Apply VGGNet-Based Deep Learning Model of Vibration Data for Prediction Model of Gravity Acceleration Equipment

arXiv: Signal Processing Pub Date : 2020-05-22 DOI:10.20944/preprints202012.0646.v1

Seonwoo Lee, HyeonTak Yu, HoJun Yang, Inseo Song, JaeHeung Yang, Gang-Min Lim, Kyusung Kim, Byeong-Keun Choi, Jangwoo Kwon

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Abstract

Hypergravity accelerators are a type of large machinery used for gravity training or medical research. A failure of such large equipment can be a serious problem in terms of safety or costs. This paper proposes a prediction model that can proactively prevent failures that may occur in a hy-pergravity accelerator. The method proposed in this paper was to convert vibration signals to spectograms and perform classification training using a deep learning model. An experiment was conducted to evaluate the performance of the method proposed in this paper. A 4-channel accel-erometer was attached to the bearing housing, which is a rotor, and time-amplitude data were obtained from the measured values by sampling. The data were converted to a two-dimensional spectrogram, and classification training was performed using a deep learning model for four conditions of the equipment: Unbalance, Misalignment, Shaft Rubbing, and Normal. The ex-perimental results showed that the proposed method had a 99.5% F1-Score, which was up to 23% higher than the 76.25% for existing feature-based learning models.

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基于vggnet的振动数据深度学习模型在重力加速度设备预测模型中的应用

超重力加速器是一种用于重力训练或医学研究的大型机械。这种大型设备的故障在安全或成本方面可能是一个严重的问题。提出了一种能够主动预防超重力加速器故障的预测模型。本文提出的方法是将振动信号转换为频谱，并使用深度学习模型进行分类训练。通过实验验证了该方法的性能。在作为转子的轴承座上安装了一个4通道加速度计，对测量值进行采样得到时幅数据。将数据转换为二维光谱图，并使用深度学习模型对设备的四种情况进行分类训练:不平衡、不对中、轴摩擦和正常。实验结果表明，该方法的F1-Score准确率为99.5%，比现有基于特征的学习模型的76.25%提高了23%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Signal Processing

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