Investigating Vapour Cloud Explosion Dynamic Fatality Risk on Offshore Platforms by Using a Grid-Based Framework

Usama Muhammad Niazi,Masdi Muhammad,Mohammad Shakir Nasif,Faisal Khan

doi:10.3390/pr8060685

Usama Muhammad Niazi, Masdi Muhammad + Show 2 more

Open Access

https://doi.org/10.3390/pr8060685

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Abstract

The reliability of petroleum offshore platform systems affects human safety and well-being; hence, it should be considered in plant design and operation in order to determine its effect on human fatality risk. Methane Vapour Cloud Explosions (VCE) in offshore platforms are known to be one of the fatal potential accidents that can be attributed to failure in plant safety systems. Traditional Quantitative Risk Analysis (QRA) lacks in providing microlevel risk assessment studies and are unable to update risk with the passage of time. This study proposes a grid-based dynamic risk analysis framework for analysing the effect of VCEs on the risk of human fatality in an offshore platform. Flame Acceleration Simulator (FLACS), which is a Computational Fluid Dynamics (CFD) software, is used to model VCEs, taking into account different wind and leakage conditions. To estimate the dynamic risk, Bayesian Inference (BI) is utilised using Accident Sequence Precursor (ASP) data. The proposed framework offers the advantage of facilitating microlevel risk analysis by utilising a grid-based approach and providing grid-by-grid risk mapping. Increasing the wind speed (from 3 to 7 m/s) resulted in maximum increase of 21% in risk values. Furthermore, the integration of BI with FLACS in the grid-based framework effectively estimates risk as a function of time and space; the dynamic risk analysis revealed up to 68% increase in human fatality risk recorded from year one to year five.

Highlights

Offshore oil and gas processing facilities are widely constructed, and their reliable operation is essential to nations’ economies and provision of a sustainable supply of fuel
Flame Acceleration Simulator (FLACS) in the grid-based framework effectively estimates risk as a function of time and space; the dynamic risk analysis revealed up to 68% increase in human fatality risk recorded from year one to year five
A research study by the Health and Safety Executive (HSE) confirmed that accidents that occur in process units account for nearly 80% of the risk to personnel working on offshore platforms [35]

Summary

Introduction

Offshore oil and gas processing facilities are widely constructed, and their reliable operation is essential to nations’ economies and provision of a sustainable supply of fuel. One of the most important aspects of offshore platforms operation is workers’ safety. Offshore platforms are equipped with numerous equipment and control systems that have operating procedures and safety measures to operate in order to ensure optimum reliability. Process equipment deviations from normal working conditions, faults in safety system operations, and equipment degradation render offshore facilities vulnerable to failures that may lead to accidents [1,2]. Failures in the processing areas of offshore facilities mainly lead to hydrocarbon release, which can cause fires and explosions [3,4,5].

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