Development of Compartment Models for Diagnostic Purposes

IF 0.5 Q4 ENGINEERING, CHEMICAL

Hungarian Journal of Industry and Chemistry Pub Date : 2021-09-21 DOI:10.33927/hjic-2021-07

B. Tarcsay, Ágnes Bárkányi, T. Chován, S. Németh

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引用次数: 0

Abstract

The importance of recognizing the presence of process faults and resolving these faults is continuously increasing parallel to the development of industrial processes. Fault detection methods which are both robust and sensitive help to recognize the presence of faults in time to avoid malfunctions, financial loss, environmental damage or loss of human life. In the literature, the use of various model-based fault detection methods has gained a considerable degree of popularity. Methods usually based on black-box models, data-based techniques or models using symbolic logic, e.g.\ expert systems, have become widespread. White-box models, on the other hand, have been applied less despite their considerable robustness because of multiple reasons. Firstly, their complexity and the relatively vast amount of technological and modelling knowledge needed to construct them for industrial systems. Secondly, their large computational demand which makes them less suitable for online fault detection. In this study, the aim was to resolve these problems by developing a method to simplify the complex Computational Fluid Dynamics models employed to describe the equipment used in the chemical industry into less complex model structures. These simpler structures are Compartment Models, a type of white-box model which breaks down a complex system into smaller units with idealized behaviour. In the case of a small number of compartments, the computational load of such models is not significant, therefore, they can be employed for the purposes of online fault detection while providing an accurate representation of the system. For the purpose of identifying the compartmental structure, fuzzy logic was employed to create a model which approximates the real behaviour of the system as accurately as possible. Our future objective is to explore the possibility of combining this model with various diagnostic methods (expert systems, Bayesian networks, parity relations, etc.) and derive robust tools for the purpose of fault detection.

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用于诊断目的的舱室模型的开发

随着工业过程的发展，识别过程故障并解决这些故障的重要性不断增加。故障检测方法既稳健又灵敏，有助于及时识别故障的存在，避免故障、经济损失、环境破坏或人员生命损失。在文献中，各种基于模型的故障检测方法的使用已经获得了相当程度的普及。通常基于黑盒模型、基于数据的技术或使用符号逻辑的模型的方法，例如专家系统，已经变得广泛。另一方面，由于多种原因，尽管白盒模型具有相当大的稳健性，但其应用较少。首先，它们的复杂性以及为工业系统构建它们所需的相对大量的技术和建模知识。其次，它们的计算量大，不太适合在线故障检测。在这项研究中，目的是通过开发一种方法来解决这些问题，将用于描述化学工业中使用的设备的复杂计算流体动力学模型简化为不太复杂的模型结构。这些更简单的结构是隔室模型，这是一种白盒模型，它将复杂的系统分解为具有理想化行为的较小单元。在少数隔间的情况下，这种模型的计算负载并不显著，因此，它们可以用于在线故障检测，同时提供系统的准确表示。为了识别隔室结构，使用模糊逻辑来创建一个模型，该模型尽可能准确地近似系统的真实行为。我们未来的目标是探索将该模型与各种诊断方法（专家系统、贝叶斯网络、奇偶关系等）相结合的可能性，并推导出用于故障检测的稳健工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Hungarian Journal of Industry and Chemistry ENGINEERING, CHEMICAL-

自引率

50.00%

发文量

审稿时长

6 weeks