This application claims the benefit and priority of French Patent Application Serial No. 1153502, filed on Apr. 22, 2011, which is incorporated by reference herein.
The present invention relates to a passenger ship, such as a passenger liner or a ferry for example.
Such a ship comprises a main structure bounded by a hull and its upper deck (or freeboard deck), above which rises at least one superstructure consisting in particular of an assembly of decks and of longitudinal and transverse bulkheads (partition walls). The superstructures of these ships are subjected to loads generated by the deflection of the ship during its passage through the swell, loads that are manifested by a parabolic bending moment distribution and by a shear load. On large size ships of the passenger liner or ferry type, the type of construction of these superstructures involves said superstructures contributing to the aggregate strength of the ship. Consequently, they are taken into account for the strength calculation of the “hull girder”, that is the girder schematic that represents the set of loads to which the structure of a ship is subjected. However these superstructures are currently made up of decks interconnected by interior bulkheads and/or boundary bulkheads called “platings”, as well as by stanchions.
Depending on the type of construction selected, these interior bulkheads, particularly those oriented in the longitudinal direction of the ship, and these platings, the number of which is high, complicate the structure of ships. This involves not only a complication of the superstructure itself but also of the main structure aimed at ensuring structural continuity, incidentally increasing the overall weight of the superstructure and/or not allowing good natural illumination of the cabins and other passenger living spaces. In particular, in the interior portions of these ships, certain spaces are “blind”, in the sense that they do not get the benefit of any outside lighting.
The present invention aims to resolve these problems. In other words, it has the object of proposing a ship the overall structure whereof is as strong as that of currently known ships, carrying the full set of loads, but allowing the elimination of part of the decks, the interior bulkheads and/or the platings of the superstructures, particularly so as to:
Thus, the present invention relates to a passenger ship, such as a passenger liner, which includes a main structure bounded by a hull and its upper deck (or freeboard deck), above which rises at least one superstructure, characterized by the fact that it comprises at least one arch which stands generally fore and aft, and which extends at least partly over the main structure, its opposite ends being firmly joined to this main structure, so that the arch carries at least partly the loads connected with its deflection. In other words, said arch begins toward the stern and extends in the direction of the bow.
Thus, the arch aims to limit the deflection (deformation) of the ship when it is on the swell (in this case, the arch is in tension when the middle of the ship is on the crest of a swell, and in compression when the two ends of the ship are on the crest of a swell). This makes it possible to thus limit the bending of the ship, which constitutes an essential criterion in the classification of ships. In the present application, the term “deflection” signifies “deformation”.
Preferably, when the superstructure consists particularly of an assembly of decks and of structural transverse bulkheads, at least part of the decks of the superstructure is fixed to this arch. The arch then also carries a large part of the loads to which the superstructure of the ship is subjected. It is thus possible, in the construction of the superstructures, to eliminate certain longitudinal structural bulkheads and/or some platings which are normally necessary for avoiding or limiting relative slippage of the decks and thus contribute to the aggregate strength of a ship according to the state of the art, particularly for resisting the shear loads thus generated.
This makes it possible, as already indicated above, to:
According to other advantageous characteristics:
Other characteristics and advantages of the present invention will appear upon reading the detailed description of certain preferred embodiments.
This description will be made with reference to the appended drawings wherein:
The passenger ship which is shown in the figures and which consists of a passenger liner 1 has a structure that is generally known per se. To this end, it includes a main structure 2 which is bounded by a hull 20 and its upper deck 21. Such a main structure contains all the known equipment which conventionally equips a ship, this main structure being subdivided into different compartments which are bounded by decks and vertical bulkheads (partition walls), in the ship's longitudinal and transverse directions. The terms “longitudinal” and “transverse” are defined with reference to the longitudinal axis of the ship designated X-X′, this axis corresponding to the direction of motion of said ship.
Above the main structure 2 rises a superstructure 3 which consists, as is also known, of an assembly of decks 30, of transverse structural bulkheads 31 and of stanchions. These are metal decks and bulkheads, pre-assembled together, which later receive all the operation and accommodation equipment necessary for the use of the ship. In conformity with an embodiment of the invention, this ship has the particular feature of including at least one arch 4 which stands vertically and parallel to the longitudinal axis X-X′. In the case presented here, these arches (or arcs) are two in number and are arranged symmetrically on either side of the medial axis X-X′. They extend in the neighborhood, i.e. in immediate proximity to the platings of the hull 20.
In a different embodiment, not shown, the number of arches and/or their arrangement could be otherwise. Thus, in the case where the ship is provided with a single arch, this extends in the medial position, that is along the axis X-X′.
Said arch extends at least partly over the main structure 2 of the ship and its opposite ends 41 are firmly joined to this main structure 2. The latter do not necessarily reach the stern and the bow of the ship. In conformity with the invention, at least part of the aforementioned decks 30 in the superstructure 3 is fixed to this arch, as partially shown in
Thanks to this arrangement, the loads generated by the decks and bulkheads of the superstructure, during the ship's passage through a swell or due to its roll, are carried by the arches 4 and are distributed to their opposite ends 41. Of course, these ends 41 must be effectively joined to the main structure, rigidly that is, their dimensions and their shape allowing them to transmit said loads to the main structure. Thus, when the arch consists of a metallic material, then these ends 41 will be joined to the main structure 2, by arc welding for example.
With reference to
In the absence of platings, it is absolutely necessary that the arches be supported by stanchions or by an equivalent structural means, allowing the provision of large openings in this region (normally occupied by platings) of the superstructures, so as to bring natural light to the interior of the ship. As stated above, the arch 4 is preferably made of metal.
In such a case it will be preferred to use, in building it, elements or modules in the form of meshes, such as those shown in
Of course, other types of material than metal can be used. In particular, any kind of composite material can be considered, particularly those based in carbon fiber. In such a case, and as shown in
Thanks to the presence of these arches, which carry the loads generated by the structure of the ship itself, it is possible, particularly in the construction of the superstructure 3, to eliminate all or part of the decks, longitudinal structural bulkheads and/or platings which are necessary in particular to the aggregate strength of the ship. By eliminating all or part of the longitudinal bulkheads and/or platings, spaces with larger dimensions can thereby be obtained and/or, in certain cases, the lighting of the interior of the ship can be improved.
In the embodiment shown in
They are joined at their upper end to the associated arch 4 and at their base to the main structure 2. Their function is to prevent any deflection of the arches and to carry part of the loads sustained by the latter. In a sense, these pillars function as stays.
In a simplified embodiment of
Number | Date | Country | Kind |
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1153502 | Apr 2011 | FR | national |