Deep-learning based artificial intelligence tool for melt pools and defect segmentation

IF 5.9 2区 工程技术 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Amra Peles, Vincent C. Paquit, Ryan R. Dehoff
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引用次数: 0

Abstract

Accelerating fabrication of additively manufactured components with precise microstructures is important for quality and qualification of built parts, as well as for a fundamental understanding of process improvement. Accomplishing this requires fast and robust characterization of melt pool geometries and structural defects in images. This paper proposes a pragmatic approach based on implementation of deep learning models and self-consistent workflow that enable systematic segmentation of defects and melt pools in optical images. Deep learning is based on an image-to-image translation–conditional generative adversarial neural network architecture. An artificial intelligence (AI) tool based on this deep learning model enables fast and incrementally more accurate predictions of the prevalent geometric features, including melt pool boundaries and printing-induced structural defects. We present statistical analysis of geometric features that is enabled by the AI tool, showing strong spatial correlation of defects and the melt pool boundaries. The correlations of widths and heights of melt pools with dataset processing parameters show the highest sensitivity to thermal influences resulting from laser passes in adjacent and subsequent layer passes. The presented models and tools are demonstrated on the aluminum alloy and datasets produced with different sets of processing parameters. However, they have universal quality and could easily be adapted to different material compositions. The method can be easily generalized to microstructural characterizations other than optical microscopy.

Abstract Image

基于深度学习的人工智能工具,用于熔池和缺陷分割
加速制造具有精确微观结构的快速成型部件,对于保证制造部件的质量和合格性,以及从根本上了解工艺改进非常重要。要做到这一点,就需要对图像中的熔池几何形状和结构缺陷进行快速、稳健的表征。本文提出了一种基于深度学习模型和自洽工作流程的实用方法,可对光学图像中的缺陷和熔池进行系统分割。深度学习基于图像到图像平移条件生成对抗神经网络架构。基于该深度学习模型的人工智能(AI)工具能够快速、逐步更准确地预测普遍存在的几何特征,包括熔池边界和印刷引起的结构缺陷。我们利用人工智能工具对几何特征进行了统计分析,结果表明缺陷和熔池边界具有很强的空间相关性。熔池的宽度和高度与数据集加工参数的相关性表明,相邻层和后续层的激光通过对热影响的敏感性最高。所介绍的模型和工具在铝合金和使用不同加工参数生成的数据集上进行了演示。不过,它们具有通用性,很容易适用于不同的材料成分。除光学显微镜外,该方法还可轻松应用于微观结构表征。
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来源期刊
Journal of Intelligent Manufacturing
Journal of Intelligent Manufacturing 工程技术-工程:制造
CiteScore
19.30
自引率
9.60%
发文量
171
审稿时长
5.2 months
期刊介绍: The Journal of Nonlinear Engineering aims to be a platform for sharing original research results in theoretical, experimental, practical, and applied nonlinear phenomena within engineering. It serves as a forum to exchange ideas and applications of nonlinear problems across various engineering disciplines. Articles are considered for publication if they explore nonlinearities in engineering systems, offering realistic mathematical modeling, utilizing nonlinearity for new designs, stabilizing systems, understanding system behavior through nonlinearity, optimizing systems based on nonlinear interactions, and developing algorithms to harness and leverage nonlinear elements.
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