The effects of geometrical imperfections on the  ultimate strength of aluminium stiffened plates  subject to combined uniaxial compression and lateral  pressure

Khedmati, Mohammad Reza; Pedram, Masoud; Rigo, Philippe

doi:10.1080/17445302.2012.726761

Article (Scientific journals)

The effects of geometrical imperfections on the ultimate strength of aluminium stiffened plates subject to combined uniaxial compression and lateral pressure

Khedmati, Mohammad Reza; Pedram, Masoud; Rigo, Philippe

2014 • In Ships and Offshore Structures

Peer Reviewed verified by ORBi

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https://hdl.handle.net/2268/133457

DOI
10.1080/17445302.2012.726761

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Keywords :

aluminium stiffened plate; initial imperfection; heat-affected zone; finite element analysis; ultimate strength

Abstract :

[en] The present study aims at determining the effects of the geometrical imperfections on the ultimate strength and load-carrying capacity of aluminium stiffened plates under combined axial compression and lateral pressure. The finite element models proposed by the Committee III.1 ‘Ultimate Strength’ of ISSC’2003 are used in the present investigation. Initial imperfections as proposed by ISSC committee as well as those recommended by Ship Structure Committee are considered in the analyses. Models are tested using non-linear finite element elastic–plastic analyses. Aluminium alloy AA6082-T6 is selected as the material for the models. The studied models are triple-span panels stiffened by either extruded or non-extruded angle-bar profiles. Different arrangements of heat-affected zone (HAZ) are considered. The main outcomes of this study show the need for a subtle assessment of the real shapes of the initial deformations. The way they affect the ultimate strength of models is clarified through finite element analyses.

Disciplines :

Mechanical engineering
Civil engineering

Author, co-author :

Khedmati, Mohammad Reza

Pedram, Masoud

Rigo, Philippe ; Université de Liège - ULiège > Département ArGEnCo > Constructions hydrauliques et navales

Language :

English

Title :

The effects of geometrical imperfections on the ultimate strength of aluminium stiffened plates subject to combined uniaxial compression and lateral pressure

Publication date :

2014

Journal title :

Ships and Offshore Structures

ISSN :

1744-5302

eISSN :

1754-212X

Publisher :

Taylor & Francis, Abingdon, United Kingdom

Special issue title :

Ships and Offshore Structures

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 05 November 2012

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Bibliography

Aalberg A, Langseth M, Larsen P. 2001. Stiffened aluminium panels subjected to axial compression. Thin-Walled Struct. 39(10):861-885.
ANSYS. 2007. ANSYS user's manual release 11.0. Canonsburg (PA): ANSYS.
Benson S, Downes J, Dow R. 2011. Ultimate strength characteristics of aluminium plates for high-speed vessels. Ship Offshore Struct. 6(1-2):67-80.
Clarke J, Narayanan R. 1987. Buckling of aluminium alloy stiffened plate ship structure. Paper presented at the proceedings of the International Conference on Steel and Aluminium Structures; Cardiff, UK.
Collette M. 2005. Strength and reliability of aluminium stiffened panels [doctoral thesis]. [Newcastle upon Tyne (UK)]: School of Marine Science and Technology, Faculty of Science, Agriculture and Engineering, University of Newcastle.
Cook R, Malkus D, Plesha M, Witt R. 2002. Concepts and applications of finite element analysis. New York: Wiley.
Herrington P, Latorre R. 1998. Development of an aluminium hull panel for high-speed craft. Mar Struct. 11(1-2):47-71.
Hopperstad O, Langseth M, Hanssen L. 1997. Ultimate compressive strength of plate elements in aluminium: correlation of finite element analyses and tests. Thin-Walled Struct. 29(1-4):31-46.
Khedmati MR, Bayatfar A, Rigo P. 2010. Post-buckling behaviour and strength of multi-stiffened aluminium panels under combined axial compression and lateral pressure. Mar Struct. 23(1):39-66.
Khedmati MR, Ghavami K. 2009. A numerical assessment of the buckling/ultimate strength characteristics of stiffened aluminium plates with fixed/floating transverse frames. Thin-Walled Struct. 47(11):1373-1386.
Khedmati MR, Zareei MR, Rigo P. 2009. Sensitivity analysis on the elastic buckling and ultimate strength of continuous stiffened aluminium plates under combined in-plane compression and lateral pressure. Thin-Walled Struct. 47(11):1232-1245.
Kim UN, Choe IH, Paik JK. 2009. Buckling and ultimate strength of perforated plate panels subject to axial compression: experimental and numerical investigations with design formulations. Ship Offshore Struct. 4(4):337-361.
Kristensen Q, Moan T. 1999. Ultimate strength of aluminium plates under biaxial loading. Paper presented at the proceedings of the International Conference on Fast Sea Transportation; New York, USA.
Paik JK. 2009. Buckling collapse testing of friction stir welded aluminium stiffened plate structures. Report SR-1454. Washington (DC):. Ship Structure Committee.
Paik JK, Thayamballi AK. 2003. Ultimate limit state design of steel plated structures.1st ed. London: John Wiley & Sons.
Paik JK, Thayamballi AK. 2006. Some recent developments on ultimate limit state design technology for ships and offshore structures. Ship Offshore Struct. 1(2):99-116.
Paik JK, Thayamballi AK, Ryu J, Jang J, Seo J, Park S, Soe S, Renaud C, Kim N. 2008. Mechanical collapse testing on aluminium stiffened panels for marine application. Report SSC-451.1232-1245. Washington (DC):. Ship Structure Committee.
Rigo P, Sarghiuta R, Estefen S, Lehmann E, Otelea S, Pasqualino I, Simonsen BC, Wan Z, Yao T. 2003. Sensitivity analysis on ultimate strength of aluminium stiffened panels. Mar Struct. 16(6):437-468.
Sielski RA. 2008. Research needs in aluminium structure. Ship Offshore Struct. 3(1):57-65.
Zha Y. 2003. Experimental and numerical prediction of collapse of flatbar stiffeners in aluminium panels. J Struct Eng. 129:160.
Zha Y, Moan T. 2001. Ultimate strength of stiffened aluminium panels with predominantly torsional failure modes. Thin-Walled Struct. 39(8):631-648.