Design optimization of Bakelite support for LNG ISO tank 40 ft using finite element analysis

Design optimization of Bakelite support for LNG ISO tank 40 ft using finite element analysis

Design optimization of a liquefied natural gas (LNG) ISO tank is essential to ensure structural integrity while minimizing weight. This approach enables the identification of efficient material distributions under critical loading conditions, enhancing safety, compliance with ISO 1496 standards, and...

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Main Authors: Tuswan Tuswan, Taufiq Rafif Naufal, Mursid Ocid, Sari Dian Purnama, Rizal Nandiko, Yuniati Yuniati, Sasmito Agus, Machfudin Andik, Sandjaja Irfan Eko, Utina Muhammad Ridwan, Harmadi Rudias, Muttaqie Teguh
Format: Article
Language:English
Published: De Gruyter 2025-07-01
Series:Curved and Layered Structures
Subjects:
lng iso tank
bakelite support
topology optimization
finite element method
Online Access:https://doi.org/10.1515/cls-2025-0030
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Summary:Design optimization of a liquefied natural gas (LNG) ISO tank is essential to ensure structural integrity while minimizing weight. This approach enables the identification of efficient material distributions under critical loading conditions, enhancing safety, compliance with ISO 1496 standards, and overall transport efficiency without compromising strength. This study proposes a topology optimization for the Bakelite support structure of a 40 ft LNG ISO tank that balances structural strength and weight efficiency. The optimization process incorporates two main strategies: strain energy minimization and mass retain, defined as the objective function and constrained within a 90–50% mass retain range. To ensure structural integrity and regulatory compliance, the resulting designs are evaluated under the ISO 1496 standard loading scenarios, including lifting, stacking, and racking. Initial mesh convergence study of the proposed finite element analysis model shows optimum mesh selection with optimum computational time. The topology optimization results with mass retain ranging from 90 to 50% in all loading scenarios achieved a substantial weight reduction in the Bakelite support, between 4.81 and 81.41%, by eliminating the Bakelite application in the middle support of the pressure vessel. The optimized Bakelite support slightly increases stress and deformation in both the pressure vessel and the Bakelite support, remaining within the standard criteria limits. The proposed optimization is promising in maintaining structural strength compliance with ISO 1496 standards.
ISSN:2353-7396

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