PSI - Issue 59

Teguh Muttaqie et al. / Procedia Structural Integrity 59 (2024) 222–229 Muttaqie et al. / Structural Integrity Procedia 00 (2019) 000 – 000

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mean value based on available test data. In these findings, it is still challenging to predict at what temperature regime the material's character changes from brittle to ductile. In the future, better material fabrication and a larger number of test specimens will certainly improve these results. Acknowledgements This work is part of the research activity conducted by the Marine Numerical and Safety Analysis research group under the Research Center for Hydrodynamics Technology, National Research and Innovation Agency, BRIN, in collaboration with the Research and Development Division of PT Biro Klasifikasi Indonesia (Persero) and Department of Mechanical Engineering, Universitas Sebelas Maret, Surakarta. References ASME, 2019. Boiler and Pressure Vessel Code. Section VIII Division 1. Rules for construction of pressure vessels, Appendix, 1(1). The American Society of Mechanical Engineers, New York, US. Bader, A.A., Mohamed, S.S., 2022. Impact resistance of AISI 304L stainless steel welded joints at low temperatures. Engineering Research Journal-Faculty of Engineering (Shoubra) 51(1), 21-26. Byun, T.S., Collins, D.A., Lach, T.G., Carter, E.L., 2020. Degradation of impact toughness in cast stainless steels during long-term thermal aging. Journal of Nuclear Materials 542, 152524. Cao, B., Bae, D.M., Sohn, J.M., Prabowo, A.R., Chen, T.H., Li, H., 2016. Numerical analysis for damage characteristics caused by ice collision on side structure. Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering – OMAE 8, V008T07A019. Cooper, A.J., Cooper, N.I., Bell, A., Dhers, J., Sherry, A.H., 2015. A microstructural study on the observed differences in charpy impact behavior between hot isostatically pressed and forged 304L and 316L austenitic stainless steel. Metallurgical and Materials Transactions A 46, 5126 5138. IMO, 1993. International Code for the Construction and Equipment of Ships Carrying Liquefied Gases in Bulk: IGC Code. International Maritime Organization, London, United Kingdom. IMO. 2019. Consistent Implementation of MARPOL Annex VI. International Maritime Organization, London, UK. Kim, D., Ahn, S.B., Yoo, B.O., Kim, K.H., Choo, Y.S., Hong, K.P., 2006. Fatigue Characteristics of STS 304 Stainless Steel for LNG Storage Tank at Low Temperature. Transactions of the Korean Nuclear Society Autumn Meeting, Gyeongju, South Korea. Kim, J.H., Choi, S.W., Park, D.H., Lee, J.M., 2014. Cryogenic charpy impact test based on GTAW method of AISI 304 stainless steel for LNG pipeline. Journal of Welding and Joining 32(3), 89-94. Lee, D.Y., Jo, J.S., Nyongesa, A.J., Lee, W.J., 2023. Fatigue Analysis of a 40 ft LNG ISO Tank Container. Materials 16(1), 428. Muttaqie, T., Sasmito, C., Kadir, A., 2022. Structural Strength Assessment of 20-ft LNG ISO Tank: An Investigation of Finite Element Analysis and ASME Design Guidance. IOP Conference Series: Earth and Environmental Science 972, 012015. Nubli, H., Fajri, A., Prabowo, A.R., Khaeroman, Sohn, J.M., 2022. CFD implementation to mitigate the LNG leakage consequences: A review of explosion accident calculation on LNG-fueled ships. Procedia Structural Integrity 41(C), pp. 343 – 350. Park, M., Kim, K., Jang, J., Kim, H.C., Moon, H.S., Jeon, J.B., Nam, D.G., Sohn, K.Y., Kim, B.J., 2018. Influence of heat treatment on mechanical properties for cold worked 304 austenitic stainless steel. Korean Journal of Metals and Materials 56(7), 490-498. Prabowo, A.R., Bahatmaka, A., Cho, J.H., Sohn, J.M., Samuel, S., Cao, B., 2016. Analysis of structural crashworthiness on a non-ice class tanker during stranding accounting for the sailing routes. Maritime Transportation and Harvesting of Sea Resources 1, 645-654. Prabowo, A.R., Byeon, J.H., Cho, H.J., Sohn, J.M., Bae, D.M., Cho, J.H., 2018. Impact phenomena assessment: Part I-Structural performance of a tanker subjected to ship grounding at the Arctic. MATEC Web of Conferences 159, 02061. Sari, D.P., Tuswan, T., Muttaqie, T., Soetardjo, M., Murwatono, T.T.P., Utina, R., Yuniati, T., Prabowo, A.R., Misbahudin, S., 2023. Critical Overview and Challenge of Representative LNG-Fuelled Ships on Potential GHG Emission Reduction. Evergreen 10(3), 1792-1808. Suryanto, S., Prabowo, A.R., Muttaqie, T., Istanto, I., Adiputra, R., Muhayat, N., Fajri, A., Braun, M., Ehlers, S., 2023. Evaluation of high-tensile steel using nonlinear analysis: Experiment-FE materials benchmarking of LNG carrier structures under low-temperature conditions. Energy Reports 9(Supplement 9), 149-161. Tuswan, T., Sari, D.P., Muttaqie, T., Prabowo, A.R., Soetardjo, M., Murwantono, T.T.P., Utina, R., Yuniati, Y., 2023. Representative application of LNG-fuelled ships: a critical overview on potential GHG emission reductions and economic benefits. Brodogradnja 74(1), 63 – 83. Zheng, C., Yu, W., 2018. Effect of low-temperature on mechanical behavior for an AISI 304 austenitic stainless steel. Materials Science and Engineering: A 710, 359-365.