NO346928B1 - Floating and submersible platform - Google Patents

Description

The present invention relates to a floating and submersible platform, developed for use as a connection station at sea for offshore wind farms and which can also be used in oil and gas extraction, of the type comprising lower pontoons, arranged several separately or as connected, e.g. in a ring, and at least three columns which are arranged at their lower ends for the pontoons and which are arranged at their upper ends to support a platform deck construction.

The invention is the solution, the proportions and the technique that enable the idea of a self-installing gravity-based platform in shallow and medium-deep water and that makes it realizable in the present form. That it is realizable has been proven through extensive calculations, simulations and model tests and by external verification in an ongoing realization project.

The floating and submersible platform is so-called "self-installing" and has been developed preferably for water depths from around 15 meters to 60 meters.

The platform concept has been developed for high-voltage rectifier substations (English HV-DC substations) for the offshore industry, but is also applicable to other types of offshore platforms regardless of function, for example for oil and gas extraction and production.

The platform concept is a gravity base structure (GBS) during operation, and self-floating in temporary phases.

Known and tested methods and elements have been combined into a new concept to arrive at a technically and economically safe and competitive solution for a number of functional requirements described below. The invention is further a complete combination of the proportions of the platform construction, the new way of ensuring continuity between columns and platform deck construction (top side) without limiting the arrangement of the top side and the technical solutions of key elements which are further described.

Previously known technology in the area of the present invention are self-floating units such as jack-up platforms, which are self-floating with legs that can be lowered to the seabed and then used to jack up the platform deck out of the water and free from waves.

Other examples of known technology are "gravity base structures" (GBS) which are self-floating with attached topsides. Such platforms have normally been used as fixed installations in deep water.

Other structures are floaters with typically two pontoon drilling rigs and typical semi-submersible ring pontoon production platforms. Such platforms have columns and pontoons, but are dimensioned to be optimal as floating structures during operation and thus with a ratio between volume of columns and volume of pontoons that optimizes this. Such semi-submersible platforms typically have a ratio between pontoon volume and column volume in the range of 2.4-3.5, which can also extend up to over 5.

Floating structures must have eigenperiods above the wave periods with significant energy in order not to resonate with the waves. A small footprint GBS should have pontoons as small as possible to minimize wave forces and be able to achieve geotechnical stability.

US 4576518 A relates to a platform for use in combination with a foundation which can be attached to the seabed to provide a fixed or movable marine structural system for use in selected offshore locations. The platform is capable of alternately existing in a fixed mode where the platform is releasably connected to the foundation, and a floating mode where the platform is disconnected from the foundation. The platform comprises a working deck and a support structure which includes buoyancy adjustment means and securing means. The buoyancy adjustment device preferably comprises ballast adjustment means.

US 4695197 A relates to a movable offshore platform for petroleum drilling and production operations intended for deployment in waters with severe weather and iceberg conditions. The structure is normally held down by gravity, but during the deballast procedure a hold-down system is used to keep the platform on the seabed until the platform is to be moved. The platform operates on the principle of hydrostatics.

The aims of the present invention can thus be summarized as follows:

- no further securing of the foundation, such as piling or anchoring, is necessary

- self-installing, i.e. without the use of special vessels or equipment, in sea condition it means self-floating.

- Be tolerant during installation to minimize risk of waiting for weather - easy removal at the end of its life,

- tolerant and robust during installation of heavy equipment,

- maneuverable with little towing resistance,

- can be completed at a shipyard and transport a complete top side to the field,

- transportable on typical heavy-lift ships,

- minimal use of solid ballast on site,

- minimize substructure when no storage is required, - substructure creates no restriction for top side arrangement,

- technically and economically competitive for shallow water depths

15-50 meters,

- minimal leaching effect,

- minimal need for seabed preparations,

- minimal/no need for maintenance/inspiration of substructure or substructure systems during operation,

- must be able to be constructed at a number of existing shipyards,

- flexible consideration of the completion strategy during construction, and everything assembled at a shipyard, or separately,

- simple and safe and proven naval operations,

- two chamber damage criteria for less risk in the project.

The objectives of the present invention are achieved by a floating and submersible platform according to independent claim 1.

Preferred embodiments are further elaborated in claims 2 to 6 inclusive.

The floating and submersible platform according to the invention shall be further explained with reference to the figures, where

figures 1a and 1b show embodiments of a typical high-voltage substation design (HV-DC substation) and a GBS with a double pontoon or with a ring pontoon, respectively,

figures 2a and 2b show alternative designs and configurations that use the principles according to the present invention,

figures 3a, 3b and 3c show eigenperiods for previously known platform constructions (i.e. prior art) in the different phases respectively floating on pontoons, floating with the pontoons submerged on the way down and the pontoons near the bottom, figures 4a, 4b and 4c show eigenperiods for the platform construction in the different phases respectively floating on pontoons, floating with the pontoons submerged on the way down and the pontoons near the bottom,

figure 5 shows an embodiment of the platform in a phase where the platform deck construction is transported on a barge that is floated in between the columns for mounting the platform deck construction to the columns,

figures 6a and 6b show the platform during transport on a heavy-lift vessel, figures 7a, 7b and 7c show a simplified water ballast system according to the present invention,

figures 8a and 8b show a simplified ballast and solid ballast removal system according to the present invention,

figures 9a, 9b, 9c and 9d show step by step an example of principles for foundation of the platform,

figures 10a, 10b and 10c show an example of how the platforms can be maneuvered and installed using only tugboats,

figures 11a, 11b, 11c and 11d show hydrostatic undamaged and damaged stability in all phases and all drafts with full platform deck weight,

figure 12 shows box tops on the outside of the platform deck's main box, and figure 13 shows a table of structural volume ratios for the present platform and known platforms.

With reference to the figures, a floating and submersible platform 1 is shown. The platform 1 comprises lower pontoons arranged separately or connected, e.g. in ring 5 and at least 3 columns 10 which in their lower end areas are arranged for the pontoons 5 and in their upper end areas are arranged for a platform deck structure 15. A ratio between volume of the pontoons 5 and volume of columns 10 is for the shown designs of the platform 1 in the range 0.8-1.5. The result of this volume ratio can be seen in figures 3a, 3b and 3c and figures 4a, 4b and 4c which respectively show heave movement transfer functions for known floating production and drilling rig semi-platforms and the present platform concept. The figures show that there is a clear difference in the fluid movement characteristics between existing semis and the platform according to the present invention. In this connection, reference is made to table 13, which shows the relationships between volume of pontoons and volume of columns for five different versions of the present platform concept (that is, the first five at the top of the table), and compared to six known floating semi-structures (that is, the bottom six in the table). The volume ratio of pontoon/pillars varies from 0.83 to 1.38 for present platform concepts, while the volume ratio for the known constructions varies from 2.45 to 5.55.

The platform deck construction 15 is further arranged with an outer box stopper 20 in the lower area of the platform deck construction for attachment between columns 10, whereby continuity between columns 10 and the platform deck construction 15 is ensured.

Outer box tops are closed in all 6 surfaces, which hit the deck levels at the top and bottom, and which then transfer all forces from the columns to the deck and side bulkheads in the deck box via in-plane continuous force transmission.

A transition element 12 is also arranged on the upper end areas of the columns 10. The columns 10 can also have a conical design. With reference to figure 7a, b, c and figure 8a and b, the platform 1 is shown arranged respectively with a simplified water ballast and fixed ballast system which otherwise does not require maintenance during the platform's lifetime.

The platform concept is self-floating with stability to carry the top side fully installed and controlled at the quay, from the assembly yard to the offshore site by towing in the sea without the need for retrofitting of modules or equipment. The ballast system mentioned above is used to ballast the platform 1 down to land on the bottom for operation.

Installation is then done independently of a crane vessel or other specialized vessel, and the scope of expensive offshore assembly "hookup" and final testing "commissioning" is limited to what can only be tested under real operating conditions for the platform systems such as high-voltage tests for "HV-DC substations" and oil and gas production from real wells.

The movement response during installation, from environmental stress, wave current and wind, is beneficial and makes the concept more weather tolerant during installation than existing concepts. The concept is prepared so that the massive ballast can be removed and the ballast system is operable without maintenance during operation at the end of the platform's lifetime. Furthermore, the foundation concept is such that, when deballasted, it has sufficient buoyancy to be pulled away from the seabed without cutting piles etc. This concept means that the platform is easy to remove and tow to a decommissioning yard at the end of its life. Skirts can be used, long or short depending on the conditions on site, but in most cases the platform is dimensioned in such a way that bottom line moment is small and uplift does not occur, and there is thus no need for suction skirts, and thus no need to apply excess pressure in the skirt chambers for removal.

The platform concept is flexible and can be manufactured and assembled locally. It can be manufactured in other parts of the world than the site of operation and transported, either fully assembled or in several parts for local assembly.

The platform concept is scalable to any size and top side/equipment weight and does not depend on crane vessel capacity or other limitations.

The weather tolerance during installation, the independence of special vessels during installation, the scalability and flexibility of the project make the concept robust, competitive and with low risk both technically and financially.

The platform concept according to the present invention can be considered a combination of a floater and a GBS. Self-floating in temporary phases and bottom-fixed gravity-based stability during operation (operation). The platform has good buoyancy during temporary phases, minimal towing resistance during pontoon sinking and favorable movements during installation when the pontoons are submerged.

The foundation area for use with gravity-based stability when the platform is firmly grounded can be adapted to the local conditions. On sandy seabeds, a minimum area to achieve a vertical preload of the soil that increases soil shear strength is advantageous, smaller submerged volume is also advantageous with regard to environmental loads and a reduced need for solid ballast, and here the concept deviates from a traditional large foundation area for GBS.

The concept deviates from typical semi-submersible platforms in its proportions between columns and pontoons, as the concept has smaller and lower pontoons that are more optimized for the anchoring conditions on the bottom, maintaining most of the favorable movement characteristics in the floating phases using the semi-cancellation principle.

The platform deck structure 15 is arranged with a central box with freedom of arrangement independent of the columns 10. External areas (that is, those outside the columns 10) can be closed with secondary structures, or as part of the main structure to make room for topside equipment. Structural continuity for columns 10 into vertical bulkheads and decks in the top side is achieved by using outer box tops 20. The concept means that freedom of arrangement for the central box is achieved, but in a way that ensures structural continuity. The distance between the pillars 10 is such that a large barge, typically with a width of 36-40 metres, can be used or driven in between the pillars for wet assembly "wet deck feeding". The platform concept has also been adapted so that the platform can be transported on a typical heavy cargo vessel with a width of 40-50 metres.

The platform concept also means that hydrostatic stability will be achieved at all drafts with an attached topside. Furthermore, damage stability will also be achieved with sufficiently small tank volumes in separated tanks. To keep environmental forces on the structure as small as possible, i.e. submerged volume is kept to a minimum, and this is achieved by using tapered columns and as small pontoons as possible.

From model tank testing, it has been found that the proportions of columns and with a low and small pontoon minimize hydrodynamic load when the platform is fixed to the bottom. The proportions of the columns and pontoons are also such that vertical dynamic pressure on the pontoons produces a moment in the opposite wave phase to the moment from horizontal load and thus there is a cancellation of bottom line moment which in most cases ensures that there is no upward lift and no need for suction skirt. The foundation area is large enough, but not too large, to achieve a certain vertical compression of the earth and thereby geotechnical stability against both seabed forces and moments.

Minimal washout has been achieved by using rounded pontoon ends, and as an alternative ring pontoons in square or circular shapes can be used.

The slender pontoons 5 can be stiffened by using permanent stiffeners between the pontoons and also between the pontoons and the columns in the lower area of the platform.

A water ballast system has been developed which uses simple lowering caissons for each tank and one for water intake. Filling is done by using a submersible pump in the intake caisson with a hose into the caisson to fill the tank. Emptying is done by lowering a submersible pump into the tank to be emptied.

This simple system is robust, safe, cost-effective and can be operated at the end of the platform's life without maintenance during the operational phase.

The water ballast system is also such that it can receive water from auxiliary vessels to speed up the ballasting process.

This concept differs here from a permanent float that has a permanent, and a number of more complicated ballast systems that require continuous maintenance.

A fixed ballast system has been developed which can receive a slurry mixture of water and sand or crushed stone in one or more simple connection points and with an internal distribution system with a minimum of bends in the internal pipe system, and which uses other tanks as settling tanks for overflow water treatment before discharge in the lake.

A hatch system for access for submersible slurry pumps has also been developed. This is intended to be used for the removal of solid ballast for "decommissioning" at the end of the platform's lifetime. This combination is new.

Three different foundation concepts have been developed for the concept.

1. Skirts that penetrate the upper soil layer with grouting (groating) using a concrete mixture, of cavities in the skirt chamber for even foundation contact. This is the solution used for most GBS's.

2. Gravel bed plus ribs on the underside of the pontoon which combine foundation and washout protection. With reference to figure 9a, b, c and d, the installation sequence for the gravel bed is shown. Ribs are arranged on the underside of the pontoons to achieve the necessary friction between steel and gravel.

3. Gravel bed plus skirt. The use of longer skirts at the perimeter, which will penetrate a gravel bed down to stronger soil layers and combat the geotechnical fracture mechanism of deep layers, is a possibility that will reduce the need for solid ballast. Optimum form of hydrostatic stability is achieved by using large enough columns, with a large enough distance, but by keeping the volume to a minimum by using tapered columns.

A redundant structural system is constructed, with more than normal continuity of load-bearing structure, with reduced steps in stiffness for local structures and with more than typical reserve capacity in possible load paths that are still predictable with normal design and analysis approaches. A combination of plate structures has been used using girders, beams, trusses and plate stiffeners to complete an effective main structural system with the need for sub-dividers, either watertight in the substructure or airtight for air treatment of rooms on the top side.

The platform concept is designed for simple and safe marine operations, and it is shown in this connection to figure 10a and b.

Claims (6)

PATENT CLAIMS 1. Floating and submersible platform (1), preferably for oil and gas extraction, of the type comprising lower pontoons (5) arranged separately or connected e.g. in a ring and at least three columns (10) which in their lower end areas are arranged for the pontoons (5) and which in their upper end areas are arranged for a platform deck structure (15), where a ratio between the volume of the pontoons (5) and the volume of the columns (10) is in the range 0.8-1.5; characterized in that the platform deck construction (15) is arranged with outer box tops (20) in the platform deck construction's lower area for attachment between columns (10), whereby continuity between columns (10) and the platform deck construction (15) is ensured without placing restrictions on the inner deck arrangement. 2. Floating and submersible platform (1) according to claim 1, characterized in that transition elements (12) are arranged on the upper end areas of the columns (10). 3. Floating and submersible platform (1) according to claim 1 or 2 characterized by the fact that the columns (10) are conical. 4. Floating and submersible platform (1) according to any of the preceding claims, characterized in that the platform (1) is founded directly on the seabed. 5. Floating and submersible platform (1), according to any of the preceding claims, characterized in that the platform (1) is equipped with a maintenance-free temporary ballasting system, consisting of simple caissons with access to each tank and sea, and with a temporary distribution system between the caissons, and where temporary submersible pumps are used to fill and empty the tanks with water, and where an external flange connection is used to fill with solid ballast. 6. Floating and submersible platform (1), according to any of the preceding claims, characterized in that the pontoons (5) have a rounded shape.