L-PBF High-Throughput Data Pipeline Approach for Multi-modal Integration

IF 2.4 3区材料科学 Q3 ENGINEERING, MANUFACTURING Integrating Materials and Manufacturing Innovation Pub Date : 2024-07-19 DOI:10.1007/s40192-024-00368-0

Kristen J. Hernandez, Thomas G. Ciardi, Rachel Yamamoto, Mingjian Lu, Arafath Nihar, Jayvic Cristian Jimenez, Pawan K. Tripathi, Brian Giera, Jean-Baptiste Forien, John J. Lewandowski, Roger H. French, Laura S. Bruckman

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Abstract

Metal-based additive manufacturing requires active monitoring solutions for assessing part quality. Multiple sensors and data streams, however, generate large heterogeneous data sets that are impractical for manual assessment and characterization. In this work, an automated pipeline is developed that enables feature extraction from high-speed camera video and multi-modal data analysis. The framework removes the need for manual assessment through the utilization of deep learning techniques and training models in a weakly supervised paradigm. We demonstrate this pipeline’s capability over 700,000 high-speed camera frames. The pipeline successfully extracts melt pool and spatter geometries and links them to corresponding pyrometry, radiography, and processparameter information. 715 individual prints are examined to reveal melt pool areas that exceeds 0.07 mm² and pyrometry signal over a threshold (375 pyrometry units) were more likely to have defects. These automated processes enable massive throughput of characterization techniques.

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用于多模式集成的 L-PBF 高通量数据管道方法

基于金属的快速成型制造需要主动监测解决方案来评估零件质量。然而，多个传感器和数据流会产生大量异构数据集，人工评估和表征不切实际。在这项工作中，开发了一个自动管道，可从高速摄像视频和多模态数据分析中提取特征。该框架通过利用深度学习技术和弱监督范式中的训练模型，消除了人工评估的需要。我们在 700,000 个高速摄像帧上演示了这一管道的能力。该管道成功提取了熔池和喷溅几何图形，并将它们与相应的高温测量、射线照相和工艺参数信息联系起来。对 715 个印花进行检查，发现熔池面积超过 0.07 平方毫米和高温测量信号超过临界值（375 个高温测量单位）的印花更有可能存在缺陷。这些自动化流程实现了表征技术的高吞吐量。

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来源期刊

Integrating Materials and Manufacturing Innovation Engineering-Industrial and Manufacturing Engineering

CiteScore

5.30

自引率

9.10%

发文量

审稿时长

39 days

期刊介绍： The journal will publish: Research that supports building a model-based definition of materials and processes that is compatible with model-based engineering design processes and multidisciplinary design optimization; Descriptions of novel experimental or computational tools or data analysis techniques, and their application, that are to be used for ICME; Best practices in verification and validation of computational tools, sensitivity analysis, uncertainty quantification, and data management, as well as standards and protocols for software integration and exchange of data; In-depth descriptions of data, databases, and database tools; Detailed case studies on efforts, and their impact, that integrate experiment and computation to solve an enduring engineering problem in materials and manufacturing.