NO136403B - - Google Patents

Description

The present invention relates to a floating drilling platform or similar floating construction as stated in the introduction to the following main claim.

Such floating constructions are known, e.g. from US patent 3-507,239 and corresponding British patent 1,211,091. In said material, a construction is shown where the central strut node is placed at a considerable distance below the platform's working deck and preferably at a height with the upper edge of the floating bodies and thus at the lower ends of the columns. Mainly horizontal as well as inclined struts extend

from this junction to low and high points on the columns. In the deck construction, a second secondary node can be arranged, connected by means of a mainly vertical strut to the first node, from which secondary node only deck beams extend to the columns.

It has been shown that this construction though it

has considerable advantages, can be improved with regard to the conduction of forces and loads and influences from water and waves.

In order to achieve such an improvement, the initially mentioned construction, according to the invention, is characterized by the fact that the central node construction is arranged approximately at the height of the platform deck, and that the struts consist of upper horizontal struts to the upper end of the columns, and inclined struts that extend downwards to the lower end of each column.

This gives the following advantages compared to it

known construction:

During towing, it usually has a floating construction the floating bodies float on water and are thus only partially submerged. In such a state, the known construction will be exposed for considerable influence from the waves on the node construction due to its low height between the columns, since such a node construction will have considerable dimensions. By using the present invention, this will be avoided and it will thus be possible to continue towing in bad weather with the structure floating high in the water. It is thus not necessary to bring ballast into the floating structure in order to submerge it to a considerable extent for further towing, in which partially submerged state there is a much greater towing resistance.

Also when the floating structure is thus partially submerged during towing in very bad weather, and always when the platform is in its stationary position at normal times such as e.g. when drilling, the wave impacts are reduced because they do not reach the nodal construction near the working deck. It is true that the wave forces exerted on the columns are partly transferred to the connecting structure but only indirectly through the struts and they are thus damped so that they only act on the junction structure after they have been reduced and after the shocks have been dampened.

The inclined struts which extend from the junction construction according to the invention, to the lower points of the columns direct the loads from the working deck in the central area between the columns with all heavy constructions on it such as drilling equipment etc.; from the node construct ion

to the area near the floating bodies and then to the construction's floating surfaces, so that the load on the columns is considerably reduced. The rods are thus exposed to compressive stresses so that possible deflection must be taken into account, but nevertheless it seems easy to make these strong enough with regard to this without them becoming heavy and bulky.

Furthermore, the hub construction at a height near the deck can be easily inspected and maintained during long operating periods at sea, which is impossible or much more difficult for a hub construction at a lower height that the waves can easily reach. It is thus also possible to better protect the higher-lying junction structure against corrosion.

In a preferred, practical embodiment, con-

the structure a second central junction structure to

approached vertically, below the central main node structure, which second node structure is connected only by struts each extending substantially horizontally to the lower end of the respective columns, and that it is also connected by means of a substantially vertical strut to the nearby central node structure of the tire. The second node construction thus only serves for the horizontal connection between the lower ends of the columns and thus does not need to transmit very large forces whereby only a small number of struts must be connected to this, so that it becomes possible to perform this secondary node with small dimensions and small weight whereby the small dimensions mean that the wave effect on them becomes insignificant.

Preferably, it is central hub construction

in the vicinity of the deck formed as a hub core with connections for the substantially horizontal struts and with downwardly sloping substantially prismatic or truncated pyramidal portions as directly or through connected transition pieces extending from and tapering from the portions, or by means of both measures at the same time, are connected by braces flush with the parts, which braces have a smaller cross-sectional area than the ends of the projecting parts which are furthest away from the braces and are thus closest to the nodal construction.

In some cases, however, another embodiment of the connecting structure is to be preferred, which is possible due to the fact that it is placed so high so as not to be affected by water and waves. This can have advantages for better support of larger areas of the working deck on which the heavy equipment is placed such as derricks etc. Such another embodiment is characterized by. that the central hub construction near the deck is designed as a box or ring-shaped, hollow beam with a rectangular vertical cross-section.

The ring-shaped box or hollow beam can be circular in a horizontal plane, but is preferably of a polygonal shape in this horizontal plane, preferably with straight parts without bends between the points where the rods are connected to it. Thereby, the forces are transferred in the most favorable way between the hollow beam or box and the struts.

If, as indicated above, a secondary central hub structure is placed at a lower level, it is preferable in the event that the higher central main hub structure takes the form of an annular hollow beam or box near the working deck, forming the vertical connection between the two nodal structures as one or more struts extending if desired, in a somewhat oblique direction from the lower surface of the hollow beam or box near the deck, to the secondary nodal structure.

The characteristic features of the invention will also be apparent from the subsequent claims, and the invention shall be explained in more detail in the following with the help of possible embodiments of the invention and with reference to the drawing where

fig. 1 is a side view of the construction according to the invention in the form of a floating drilling platform,

fig. 2 is a top view of the platform,

fig. 3 is a vertical section and outline of a central part thereof mainly along the line III-III in fig. 2,

fig. 4 is a side view of a drilling platform according to the invention with another embodiment,

fig. 5 is a top view of the central part of the construction according to fig. 4, and

fig. 6 is a section and view in a vertical plane of the part of the structure shown in fig. 4 and '5 after the line VI-VI

in fig. 5-

The floating platforms shown in the drawing derive their buoyancy mainly from five floating bodies 1 of circular cross-section, each connected through conical transition pieces 2 to a column 3 which extends upwards and has the same axis as the floating bodies 1. The columns and the floating bodies are placed in the corners of a horizontal, regular pentagon.

The columns 3 can extend downwards in the floating bodies 1 and can be connected to their flat bottom surfaces so that in the floating bodies there is a suitable ring-shaped space for ballast around the downward extensions of the columns.

At the upper end of this construction, a cover construction 5 is placed which is not shown in detail and whose contours are shown with dashed-dotted lines in fig. 2 between the horizontal deck struts 16 and 20 which will be described in the following. This construction may comprise one or more tires as is known in and of itself. In a floating drilling platform, there will often be three decks, for engine rooms, for storing material and tools, and for accommodation. At 6 in fig. 2, a drilling rig can be arranged and at 7 there can be a higher deck which, if desired, protrudes further outside the structure and is intended to form a landing platform for helicopters.

In fig. 1,2 and 3, a central hub construction 8 is arranged which geometrically consists of a central, prismatic core 9 with a vertical axis. The core is polygonal so that each vertical side surface of this is perpendicular to the axis of a strut 16 which extends horizontally to one of the columns 3- In the embodiment shown where the columns are placed at the corners of a regular pentagon, the core 9 is in horizontal section and seen from above, also a regular pentagon.

Each vertical delimiting surface of the core 9 has two projecting parts 10 and 11 which merge into each other vertically and which constitute a unitary construction and which have common vertical limiting surfaces 12. The core 9 need not be designed as a separate body with its own closed side surfaces vertically , but can consist of a unitary construction with parts 10 and 11 which are mainly open and hollow inside, even if they have reinforcement struts, partitions or the like inside. Such reinforcement can be plates welded inside the core and which transfer the forces in desired directions. Furthermore, there may be internal reinforcements between the surfaces 12. As can be seen from fig. 2, there are each time two vertical delimiting surfaces 12 which extend from the center at the node and parallel outwards, although it is also possible that they converge somewhat outwards. The upper delimiting surfaces 13 and the lower delimiting surfaces of the projecting parts 11 are also parallel, but these can also, if desired, converge slightly outwards so that the projecting parts 11 can have a pyramid shape. The upper boundary surfaces 13 and lower boundary surfaces may also have a convergence angle different from the vertical side surfaces 12. At the end surfaces 15 of the projecting parts 12, their cross-sectional shape is a regular polygon, in this case a square.

Rectangular, horizontal struts 16 extend horizontally along the undersurface of the tire from the projecting parts 10 to the columns 3. Inclined struts 22 with circular or other round cross-sections extend from and with their axes each coinciding with an axis in a projecting part 11, down to the lower ends of the columns. Por a good connection with the projecting part 11, to the struts 22, each side of the part's square end surface runs into a flat surface 17, which ends at 18 in the strut' 22 with a curved or circular cross-section, and between which four flat surfaces 17 there are four conical surfaces 14 for each projecting part 11. If such conical surfaces are designed as parts of cones with inclined axes and with a circular base surface (if the struts 22 are of circular cross-section) each conical surface will have its tip in a corner of the square at the end of a protruding part 11.

The flat surfaces 17 and the conical surfaces 14 have straight boundary lines between them so that the surfaces 17 are triangles. These provide a simple possibility for manufacturing and welding as the plates,

of which this construction is composed, will not have boundary lines in the form of curved sections.

The struts 22 near the columns 3 go via transition parts 23 corresponding to the parts 14, 17 and which have four flat surfaces similar to the surfaces 17 and four curved surfaces similar to the surfaces 14, into mainly prismatic or pyramid-shaped parts 24 by means of which they are connected to each respective column 3» Of the four limiting surfaces of the parts 4, two vertical surfaces can be mutually parallel and the upper and lower surfaces can also be parallel to obtain prismatic connecting parts 24,

but if desired, it is possible to let two opposite of the mentioned surfaces or each pair of the mentioned surfaces diverge in relation to each other to form a truncated pyramid-shaped part or similar connected to the column with a larger cross-sectional area than the area it runs into the strut 22 via the aforementioned alternative flat and curved surfaces.

It appears from fig. 2 that the struts 19 and 20 in the same horizontal plane as the struts 16 mutually connect the columns 3.

In fig. 1, the front strut 19 is shown with the central part partially removed, to show the node 8. The struts 20 are rectangular as well as the struts 16, and the three struts 19 are circular in cross-section with towards the frustoprismatic transition parts 21 at the columns, and whose upper surface is horizontal and the two upright side surfaces are vertical, and where the lower surface extends downwards towards the column as is clear from fig. 1. Such connecting parts 21 pass via circumferentially alternating triangular planes and inclined conical planes at 28 into the struts 19. Near the transition between the conical parts 2 and the columns 3, there is also each time in each plane through the axes of two adjacent columns, a brace 26 which extends horizontally between two adjacent columns, and a brace 27 which extends in the same vertical plane through two adjacent columns 3 and upwards to a horizontal brace 19,20 in the upper zone of the construction. The said braces are preferably circular and have at both ends mainly prismatic or pyramidal connecting parts 30 which, through four flat surfaces which alternate with four conical surfaces at 29, transition into the circular braces 26,27-

From the lower surface of the prismatic core 9 to the node 8, a circular strut 31 runs vertically downwards, which strut at its upper <p>g lower end via a transition piece 32 which also has alternating flat and curved surfaces, transitions into the on one side the core 9 and on the other side into a junction 33 which is pentagonal and prismatic in shape and continues via transition pieces 34,35 into five horizontal stays 36, one for each column. This lower node, seen from above, has essentially the same appearance as node 8 (see fig. 1), but is much simpler as no inclined struts are connected to it so that, as can be seen in fig. 1 is much lower in the vertical direction and will thus exert little resistance in the water. Each transition piece 32 has, of course, not four, but five flat triangular surfaces which alternate with five conical surfaces.

All struts are hollow with, if desired, the necessary reinforcements in them such as retaining walls, ribs or frame parts.

In fig. 4, 5 and 6 show an embodiment in which the central node in fig. 1 and 2 is replaced by an annular body 43 assembled from flat plates to form a hollow beam. As can be seen from fig. 5, this beam 43 is mainly pentagonal in that at the connections of the stays 16 and 22 and thus in the corners of the pentagon, there are parts 37 which are perpendicular to the bisector lines of the five angular corners in the pentagon so that the pentagon is somewhat flattened at said corners, whereby an irregular decagonal figure.

Thus, the forces are transmitted precisely in the corners between the struts and the ring-shaped hollow beam 43.

The struts 22 have connecting pieces 38 with the hollow beam 43 which are also connecting pieces for the struts 16. Thus, the axes of the inclined struts 22 do not cross each other - at the intersection of the axes of the horizontal struts l6 as in the previous design example, but above the deck 5-This construction provides a simplification of the support of the deck construction as this is now intended to be supported very effectively over a larger area by means of the hollow beam 43.

In this case, the struts 39 extend from the hollow beam 43 in a downward but slightly inclined direction towards the single, underlying node 40. The struts 39 pass over as can be seen from fig. 4, in the ring-shaped hollow beam 43 in a straight area in the lower surface of this between two parts 37-This stay 39 has the same transitions with alternating flat and curved surfaces as here denoted by 41, to prismatic connecting pieces 42 at the ends at which is connected at its upper end to the hollow beam 43 and at its lower end to the node 40. The rods 16 and 22 can also pass into the hollow beam 43 by connection pieces that taper horizontally so that they are much wider at the hollow beam 43 than at the struts. In such a case, the struts will preferably not be connected to the corners of the hollow, pentagonal beam, but to the central parts of its sides.

The hollow beam 43 can be replaced by a hollow box having the same external shape, but which is completely closed at its horizontal upper and lower surfaces.

Claims (3)

1. Floating drilling platform or similar floating structure, comprising at least three vertical columns (3) which extend downwards from the platform (5) and are rigidly connected to it, which columns (3) have floating bodies (1) at their lower end with devices for submerging these by filling with water; and a central junction structure (8) between the columns (3) from which struts (16,22) extend both to upper and lower points of the columns (3), which struts (16,22) center lines converge towards the junction structure (8); and struts (19,20,26,27) which extend between adjacent columns (3) and are free of connections with other struts, characterized in that the central node structure (8) is arranged approximately at the height of the platform deck (5), and that the struts (16,22) consist of upper horizontal struts (16) to the upper end of the columns (3), and inclined struts (22) which extend downwards to the lower end of each column (3). 2. Construction according to claim 1, characterized in that the central node construction (8) is designed as a box or ring-shaped hollow beam (43) with a rectangular vertical cross-section. 3. Construction according to claim 2, characterized in that the box or beam (43) has straight outer wall parts between each place where it is connected to an upper horizontal brace (16) and an inclined brace (22) so that when viewed in a horizontal plane, it has a polygonal shape.