Analysis of Wire Rolling Processes Using Convolutional Neural Networks

Matheus Capelin, Gustavo Aristides Santana Martínez, Yutao Xing, Adriano Francisco Siqueira, Wei-Liang Qian
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Abstract

This study leverages machine learning to analyze the cross-sectional profiles of materials subjected to wire-rolling processes, focusing on the specific stages of these processes and the characteristics of the resulting microstruc - tural profiles. The convolutional neural network (CNN), a potent tool for visual feature analysis and learning, is utilized to explore the properties and impacts of the cold plastic deformation technique. Specifically, CNNs are constructed and trained using 6400 image segments, each with a resolution of 120 × 90 pixels. The chosen ar - chitecture incorporates convolutional layers intercalated with polling layers and the “ReLu” activation function. The results, intriguingly, are derived from the observation of only a minuscule cropped fraction of the material’s cross-sectional profile. Following calibration two distinct neural networks, training and validation accuracies of 97.4%/97% and 79%/75% have been achieved. These accuracies correspond to identifying the cropped image’s location and the number of passes applied to the material. Further improvements in accuracy are reported upon integrating the two networks using a multiple-output setup, with the overall training and validation accuracies slightly increasing to 98.9%/79.4% and 94.6%/78.1%, respectively, for the two features. The study emphasizes the pivotal role of specific architectural elements, such as the rescaling parameter of the augmentation process, in attaining a satisfactory prediction rate. Lastly, we delve into the potential implications of our findings, which shed light on the potential of machine learning techniques in refining our understanding of wire-rolling processes and guiding the development of more efficient and sustainable manufacturing practices.
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使用卷积神经网络分析轧线工艺
本研究利用机器学习来分析经过线材轧制过程的材料横截面轮廓,重点关注这些过程的特定阶段以及由此产生的微观结构轮廓的特征。卷积神经网络(CNN)是视觉特征分析和学习的有效工具,它被用来探索冷塑性变形技术的特性和影响。具体来说,利用分辨率为 120 × 90 像素的 6400 个图像片段构建和训练 CNN。所选的架构包括卷积层、轮询层和 "ReLu "激活函数。有趣的是,这些结果仅仅是通过观察材料横截面剖面的一小部分而得出的。校准两个不同的神经网络后,训练和验证精确度分别达到 97.4%/97% 和 79%/75% 。这些精确度与识别裁剪图像的位置和材料的通过次数相对应。使用多输出设置整合两个网络后,准确率进一步提高,两个特征的总体训练和验证准确率分别略微提高到 98.9%/79.4% 和 94.6%/78.1% 。这项研究强调了特定结构元素(如增强过程的重缩放参数)在获得令人满意的预测率方面的关键作用。最后,我们深入探讨了研究结果的潜在影响,这些影响揭示了机器学习技术在完善我们对轧线工艺的理解以及指导开发更高效、更可持续的生产实践方面的潜力。
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