The doctoral dissertations of the former Helsinki University of Technology (TKK) and Aalto University Schools of Technology (CHEM, ELEC, ENG, SCI) published in electronic format are available in the electronic publications archive of Aalto University - Aaltodoc.
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Dissertation for the degree of Doctor of Science in Technology to be presented with due permission of the Department of Mechanical Engineering for public examination and debate in Auditorium 216 at Helsinki University of Technology (Espoo, Finland) on the 10th of March, 2006, at 12 noon.
Dissertation in PDF format (ISBN 951-22-8029-9) [10321 KB]
Dissertation is also available in print (ISBN 951-22-8028-0)
The ultimate strength of the hull girder for large passenger ships with numerous decks and openings was investigated. The collapse of the hull girder, composed of the hull itself and the superstructure, as compared to a single deck ship with a continuous structure, involves several important structural phenomena that complicate understanding of this process. In this study, a theory of a non-linear coupled beam method was created. This method enables one to estimate the non-linear response of a passenger ship with a large multi-deck superstructure subjected to longitudinal bending. The method is based on the assumption that the ship structure can be modelled as a set of coupled beams. Each deck in the superstructure and also in the main hull can be considered as a thin-walled beam with non-linear structural behaviour. These beams are coupled to adjacent beams with non-linear springs called vertical and shear members, modelling the stiffness properties of the longitudinal bulkheads, side shells and pillars. Special emphasis was placed on the modelling of the shear members. A semi-analytic formula of the load-displacement curve was developed by help of the non-linear finite element analysis. Also, the load-end shortening curves under axial load taken from the literature were validated with the finite element method. The reverse loading options are included into the behaviour of the structural members. The created approach allows the calculation of the normal stresses and vertical deflections in the arbitrary location of the whole hull girder. Average longitudinal displacements and deflections of deck structures and shear stresses in the side structures can be estimated as well. The method is a further development of the linear coupled beam method. The ultimate strength of the hull girder was studied also with the non-linear finite element method. This required an investigation of the element mesh configuration in order to find an optimum mesh type and size. The prismatic hull girder of a post-Panamax passenger ship was chosen as a case study. The ultimate strength was estimated both in hogging and sagging loading with the coupled beam method and with the finite element method. The results of these two different methods, presented in the form of the bending moment versus the deflection of the hull girder, show good correlation up to the area where the moment starts to decrease. In both loading cases, the failure starts by the shear collapse in the longitudinal bulkhead. The ultimate stage of the strength was reached in the sagging loading when the failure progressed to the lower decks and correspondingly, in the hogging loading when the bottom structures failed in compression. The results on the structural failure modes show clearly that the shear strength of the longitudinal bulkheads and side structures is a very important issue on the ultimate strength problem of a passenger ship.
Keywords: coupled beam, finite element, superstructure, passenger ship, ultimate strength
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© 2006 Helsinki University of Technology