Quality monitoring of projection welding using machine learning with small data sets

IF 3.7 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Science and Technology of Welding and Joining Pub Date : 2023-01-03 DOI:10.1080/13621718.2022.2162709

Johannes Koal, Tim Hertzschuch, Martin Baumgarten, J. Zschetzsche, U. Füssel

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引用次数: 2

Abstract

Capacitor discharge welding is an efficient, cost-effective and stable process. It is mostly used for projection welding. Real-time monitoring is desired to ensure quality. Until this point, measured process quantities were evaluated through expert systems. This method is strongly restricted to specific welding tasks and needs deep understanding of the process. Another possibility is quality prediction based on process data with machine learning. This requires classified welding experiments to achieve a high prediction probability. In industrial manufacturing, it is rarely possible to generate big sets classified data. Therefore, semi-supervised learning is investigated to enable model development on small data sets. Supervised learning models on large amounts of data are used as a comparison to the semi-supervised models. A total of 389 classified weld tests were performed. With semi-supervised learning methods, the amount of training data necessary was reduced to 31 classified data sets.

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基于小数据集的机器学习投影焊接质量监测

电容器放电焊接是一种高效、经济、稳定的焊接工艺。它主要用于投影焊接。需要实时监控以确保质量。在此之前，测量的过程数量是通过专家系统进行评估的。这种方法强烈限制于特定的焊接任务，需要对工艺有深入的了解。另一种可能性是基于机器学习过程数据的质量预测。这就需要对焊接实验进行分类，以达到较高的预测概率。在工业制造中，很少有可能产生大的分类数据集。因此，研究了半监督学习，以便在小数据集上开发模型。使用基于大量数据的监督学习模型与半监督学习模型进行比较。总共进行了389次分类焊接试验。使用半监督学习方法，所需的训练数据量减少到31个分类数据集。

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来源期刊

Science and Technology of Welding and Joining 工程技术-材料科学：综合

CiteScore

6.10

自引率

12.10%

发文量

审稿时长

1.7 months

期刊介绍： Science and Technology of Welding and Joining is an international peer-reviewed journal covering both the basic science and applied technology of welding and joining. Its comprehensive scope encompasses all welding and joining techniques (brazing, soldering, mechanical joining, etc.) and aspects such as characterisation of heat sources, mathematical modelling of transport phenomena, weld pool solidification, phase transformations in weldments, microstructure-property relationships, welding processes, weld sensing, control and automation, neural network applications, and joining of advanced materials, including plastics and composites.