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Abstract
To reduce the weight of cruise ships, the shipbuilding industry is interested in thin-walled superstructures, where the thickness of butt-welded plates in stiffened panels is under 5 mm. Compared to thick plates, thin ones can develop severe welding-induced distortions, which limit the validity of recommended early-design structural stress assessment methods. Therefore, computationally costly 3D non-linear numerical analysis must be used. For a quick and effective early design, this paper investigates on simplified computational models for thin-walled panels under uni-axial tension, considering the distortions measured on 4 -mm thick, full-scale ship-deck panels. A 2D simply-supported analytical plate is shown to be sufficiently accurate (i.e., error <10%) at 150 MPa for a distortion with maximum slope within 0.02 rad and amplitude smaller than the thickness (t). Moreover, a 1D beam numerical analysis efficiently predicts local stresses around the butt weld when the maximum distortion amplitude is below 0.6×t mm. The distortion needs to be considered at least up to a length of half of the plate width from the weld location and can represent longitudinal profiles within 60% of the plate width. In conclusion, the early structural stress assessment of thin-walled panels can be significantly simplified, thus helping bridge the gap between complex numerical analysis and simplified analytical solutions.
Original language | English |
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Article number | 111637 |
Number of pages | 14 |
Journal | Thin-Walled Structures |
Volume | 197 |
DOIs | |
Publication status | Published - Apr 2024 |
MoE publication type | A1 Journal article-refereed |
Keywords
- analytical modelling
- geometric distortion
- nonlinear FEA
- scale reduction
- structural stress
- welded stiffened panel
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CaNeLis: Carbon-neutral lightweight ship structures using advanced design, production, and life-cycle services
Remes, H. (Principal investigator), Heiskari, J. (Project Member), Lehto, P. (Project Member), Romanoff, J. (Project Member), Mancini, F. (Project Member), Ono, Y. (Project Member), Niraula, A. (Project Member), Karola, A. (Project Member), Asplund, A. (Project Member), Matusiak, J. (Project Member), Mikkola, T. (Project Member), Tariq, S. (Project Member), Zaka, A. (Project Member) & Elsayed, M. (Project Member)
01/10/2022 → 30/09/2025
Project: Business Finland: Strategic centres for science, technology and innovation (SHOK)
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RAMSSES: Realisation and Demonstration of Advanced Material Solutions for Sustainable and Efficient Ships
Remes, H. (Principal investigator)
01/06/2017 → 30/11/2021
Project: EU: Framework programmes funding
Equipment
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Solid Mechanics Laboratory (i3)
Lehto, P. (Manager)
Department of Energy and Mechanical EngineeringFacility/equipment: Facility