知识增强时空分析用于流程制造中的异常检测

IF 8.2 1区 计算机科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Computers in Industry Pub Date : 2024-05-31 DOI:10.1016/j.compind.2024.104111
Louis Allen , Haiping Lu , Joan Cordiner
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引用次数: 0

摘要

有效的故障检测和诊断(FDD)对于主动识别可能危及操作员健康和流程完整性的异常状态至关重要。在工业 4.0 时代,由于存储的制造传感器数据激增,数据驱动的故障检测和诊断技术受到了特别关注。虽然这些方法已被证明善于对既定的流程故障情景进行分类,但仍有必要识别和解释源于未知故障或连续异常的相互作用的异常情况。为此,我们提出了一种知识增强型 FDD 方法,该方法将定义明确的化学工程知识与最先进的深度学习技术相结合。我们采用名为知识增强时空分析(KESA)的方法来识别可能是故障前兆的异常过程条件。此外,我们还利用管理流程的基本关系知识来解释故障发生的原因。这种深入的故障分析只有通过利用领域专业知识才能实现,与现有文献相比,标志着 FDD 技术向前迈进了一步。通过使用基准田纳西伊士曼流程数据集,我们确定了 KESA 模型的准确性和效率优于最先进的 FDD 算法。这项工作突出了在复杂环境中采用知识增强型深度学习方法的重要性,强调了及时、可解释的故障检测的关键作用。通过为模型结果提供解释,我们的 KESA 框架不仅有助于有效决策,还有可能显著缩短故障检测与实施主动缓解措施之间的时间。这种能力对于提高整体安全性、最大限度地减少停机时间以及最终为工业流程节省大量成本至关重要。
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Knowledge-Enhanced Spatiotemporal Analysis for Anomaly Detection in Process Manufacturing

Effective fault detection and diagnosis (FDD) is crucial for proactively identifying irregular states that could jeopardize operator well-being and process integrity. In the era of Industry 4.0, data-driven FDD techniques have received particular attention, driven by the proliferation of stored manufacturing sensor data. While these methods have proven adept at categorizing established process fault scenarios, there remains an imperative to identify and explain anomalies stemming from uncharted faults or the interplay of consecutive anomalies. To address this we present a knowledge-enhanced FDD approach that integrates well-defined chemical engineering knowledge with cutting-edge deep learning techniques. We apply our methodology, named Knowledge-Enhanced Spatiotemporal Analysis (KESA), to identify abnormal process conditions that may be a precursor to failure. Furthermore, we utilize the knowledge of the fundamental relationships governing the process to explain why this fault case has occurred. This type of in-depth fault analysis is only possible through leveraging domain expertise and marks a step forward in FDD technology in comparison to current literature. Using the benchmark Tennessee Eastman process dataset, we establish superiority in the accuracy and efficiency of our KESA model against state-of-the-art FDD algorithms. This work highlights the importance of a knowledge-enhanced approach to deep learning in complex environments, emphasizing the critical role of timely and interpretable fault detection. By providing explanations for model results, our KESA framework not only aids in effective decision-making but also has the potential to significantly reduce the time between fault detection and the implementation of proactive mitigation actions. This capability is paramount for improving overall safety, minimizing downtime, and ultimately contributing to substantial cost savings in industrial processes.

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来源期刊
Computers in Industry
Computers in Industry 工程技术-计算机:跨学科应用
CiteScore
18.90
自引率
8.00%
发文量
152
审稿时长
22 days
期刊介绍: The objective of Computers in Industry is to present original, high-quality, application-oriented research papers that: • Illuminate emerging trends and possibilities in the utilization of Information and Communication Technology in industry; • Establish connections or integrations across various technology domains within the expansive realm of computer applications for industry; • Foster connections or integrations across diverse application areas of ICT in industry.
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