Photodiode-based porosity prediction in laser powder bed fusion considering inter-hatch and inter-layer effects

IF 6.7 2区 材料科学 Q1 ENGINEERING, INDUSTRIAL
Zhengrui Tao , Aditi Thanki , Louca Goossens , Ann Witvrouw , Bey Vrancken , Wim Dewulf
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引用次数: 0

Abstract

Laser powder bed fusion, while promising, faces hurdles in certifying fabricated parts due to cost and complexity, with in-process monitoring emerging as a potential solution. Existing models focus on predicting defects at a given location using the monitoring signals from solely that same location. Hence, these models treat each track or layer independently of the previous and subsequent ones, neglecting potential interdependencies. This study proposed an in-situ, photodiode-based monitoring approach considering inter-hatch and inter-layer effects on porosity formation - factors often overlooked in existing research. Two Ti-6Al-4 V cuboids (10×10×5 mm3) were built with optimized process parameters, with the melt pool continuously monitored at 20 kHz via a co-axially mounted photodiode. The monitoring system captured the integral radiation in the near-infrared spectrum within a field of view centered on the melt pool. The porosity is assessed by X-ray computed tomography (X-CT), serving as ground truth to build supervised machine learning (ML) models. This study considered physical phenomena occurring during the printing process, including remelting of lack of fusion pores by the subsequent layer, keyholes penetrating the current layer hence introducing pores in the layer below, and overlap between adjacent scan tracks. These considerations are critical for a holistic understanding of pore formation mechanisms. Photodiode signals and computed tomography volumes were cropped using windows of four sizes to test the model's pore localization capability. A machine learning model, specifically a Convolutional Neural Network (CNN) - Long Short-Term Memory (LSTM) network, was trained to predict porosities using these window sequences. The CNN extracted spatial features from photodiode signals, addressing inter-hatch effects, while the LSTM captured temporal dependencies across layers, addressing inter-layer effects. The results, with the Area Under the Receiver Operating Characteristic curve (AUC) of 0.91 for pores exceeding 8000 μm3 in volume and 100 μm2 in cross-sectional area, demonstrate the feasibility of the proposed model in detecting pores-level defects. This high defect prediction and positioning accuracy are essential for process control, providing real-time status of the region of interest and informing the controller of pore positions, thus facilitating intra-layer or inter-layer correction.

基于光电二极管的激光粉末床熔融孔隙率预测,考虑到舱口间和层间效应
激光粉末床熔融技术虽然前景广阔,但由于成本和复杂性,在对制造的部件进行认证方面面临着障碍,而过程中监测则成为一种潜在的解决方案。现有模型的重点是利用来自特定位置的监测信号预测该位置的缺陷。因此,这些模型在处理每个轨道或层时都独立于前一个或后一个轨道或层,忽略了潜在的相互依存关系。本研究提出了一种基于光电二极管的原位监测方法,该方法考虑了舱口间和层间对气孔形成的影响--这些因素在现有研究中经常被忽视。采用优化的工艺参数制造了两个 Ti-6Al-4 V 立方体(10×10×5 mm3),通过同轴安装的光电二极管以 20 kHz 的频率对熔池进行连续监测。监测系统捕捉以熔池为中心视场内的近红外光谱积分辐射。孔隙率通过 X 射线计算机断层扫描(X-CT)进行评估,作为建立有监督机器学习(ML)模型的基本事实。这项研究考虑了印刷过程中出现的物理现象,包括后续层对缺乏熔融孔隙的重熔、穿透当前层从而在下面层中引入孔隙的键孔以及相邻扫描轨迹之间的重叠。这些因素对于全面了解孔隙形成机制至关重要。为了测试模型的孔隙定位能力,使用四种尺寸的窗口对光二极管信号和计算机断层扫描体积进行了裁剪。通过训练机器学习模型,特别是卷积神经网络(CNN)-长短期记忆(LSTM)网络,利用这些窗口序列预测孔隙度。卷积神经网络从光电二极管信号中提取空间特征,以解决间隙效应问题,而 LSTM 则捕捉跨层的时间依赖性,以解决层间效应问题。结果显示,对于体积超过 8000 μm3 和横截面积超过 100 μm2 的孔隙,接收者工作特征曲线下面积 (AUC) 为 0.91,这证明了所提模型在检测孔隙级缺陷方面的可行性。这种高缺陷预测和定位精度对过程控制至关重要,可提供相关区域的实时状态,并告知控制器孔隙位置,从而促进层内或层间校正。
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来源期刊
Journal of Materials Processing Technology
Journal of Materials Processing Technology 工程技术-材料科学:综合
CiteScore
12.60
自引率
4.80%
发文量
403
审稿时长
29 days
期刊介绍: The Journal of Materials Processing Technology covers the processing techniques used in manufacturing components from metals and other materials. The journal aims to publish full research papers of original, significant and rigorous work and so to contribute to increased production efficiency and improved component performance. Areas of interest to the journal include: • Casting, forming and machining • Additive processing and joining technologies • The evolution of material properties under the specific conditions met in manufacturing processes • Surface engineering when it relates specifically to a manufacturing process • Design and behavior of equipment and tools.
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