consistent melt pool geometry is an indicator of a stable laser powder bed fusion (L-PBF) additive manufacturing process. Melt pool size and shape reflect the impact of process parameters and scanning path on the interaction between the laser and the powder material, the phase change and the flow dynamics of the material during the process. Current L-PBF processes are operated based on predetermined toolpaths and processing parameters and consequently lack the ability to make reactions to unexpected melt pool changes. This paper investigated how melt pool can be characterized in real-time for feedback control. A deep learning-based melt pool classification method is developed to analyze melt pool size both fast and accurately. The classifier, based on a convolutional neural network, was trained with 2763 melt pool images captured from a laser melting powder fusion build using a serpentine scan strategy. The model is validated through 2926 new images collected from a different part in the same build using ‘island’ serpentine strategy with predictive accuracy of 91%. Compared to a traditional image analysis method, the processing time of the validation images is reduced by 90 %, from 9.72 s to 0.99 s, which gives the feedback control a reaction time window of 0.34 ms/image. Results show the feasibility of the proposed method for a real-time closed loop control of L-PBF process.
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