利用工业物联网和卷积神经网络识别旋转机械子系统的失效状态——初步研究

IF 0.7 Q3 ENGINEERING, MULTIDISCIPLINARY
Davor Kolar, D. Lisjak, Martin Curman, Juraj Benić
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引用次数: 0

摘要

旋转部件几乎可以在行业中的所有操作设备中找到,对正确操作非常重要。然而,可靠性理论解释说,当故障发生时,每个工业系统都可以改变其状态。预测性维护是从维护4.0概念中产生的最新维护策略之一。如今,这一概念可以包括连接工业资产的工业物联网(IIoT)设备,从而实现数据收集和分析,有助于对维护活动做出更好的决策。稳健的数据采集系统是任何现代预测性维护任务的先决条件,因为它为行业资产的进一步分析和健康评估提供了必要的数据。考虑到早期状态变化诊断和故障识别可以防止系统故障,故障诊断是工业旋转子系统维护中的一项重要任务。振动分析在理论和实践中被认为是早期检测旋转子系统状态变化和故障诊断的正确技术。所确定的技术状态应在能力和不同的无能力状态的背景下进行考虑。因此,早期不同的失效状态识别是旋转机械诊断程序的下一步。大多数现有的使用振动的旋转子系统故障诊断技术都涉及从原始信号中提取特征的步骤。考虑到描述旋转子系统行为的特征可能因设备类型而异,这种方法通常需要信号处理和旋转子系统领域的专家来定义必要的特征。最近,机器深度学习的出现及其在维护中的应用有望提供高效的故障诊断,同时减少对专家知识和人力的需求。本文提出作者的目标是使用自行开发的IIoT系统作为IIoT加速度计作为边缘设备,web API和卷积神经网络数据库作为基于深度学习的数据驱动故障诊断,以检测和识别旋转子系统的不同失效状态。使用IIOT系统收集两种不同转速的大型数据集,并训练和测试多个卷积神经网络模型,以检查使用IIOT进行无力状态预测的可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Identification of Inability States of Rotating Machinery Subsystems Using Industrial IoT and Convolutional Neural Network – Initial Research
Rotating parts can be found in almost all operational equipment in the industry and are of great importance for proper operation. However, reliability theory explains that every industrial system can change its state when failure happens. Predictive maintenance as one of the latest maintenance strategy emerged from the Maintenance 4.0 concept. Nowadays, this concept can include Industrial Internet of Things (IIoT) devices to connect industrial assets thus enable data collection and analysis that can help make better decisions about maintenance activity. Robust data acquisition system is a prerequisite for any modern predictive maintenance task as it provides necessary data for further analysis and health assessment of the industry asset. Fault diagnosis is an important task in the maintenance of industrial rotating subsystems, considering that early state change diagnosis and fault identification can prevent system failure. Vibration analysis in theory and practice is considered a correct technique for early detection of state changes and failure diagnostics of rotating subsystems. The identified technical state should be considered in a context of the ability and different inability states. Therefore, early different inability states identification is the next step in the rotary machinery diagnostics procedure. Most of the existing techniques for fault diagnosis of rotating subsystems that use vibrations involve the step of extracting features from the raw signal. Considering that the features that describe the behavior of the rotary subsystem can differ significantly depending on the type of equipment, such an approach usually requires an expert in the field of signal processing and rotary subsystems who can define the necessary features. Recently, the emergence of machine deep learning and its application in maintenance promises to provide highly efficient fault diagnostics while simultaneously reducing the need for expert knowledge and human labour. This paper presents authors aim to use self-developed IIoT system built as an IIoT accelerometer as the edge device, web API and database with convolutional neural network as deep learning-based data-driven fault diagnosis to detect and identify different inability states of rotating subsystems. Large dataset for two different rotational speed is collected using IIOT system and multiple convolutional neural network models are trained and tested to examine possibility of using IIOT for inability state prediction.
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来源期刊
TEHNICKI GLASNIK-TECHNICAL JOURNAL
TEHNICKI GLASNIK-TECHNICAL JOURNAL ENGINEERING, MULTIDISCIPLINARY-
CiteScore
1.50
自引率
8.30%
发文量
85
审稿时长
15 weeks
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