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An inherently safer layout design for the liquefaction process of an FLNG plant

Version 2 2024-09-18, 23:39
Version 1 2023-05-18, 20:27
journal contribution
posted on 2024-09-18, 23:39 authored by T Baalisampang, Faisal KhanFaisal Khan, V Garaniya, Shuhong ChaiShuhong Chai, Rouzbeh AbbassiRouzbeh Abbassi

Floating Liquefied Natural Gas (FLNG) facilities have limited space available and a high possibility of accidents occurring. The severity of consequences requires an inherently safer layout design. Scope of the liquefaction process requires to determine the size of utilities, operating costs, the deck area and the number of LNG trains. The layout of the liquefaction process plays a key role in defining operational and economical safety of the whole FLNG plant. The present study focuses on developing a novel methodology to design an inherently and optimally safer layout for the generic multi-deck liquefaction process of an FLNG plant. The integrated inherent safety principle is applied at the early phases of the layout design considering inherent safety and cost indices in three different layout options, and for the final design the most optimal option was selected. The proven indexing approach quantified the associated risks in all units. Safety measures were undertaken to eliminate or reduce the risk to an acceptable level. The results showed that the economic losses due to domino effects were limited by an improved layout design and passive control strategies. This study only dealt with evaluation and analysis of critical units of the plant due to a lack of detailed information at the early phase of the design. However, the proposed method plays a positive role in obtaining an inherently safer layout design of any multi-deck plants.

History

Publication title

International Journal of Maritime Engineering (Transactions of the Royal Institution of Naval Architects: Part A)

Volume

158

Issue

A2

Pagination

A91-A102

ISSN

1740-0716

Department/School

National Centre for Maritime Engineering and Hydrodynamics, AMC Governance Office

Publisher

Royal Institution of Naval Architects

Publication status

  • Published

Place of publication

United Kingdom

Rights statement

Copyright 2016 The Royal Institution of Naval Architects

Socio-economic Objectives

170399 Energy storage, distribution and supply not elsewhere classified

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