Citation:
Tatiana Pais,Marco Gaiotti,Beatrice Barsotti.Evaluation of the Residual Capacity of a Submarine for Different Limit States with Various Initial Imperfection Models[J].Journal of Marine Science and Application,2022,(2):59-68.[doi:10.1007/s11804-022-00271-0]
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Evaluation of the Residual Capacity of a Submarine for Different Limit States with Various Initial Imperfection Models
Tatiana Pais,Marco Gaiotti,Beatrice Barsotti.Evaluation of the Residual Capacity of a Submarine for Different Limit States with Various Initial Imperfection Models[J].Journal of Marine Science and Application,2022,(2):59-68.[doi:10.1007/s11804-022-00271-0]
Info
- Title:
- Evaluation of the Residual Capacity of a Submarine for Different Limit States with Various Initial Imperfection Models
- Author(s):
- Tatiana Pais; Marco Gaiotti; Beatrice Barsotti
- Affilations:
- DOI:
- 10.1007/s11804-022-00271-0
- Abstract:
- The current design philosophy for submarine hulls, in the preliminary design stage, generally considers as governing limit states material yielding along with various buckling modes. It is common belief that, beyond the design pressure, material yielding of the shell plating should occur first, eventually followed by local buckling, while global buckling currently retains the highest safety factor. On the other hand, in the aeronautical field, in some cases structural components are designed in such a way that local instability may occur within the design loads, being the phenomena inside the material elastic range and not leading to a significant drop in term of stiffness. This paper is aimed at investigating the structural response beyond a set of selected limit states, using nonlinear FE method adopting different initial imperfection models, to provide the designers with new information useful for calibrating safety factors. It was found that both local and global buckling can be considered as ultimate limit states, with a significant sensitivity towards initial imperfection, while material yielding and tripping buckling of frames show a residual structural capacity. In conclusion, it was found that the occurrence of local buckling leads to similar sudden catastrophic consequences as global buckling, with the ultimate strength capacity highly affected by the initial imperfection shape and amplitude.
References:
American Bureau of Shipping (2021) Rules for building and classing, Underwater vehicles, systems and hyperbaric facilities, Spring, TX, USA
Bureau Veritas (2016) Rules for the Classification of Naval Submarines, n. NR 535 DT R00 E, Paris, France
Cho SR, Muttaqie T, Do QT, So HY, Sohn JM (2018) Ultimate strength formulation considering failure mode interactions of ring-stiffened cylinders subjected to hydrostatic pressure, Ocean Engineering, 161:242-256, https://doi.org/10.1016/j.oceaneng.2018.04.083.
DNV-GL (2018) Rules for classification Naval vessels, Edition January 2018, Part 4 Sub-surface ships, Chapter 1 Submarines, H?vik, Norway
DNV (2009) IACS HPT02:non-linear finite element collapse analyses of stiffened panels procedure description (technical report)
Ismailab MS, Purbolaksonob J, Andriyanab A, Tanb CJ, Muhammada N, Liewb HL (2015) The use of initial imperfection approach in design process and buckling failure evaluation of axially compressed composite cylindrical shells, Engineering Failure Analysis, 51:20-28. https://doi.org/10.1016/j.engfailanal.2015.02.017
ISSC 2012 Committee V. 5(Naval Vessels), chapter 3
Komoriyama Y, Tanaka Y, Ando T, Hashizume Y, Tatsumi A, Fujikubo M (2018) Effects of cumulative buckling deformation formed by cyclic loading on ultimate strength of stiffened panel, Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering-OMAE 2018, Madrid, 17-22 June, https://doi.org/10.1115/OMAE2018-77855
Li C, Liu R (2020) Numerical investigation into the effects of different initial imperfections on the lateral buckling of submarine pipelines, Ocean Engineering, 195, art. n°106752, https://doi.org/10.1016/j.oceaneng.2019.106752
MacKay JR, Jiang L, Glas AH (2011a) Accuracy of nonlinear finite element collapse predictions for submarine pressure hulls with and without artificial corrosion damage, Marine Structures, 24(3)292-317, https://doi.org/10.1016/j.marstruc.2011.04.001.
MacKay JR, van Keulen F, Smith MJ (2011b) Quantifying the accuracy of numerical collapse predictions for the design of submarine pressure hulls, Thin-Walled Structures, 49(1):145-156, https://doi.org/10.1016/j.tws.2010.08.015.
PD5500(2021):Specification for unfired pressure vessels.
Pulos JG, Salerno VL (1961) Axisymmetric elastic deformations and stresses in a ring-stiffened, perfectly circular cylinrical shell under external hydrostatic pressure, David Taylor Model Basin Report, Sept. 1961
Reijmers JJ, Kaminski ML, Stapersma D (2022) Analytical formulations and comparison of collapse models for risk analysis of axisymmetrically imperfect ring-stiffened cylinders under hydrostatic pressure, Marine Structures, 83:103-161, https://doi.org/10.1016/j.marstruc.2022.103161
Report of Committee V.5:Naval Vessels (2012):Proceedings of the 18th International Ship and offshore Structures Congress, Volume 2, Schiahrts-Verlag "Hansa" GmbH&Co. KG, Hamburg, ISBN 978-3-87700-132-5
Ringsberg JW, Darie I, Nahshon K, Shilling G, Vaz MA, Benson S, Brubak L, Feng G, Fujikubo M, Gaiotti M, Hu Z, Jang BS (2021) The ISSC 2022 committee III. 1-Ultimate strength benchmark study on the ultimate limit state analysis of a stiffened plate structure subjected to uniaxial compressive loads, Marine Structures, 79:n°103026. https://doi.org/10.1016/j.marstruc.2021.103026
Sadovskya Z, Krivá?ekb J, Sokola M (2021) Imperfection sensitivity of axially compressed cylindrical shells under varying dimensions, Engineering Structures, 247:n° 113133, https://doi.org/10.1016/j.engstruct.2021.113133
Shiomitsua D, Yanagiharab D (2020) Elastic local shell and stiffener-tripping buckling strength of ring-stiffened cylindrical shells under external pressure, Thin-Walled Structures, 148:n° 106622, https://doi.org/10.1016/j.tws.2020.106622
Shon SD, Lee SJ, Lee KG (2013) Characteristics of bifurcation and buckling load of space truss in consideration of initial imperfection and load mode, Journal of Zhejiang University:Science A, 14(3):206-218, https://doi.org/10.1631/jzus.A1200114
Showkati H, Yousefieh A, Pourmirza M (2008) The effect of initial circumferential imperfections on the buckling and post-buckling behavior of cylindrical shells, EASEC11-Eleventh East Asia-Pacific Conference on Structural Engineering and Construction, Taipei, Taiwan, 19-21.
Simitses GJ (1986) Buckling and postbuckling of imperfect cylindrical shells:a review, Applied Mechanics Reviews, 39(10):1517-1524, https://doi.org/10.1115/1.3149506
The Riks method is available at:/2017/English/SIMACAEANLRefMap/simaanl-c-postbuckling.htm#simaanl-c-postbuckling-t-TheRiksMethod-sma-topic2[Accessed on June 8, 2022]
Vergassola G, Boote D, Manca C (2019) Buckling numerical analysis of stiffened cylindrical structures, Proceedings of the International Offshore and Polar Engineering Conference, 4:4367-4374, Honolulu, Hawaii, 16-21.
Wang XL, Zhang Q (2021) Identification of External Pressure of Nonlinear Buckling Instability of Subsea Pipeline with Initial Imperfections, Petrochemical Equipment, 50(5):32-37. https://doi.org/10.3969/j.issn.1000-7466.2021.05.007
Wang Z, Duan N, Soares CG (2021) Controlled lateral buckling of subsea pipelines triggered by imposed residual initial imperfections, Ocean Engineering, 233, art. n°109124, https://doi.org/10.1016/j.oceaneng.2021.109124
Memo
- Memo:
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Received date: 2022-02-25;Accepted date:2022-06-08。
Foundation item:The research activity on this topic is still under development in the frame of the ASAMS (Aspetti specialistici e approccio metodologico per progettazione di sottomarini di ultima generazione) project (2019-2022), which has been funded by the Italian MoD-Segredifesa, in collaboration with Fincantieri.
Corresponding author:Tatiana Pais,E-mail:tatiana.pais@unige.it
