在系统信号有限的情况下,用于旋转机械工业故障诊断的面向周期调制的抗噪相关方法。

IF 6.3 2区 计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS
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引用次数: 0

摘要

部件局部缺陷引起的周期脉冲是旋转机械故障检测和诊断的重要特征信息。近年来,许多基于频谱分析的信号处理方法被开发出来并得到验证,成为从测量到的复杂信号中挖掘与故障相关的重复瞬态的有力工具。然而,在实际应用中,由于系统信号可用性有限、复杂噪声干扰下信息提取不完整等制约因素,这些方法的应用可能会受到严重限制。针对上述问题,本文提出了一种面向周期调制的抗噪声相关(PMONRC)方法,用于旋转机械的目标周期检测和故障诊断。首先,通过一种新颖的序列程序,即信号元素逐次平方、频谱基尼指数引导的自适应低通滤波和信号元素逐次平方根计算,获得原始信号的包络,以突出更有可能与潜在故障诱发周期相关的调制波成分。随后,利用包络信号构建一系列子信号,这些子信号可以编码与故障相关的重复信息并增强抗噪能力。根据包络信号和获得的子信号,在基于 L 时刻比的指标和 Sigmoid 变换的帮助下,可以得出加权包络抗噪相关函数。最后,旋转机械的具体故障类型就能得到相应的识别和确认。所提出的 PMONRC 方法是非参数的,完全适应被处理信号本身,克服了基于频谱分析方法的不足,适用于系统信号受限和信噪比(SNR)较低的工程环境,具有巨大的实用价值。仿真分析和实验验证都深刻表明,所提出的方法优于其他现有的先进时域相关方法。此外,作为应用该方法的尝试和范例,还介绍和讨论了著名实验平台 PRONOSTIA 中基于 PMONRC 的滚动轴承数据的初期故障诊断结果,以进一步阐明所提方法的有效性和实际工程意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A periodic-modulation-oriented noise resistant correlation method for industrial fault diagnostics of rotating machinery under the circumstances of limited system signal availability

The periodical impulses caused by localized defects of components are the vital characteristic information for fault detection and diagnosis of rotating machines. In recent years, multitudinous spectrum analysis-based signal processing methods have been developed and authenticated as the powerful tools for excavating fault-related repetitive transients from the measured complex signals. Nonetheless, in practice, their applications can be severely confined by the constraints of limited system signal availability and incomplete information extraction under intricate noise interferences. To tackle the aforementioned issues, this paper proposes a periodic-modulation-oriented noise resistant correlation (PMONRC) method for target period detection and fault diagnosis of rotating machinery. Firstly, the envelope of raw signal is obtained via a novel sequential procedure of signal element-wise squaring, spectral Gini index-guided adaptive low-pass filtering, and signal element-wise square root computation, to highlight the modulated wave component that is more likely to be related to the potential fault-induced periods. Subsequently, a series of sub-signals, which can encode the fault-related repetitive information and enhance noise resistance, are constructed utilizing the envelope signal. Based upon the envelope signal and the obtained sub-signals, a weighted envelope noise resistant correlation function can be derived with the assistance of the L-moment ratio-based indicator and Sigmoid transformation. Finally, the specific fault type of the rotating machinery can be identified and affirmed accordingly. The proposed PMONRC method, which is nonparametric and completely adaptive to the signal being processed itself, overcomes the deficiencies of spectral analysis-based approaches, and is applicable for the engineering circumstances of system signal limitation and low signal-to-noise ratio (SNR), possessing immense practical merit. Both simulation analyses and experimental validations profoundly demonstrate that the proposed method is superior to other existing state-of-the-art time-domain correlation methods. Moreover, as an attempt as well as exemplar to apply this method, the PMONRC-based incipient fault diagnostic results of rolling bearing data from the well-known experimental platform PRONOSTIA are presented and discussed as well, to further elucidate the effectiveness and practical engineering significance of the proposed method.

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来源期刊
ISA transactions
ISA transactions 工程技术-工程:综合
CiteScore
11.70
自引率
12.30%
发文量
824
审稿时长
4.4 months
期刊介绍: ISA Transactions serves as a platform for showcasing advancements in measurement and automation, catering to both industrial practitioners and applied researchers. It covers a wide array of topics within measurement, including sensors, signal processing, data analysis, and fault detection, supported by techniques such as artificial intelligence and communication systems. Automation topics encompass control strategies, modelling, system reliability, and maintenance, alongside optimization and human-machine interaction. The journal targets research and development professionals in control systems, process instrumentation, and automation from academia and industry.
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