Concise convolutional neural network model for fault detection

Muhammad Dzulqarnain Al Firdausi, Shafiq Ahmad
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引用次数: 0

Abstract

Fault detection is an urgent need for maintenance to obtain the optimal scheduling of production activities, improve system reliability, and reduce operation and maintenance costs. Many studies published in recent years focus on machine learning models to detect any system anomalies in line with the era of big data and the fourth industrial revolution (Industry 4.0). Say, a working condition of bearing can be monitored and then any fault can be detected using the vibration analysis of bearing acceleration data. Most of the published works are presented based upon the knowledge of signal processing in which the result depends heavily on feature extraction. It becomes a challenge then to apply a machine learning algorithm directly to the raw acceleration data as it has been successfully applied to raw data in other science and engineering domains. In this article, a concise Convolutional Neural Networks-based deep learning model is proposed for bearing fault detection. The proposed model was concise with 98% less number of parameters compared to other well-known models. It produced 21.21% and 7.03% better accuracy and fault detection rate, respectively. The model was also tested in different operating parameter environments and still gave an excellent result. Since the proposed concise architecture of the model needed short training time, it is deemed suitable for application on manufacturing floor where the pace of production moves fast and the change of the production machine configuration likely occurs.
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故障检测的简明卷积神经网络模型
故障检测是实现生产活动最优调度、提高系统可靠性、降低运维成本的维护迫切需要。近年来发表的许多研究都集中在机器学习模型上,以检测符合大数据时代和第四次工业革命(工业4.0)的任何系统异常。例如,可以监测轴承的工作状态,然后使用轴承加速度数据的振动分析来检测任何故障。大多数已发表的作品都是基于信号处理的知识提出的,其中结果严重依赖于特征提取。因此,将机器学习算法直接应用于原始加速度数据成为一个挑战,因为它已经成功地应用于其他科学和工程领域的原始数据。本文提出了一种简明的基于卷积神经网络的轴承故障检测深度学习模型。与其他已知模型相比,该模型简洁,参数数量减少98%。准确率和故障检出率分别提高了21.21%和7.03%。该模型还在不同的操作参数环境下进行了测试,仍然取得了良好的效果。由于所提出的模型结构简洁,训练时间短,因此适合于生产节奏快、生产机器配置可能发生变化的制造车间。
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来源期刊
Communications in Science and Technology
Communications in Science and Technology Engineering-Engineering (all)
CiteScore
3.20
自引率
0.00%
发文量
13
审稿时长
24 weeks
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