在设计阶段利用功能模型确定紧急停车的安全目标和功能

Q3 Chemical Engineering

Chemical engineering transactions Pub Date : 2021-06-15 DOI:10.3303/CET2186162

Jing Wu, Mengchu Song, Xinxin Zhang, M. Lind

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引用次数: 0

摘要

本文提出了一种多级流模型(MFM)的功能建模方法，用于紧急停车系统在设计阶段的安全目标和功能识别。首先，分析了设计紧急停机安全目标和功能所需的信息。这些信息包括工艺拓扑、工艺的初始状态、停机目标和其他约束，例如单元操作的设计和操作限制以及危险和环境约束。其次，提出了一种基于所需信息的MFM处理方法。该程序包括以下步骤:1)按照以下建模步骤建立过程正常运行时的MFM模型;2)利用MFM建模中的目标函数树，定义过程计划外停机时的启动状态，识别过程的变化条件;3)定义停机操作的目标;5)基于MFM模型中表示的第一个安全函数，利用MFM结果推理，识别出停机过程中的第一个安全函数，并生成紧急停机程序。通过设计海水注入系统中海水除氧过程的紧急关闭中的安全功能，证明了这一程序。结果表明，基于该方法的应急停机程序是可行的，并可与实际运行程序进行对比验证。

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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Identifying Safety Objectives and Functions for Emergency Shutdown in the Design Phase by Using Functional Modelling

This paper proposes a functional modelling method, called Multilevel Flow Modelling (MFM) for identification of safety objectives and functions of emergency shutdown (ESD) system in the design phase for emergency shutdown safely. Firstly, the required information for designing safety objectives and functions for an emergency shutdown is analysed. The information includes process topology, the initial state of the process, the shutdown objectives, and other constraints, such as design and operational limits of unit operations and hazardous and environmental constraints. Secondly, a procedure is proposed based on the required information by using MFM. The procedure incorporates steps: 1) The MFM model of the process in normal operations are built by following modelling procedures, 2) Initiate states are defined and changing conditions are identified of the process when it shuts down unplanned by using the objective-function tree in the MFM modelling, 3) The goals of the shutdown operation are defined, 4) With the consideration of the shutdown operating goals and changing conditions, the first safety function during shutdown process are identified by using MFM causal reasoning, 5) By using MFM consequence reasoning based on the first identified safety function represented in the MFM model, the rest of the safety functions are identified, and the emergency shutdown procedures are generated. This procedure is demonstrated by designing safety functions in an emergency shut down of a seawater deaeration process in a seawater injection system. The results show that the produced emergency shut down procedure based on the proposed method is feasible and that it can be validated against the real operating procedure.

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来源期刊

Chemical engineering transactions Chemical Engineering-Chemical Engineering (all)

CiteScore

1.40

自引率

0.00%

发文量

审稿时长

6 weeks

期刊介绍： Chemical Engineering Transactions (CET) aims to be a leading international journal for publication of original research and review articles in chemical, process, and environmental engineering. CET begin in 2002 as a vehicle for publication of high-quality papers in chemical engineering, connected with leading international conferences. In 2014, CET opened a new era as an internationally-recognised journal. Articles containing original research results, covering any aspect from molecular phenomena through to industrial case studies and design, with a strong influence of chemical engineering methodologies and ethos are particularly welcome. We encourage state-of-the-art contributions relating to the future of industrial processing, sustainable design, as well as transdisciplinary research that goes beyond the conventional bounds of chemical engineering. Short reviews on hot topics, emerging technologies, and other areas of high interest should highlight unsolved challenges and provide clear directions for future research. The journal publishes periodically with approximately 6 volumes per year. Core topic areas: -Batch processing- Biotechnology- Circular economy and integration- Environmental engineering- Fluid flow and fluid mechanics- Green materials and processing- Heat and mass transfer- Innovation engineering- Life cycle analysis and optimisation- Modelling and simulation- Operations and supply chain management- Particle technology- Process dynamics, flexibility, and control- Process integration and design- Process intensification and optimisation- Process safety- Product development- Reaction engineering- Renewable energy- Separation processes- Smart industry, city, and agriculture- Sustainability- Systems engineering- Thermodynamic- Waste minimisation, processing and management- Water and wastewater engineering