Feature-based statistical process monitoring for pressure swing adsorption processes

IF 2.5 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Frontiers in chemical engineering Pub Date : 2022-11-18 DOI:10.3389/fceng.2022.1064221
Jangwon Lee, Ankur Kumar, Jesus Flores-Cerrillo, Jin Wang, Q. He
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Abstract

Pressure swing adsorption (PSA) is a widely used technology to separate a gas product from impurities in a variety of fields. Due to the complexity of PSA operations, process and instrument faults can occur at different parts and/or steps of the process. Thus, effective process monitoring is critical for ensuring efficient and safe operations of PSA systems. However, multi-bed PSA processes present several major challenges to process monitoring. First, a PSA process is operated in a periodic or cyclic fashion and never reaches a steady state; Second, the duration of different operation cycles is dynamically controlled in response to various disturbances, which results in a wide range of normal operation trajectories. Third, there is limited data for process monitoring, and bed pressure is usually the only measured variable for process monitoring. These key characteristics of the PSA operation make process monitoring, especially early fault detection, significantly more challenging than that for a continuous process operated at a steady state. To address these challenges, we propose a feature-based statistical process monitoring (SPM) framework for PSA processes, namely feature space monitoring (FSM). Through feature engineering and feature selection, we show that FSM can naturally handle the key challenges in PSA process monitoring and achieve early detection of subtle faults from a wide range of normal operating conditions. The performance of FSM is compared to the conventional SPM methods using both simulated and real faults from an industrial PSA process. The results demonstrate FSM’s superior performance in fault detection and fault diagnosis compared to the traditional SPM methods. In particular, the robust monitoring performance from FSM is achieved without any data preprocessing, trajectory alignment or synchronization required by the conventional SPM methods.
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基于特征的变压吸附过程统计监测
变压吸附(PSA)是一种广泛应用于各种领域的气体产品与杂质分离技术。由于PSA操作的复杂性,过程和仪器故障可能发生在过程的不同部分和/或步骤。因此,有效的过程监控对于确保PSA系统的高效和安全运行至关重要。然而,多床PSA工艺对过程监控提出了几个主要挑战。首先,PSA过程以周期性或循环的方式运行,永远不会达到稳定状态;其次,不同运行周期的持续时间是动态控制的,以响应各种干扰,这导致了广泛的正常运行轨迹。第三,过程监测的数据有限,床层压力通常是过程监测的唯一测量变量。PSA操作的这些关键特征使得过程监控,特别是早期故障检测,比在稳定状态下连续运行的过程更具挑战性。为了解决这些挑战,我们提出了一个基于特征的PSA过程统计过程监控(SPM)框架,即特征空间监控(FSM)。通过特征工程和特征选择,我们表明FSM可以自然地处理PSA过程监控中的关键挑战,并在广泛的正常运行条件下实现对细微故障的早期检测。利用工业PSA过程中的模拟故障和真实故障,将FSM的性能与传统的SPM方法进行了比较。结果表明,与传统的SPM方法相比,FSM在故障检测和故障诊断方面具有优越的性能。特别是,FSM的鲁棒监控性能无需传统SPM方法所需的任何数据预处理、轨迹对齐或同步。
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CiteScore
3.50
自引率
0.00%
发文量
0
审稿时长
13 weeks
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