ABSTRACT
This paper investigates the use of shakedown limit state in the assessment of longitudinal strength of ship hull girders. This consideration is related to the fact that a structural system subjected to cyclic loadings may suffer from plastic collapse even when the loading magnitude is less than the instantaneous collapse load of single excursion. This paper first evaluates the shakedown limit state of a box girder model with and without the consideration of buckling. Nonlinear finite element analyses are also performed to investigate the structural behaviours of a case study model under six different cyclic loading protocols. The rationality of a shakedown limit state is discussed and an energy-based characterisation of limit state is suggested. The study shows that, whilst the use of shakedown limit state assessment may be overly conservative, the safety margin based on an ultimate limit state approach might be considerably reduced.
Notes on contributors
Shen Li is a PhD student at Newcastle University. He is now researching on the dynamic collapse of ship hull girders and is aiming to develop a novel hydro-elastoplasticity method for predicting this phenomenon. The analyses presented in this paper were performed by Shen Li and he is the person drafting this paper.
Simon D. Benson currently holds the position of Lecturer in Naval Architecture at Newcastle University. He is also the academic director of the Marine Propulsion Laboratory and undergraduate admission tutor for marine technology. The present paper is contributed by Simon Benson with his important discussion and critical insight. He also contributes to the revision of the manuscript.