DE3733952A1 - METHOD AND DEVICE FOR SETTING UP AN OFFSHORE SYSTEM - Google Patents

Description

The invention relates to a method and an apparatus for Construction of an offshore plant on site, but little least a floating body with several preferably evenly distributed traction elements is anchored to the ground in such a way that the tension elements due to the buoyancy of the float be kept streamlined, and being a platform to the Float is placed in such a way that it also with unun current sea conditions are not flooded.

With conventional offshore plants, the platform is over a central pillar or several pillars directly on the sea resboden erected. Such column-supported drilling rigs or Platforms with foundations in the sea floor do not set insignificant operational risk. You must also be sufficient be placed high above the surface of the sea so they cannot be reached even by a wave of the century nen. Changes in the seabed structure at derar ground-based systems for safety reasons alone extraordinarily expensive remodeling work required to the platform level at the intended height above the Water level and within narrow tolerances in the preese to keep that target position.

From the journal "Ocean Industry", August 1984, pages 35 to 46 a device of the generic type is known, where the actual platform is on a given one Floats anchored above the sea floor is. The floating body itself consists of a completely in  the water immersed frame-shaped tube body and in the four corner areas on top of the support pillars platform held half of the water surface. Both the Carrier columns as well as those perpendicular to each other Tubes of the fuselage are accessible and take, among other things the Spannvor directions for the tension elements designed as tubes. The main advantage of these floating offshore plants is that Expansion of production options to deep water drilling put up to more than 500 m. Also the assembly and maintenance effort is required for floating offshore plants are to be anchored at the location above the drilling site, less than at ground-based systems. However, the jigs can only a few in the known offshore plant, in relative terms locations far apart from each other be, namely in the area of one of the vertical Trä columnar. The fixed position of the drilling platform supporting floating body over a few concentrated tension elements is not without problems and requires complex anchor structures in the underground. The support columns must be in platform hold high enough above the surface of the sea, so at least least the upper deck of the platform in extreme sea conditions nits, for example in a century wave, not can be washed over and damaged.

The invention has for its object the assembly and Maintenance expenses for float-based offshore systems to reduce conditions and at the same time operational safety for Increase people and material.

In procedural terms, this object is achieved in that the Platform into a floating one that forms the floating body Basin is used so that the length of the tension elements it is placed that the platform of the rotating curbs that is sealed off from the surrounding water and from swell  is protected that part of the pool interior is flooded and that those transmitted by the tension elements Buoyancy forces controlled by changing the flooding level will. In the invention, the float itself forms one the platform surrounding the protective wall, which the surrounding Water far beyond the normal water level from that keeps the platform receiving pool interior away. Inside ren of the swimming pool is mainly below the Platform, a considerable space is available, which is characterized by Flu and suitable selection of the flooding level to adjust the effective buoyancy forces and thus to adapt to the currently prevailing sea conditions can be exploited can. In high to extreme swell, the pool interior pumped empty to a minimum level, so that maximum open driving forces are transmitted from the traction elements and to stabilize the pelvis against accordingly increased Horizontal forces can be harnessed. It will be a Buoyancy generated which is about four times the horizontal forces acting on the swimming pool. Vice versa the overall effective buoyancy in calm seas can be reduced by increasing the flooding level. Hereby become the traction elements, which have the effective buoyancy absorb, relieved, although the optimal protection of the platform the offshore facility is guaranteed.

A particularly simple and cost-saving erection of the In a further development of the invention, the platform is possible that the platform on a foundation in the pool interior is set and the maximum flooding level of the pool interior is so limited that the platform's own weight is always greater than the buoyancy forces acting on the platform is. This means that the platform cannot float and in extreme sea conditions and accordingly low flooding levels with higher weight pressure on the  Foundation is resting. Lateral securing of the platform happens for example with the help of several suitable ab stands, e.g. Fenders between the platform and the circumferential side wall of the swimming pool can be used.

Those that do not act on the offshore installation according to the invention Insignificant transverse forces are in a development of the invention compensated particularly favorably that a variety of evenly distributed anchorage cables on the outer circumference of the floating pelvis are distributed and under in essential uniform azimuth angles in the range between 90 and 45 ° can be clamped.

The device for setting up an offshore facility at the one site has at least one floating body, which with several preferably evenly distributed traction elements on the floor is so anchored that the tension elements by the buoyancy forces of the float are kept taut, and means to hold a platform on the float on and is characterized according to the invention in that the float per as a swimming pool with essentially waterproof lockable bottom and side walls is formed that the Platform in the basin is used in such a way that it is encircled by the floor walls that the Zugel emente such an effective length between ground anchoring and floating pool that have the side walls from the upper project the surface of the water surrounding the pool upwards and a protective wall against the sea surrounding the platform form passage, and means for flooding and emptying the Beckenin nenraums are provided on the floating pool.

A large number, for example, preferably serve as tension elements wise 200 to 500, evenly around the perimeter of the pelvis distributed hawser. With the help of individually or in groups  the hawser acting pretensioners can both the Immersion depth of the swimming pool as well as its Hori zonal position can be set or corrected. The easy Accessibility of such pretensioners on example the outboard of the protector basin also allows one subsequent position correction if, for example, the Seabed conditions during the use of the offshore an change position and a change of position of the swimming pool bring about. The hawser can for example from Aramid Fa sern exist, which are particularly tensile and durable have proven.

Further advantages and details of the invention emerge from the description below one in the drawing schematically illustrated embodiment of the invention. The drawing shows:

Fig. 1 is a schematic side view of an offshore installation according to the invention;

Fig. 2 is a perspective schematic view of a basin-shaped floating body anchored on site with idealized vertical anchoring arrangement;

Fig. 3 is a schematic vertical sectional view on the platform anchored on site cup-shaped floating body for receiving a drilling shown in phantom;

Figure 4 is a schematic plan view of the basin-shaped floating body and the bracket of the platform.

Fig. 5 is a schematic partial view of a multi-membered foundation ring for hawser anchoring on the sea floor; and

Fig. 6 is a schematic perspective view of a foundation ring member.

In Fig. 1 the new offshore plant is shown in its installation position above the drilling site. It has a floating body in the form of a floating basin 1 with a circular cross-section, a foundation ring 3 embedded in the seabed 2 , a plurality of anchoring cables 5 which anchor the floating basin 1 on the foundation ring 3 and are kept taut by the buoyancy forces of the floating basin. A central riser 7 connects the borehole to the platform 9 supported in the interior of the swimming pool 1 , which is indicated by dashed lines in FIG. 1. The riser 7 can be of conventional design, as can the platform 9 itself, which can be designed in accordance with the respective application requirements and is not subject to any particular shape or dimension restrictions.

In the schematic view according to FIG. 1, the anchoring cables 5 are shown at the minimum azimuth angle α of 45 ° for anchoring arrangements of this type. In this extreme inclination of the anchoring cables, in addition to the buoyancy forces in the vertical direction, approximately equally large forces occur in the horizontal direction and stress the anchoring cables 5 . In the interest of minimizing the tensile forces in the anchoring cables, the latter should have an azimuth angle α 'at or near 90 ° so that the tensile loads are limited to the effective buoyancy forces. An anchoring system idealized in this sense with a plurality of vertical tros 5 distributed uniformly over the circumference of the swimming pool 1 is shown in FIG. 2.

In one embodiment that can be implemented in practice, the floating pool 1 has a diameter of approximately 150 m. With an azimuth angle α = approx. 85 ° and a water depth of 340 m between the sea level 4 and the sea floor 2 at the point of use, there is an effective length of the anchoring hawser 5 of about 350 m.

The formation of the swimming pool 1 essential for the invention and the control of the buoyancy of the swimming pool are described below with reference to FIG. 3 ben.

The floating basin 1 shown in vertical section in FIG. 3 is a steel structure with a circular peripheral side wall 11 and a funnel-like inclined bottom wall 13 . The riser 7 shown in dash-dotted lines in FIG. 3 passes through a central bottom opening 15 and is connected to the platform 9 in a suitable manner. The floating pool 1 is carried out in the area of the side and bottom walls, including the bottom opening 15 used as a guide, essentially watertight. The anchoring cables 5 are preferably made of aramid fibers or another high tensile, corrosion-resistant material. They ( 5 ) end on the outside of the side wall 11 on a hydraulic pretensioning device 15 , which determines the immersion depth of the swimming pool 1 in the surrounding water and thus also contributes significantly to the presetting of the buoyancy forces transmitted via the anchoring cables 5 of the swimming pool 1 . Each anchoring hawser 5 can be assigned its own pre-tensioning hydraulics 15 ; Prestressing hydraulics can, however, also be assigned to a plurality of anchoring cables 5 together.

The platform 9 is placed on a foundation 17 in the interior 10 of the floating pool 1 . The latter is firmly connected to the swimming pool 1 or the bottom wall 13 by suitable means, not shown in the drawing. The platform 9 rests on the foundation 17 only under its own weight. Between the corners of the platform 9 and the inside of the circumferential side wall 11 clamped fender 19 (Fig. 4) hold the flat shape oriented 9 through the central opening 15 firmly. The floating basin 1 acting as a buoyant body generates in the example shown a buoyancy of approximately 2 GN, which is approximately four times the value of the forces acting horizontally on the basin 1 (0.4-0.5 GN). The buoyancy is adjustable. This is done by partially flooding the interior 10 of the floating pool 1 in the area H between the flood levels H ₁ and H ₂ . The lower the flooding level, the higher the effective buoyancy, since the counteracting force on the water volume in the interior 10 of the floating pool 1 is reduced. The water exchange for flooding or emptying the interior 10 of the floating pool 1 takes place with the aid of known ballast pumps 21 .

In the described embodiment, the diameter of the tank 1 is approximately 150 m, the draft of the tank 1 to the lower edge of the side wall is approximately 15 m, the draft to the lower edge of the floor wall is approximately 25 m and the freeboard dimension is approximately 20 m.

To fasten the hawser on the seabed 2 , a multi-part foundation ring 3 is provided in the exemplary embodiment described, the total diameter of which depends on water depth, pool diameter and azimuth angle and is between approximately 150-900 m. A portion of the foundation ring 3 is shown in Fig. 5; an individual member designed as a steel pontoon 23 is shown in FIG. 6. Each box-shaped steel pontoon 23 is hollow, floatable per se and can be filled with sand or ash. The length dimensions of each steel pontoon depend on the ring diameter. Its height and width dimensions must be selected so that they can reliably absorb the tensile forces of the anchor cables when filled with sand, for example. The adjacent links 23 are connected to one another by suitable connecting elements 24 in such a way that they can be inclined to one another to a limited extent. Foundation piles 25 are hammered into the floor 2 , around which the foundation ring 23 with its members 23 is placed in order to hold the foundation ring in position. The Eigenge weight of the pontoons 23 filled with sand or another relatively heavy free-flowing material is sufficient as a bottom-side abutment for the anchoring cables 5 as a rule.

On the top of each foundation ring member 23 hooks 26 are provided at regular intervals for hawser attachment.

Claims (15)

1. A method for setting up an offshore installation at a site where at least one float is anchored to the ground with several preferably evenly distributed tension elements in such a way that the tension elements are kept taut by the driving forces of the float, and in which a platform on the Floating bodies are arranged at such a height that their surface lies above the water surface even in unfavorable sea conditions,
characterized,
that a pool-shaped hollow body (floating pool) with circumferential side walls is used as a floating body and the platform is inserted into the pool,
that the length of the tension elements is adjusted so that the platform is sealed off from the surrounding side walls from the surrounding water and is protected from the sea;
that the interior of the swimming pool is partially flooded and
that the buoyancy forces transmitted by the tension elements are controlled by the flooding level. 2. The method according to claim 1, characterized in that the flooding level in the interior of the swimming pool in Depending on the sea conditions is varied. 3. The method according to claim 1 or 2, characterized in that the platform on a foundation in the interior of the swim basin and the maximum flooding level of the pool interior is limited so that the dead weight the platform is always larger than those acting on the platform Is buoyant.   4. The method according to any one of claims 1 to 3, characterized ge indicates that the buoyancy forces are essentially the same moderately distributed over a variety of anchorage cables and the anchoring cables under essentially uniform Azimuth angles are braced. 5. The method according to claim 4, characterized in that the azimuth angles at which the hawser is braced, in Range between 90 and 45 °. 6. Device for the erection of an offshore installation at a site with at least one floating body ( 1 ), which is anchored with several preferably evenly distributed tension elements ( 5 ) on the ground ( 2 ) such that the tension elements are kept taut by the buoyancy forces of the floating body are, and with means ( 17 , 19 ) for holding a platform ( 9 ) on the floating body, characterized in that the floating body is designed as a floating pool ( 1 ) with essentially water-tight lockable bottom and side walls ( 11 , 13 ) That the platform ( 9 ) in the swimming pool ( 1 ) is fixed in place so that it is surrounded by the side walls ( 11 ) all around that the tension elements ( 5 ) have such an effective length between the ground anchor ( 3 ) and the swimming pool ( 1 ) have that the side walls from the swimming pool ( 1 ) surrounding water protrude upwards and a protective wall against the sea bil to the platform the, and that means ( 21 ) for flooding and emptying the pool interior ( 11 ) on the floating pool ( 1 ) are provided. 7. The device according to claim 6, characterized in that a plurality of around the circumference of the swimming pool ( 1 ) distributed hawser ( 5 ) is provided as tensioning elements, a power-operated pretensioning device ( 15 ) the hawser an individual or in groups to adjust the immersion depth is assigned to the swimming pool. 8. The device according to claim 7, characterized in that the hawser ( 5 ) under substantially uniform azimuth angles ( 2 , 2 ') are braced in the range between 90 and 45 ° to the horizontal. 9. Device according to one of claims 6 to 8, characterized in that the floating pool ( 1 ) has a circular side wall ( 11 ). 10. Device according to one of claims 6 to 9, characterized characterized that the freeboard height between 15 and 25 m lies. 11. Device according to one of claims 6 to 10, characterized in that the floating basin ( 1 ) is dimensioned according to size, immersion depth and weight so that its drive on about 3.5-4 times the value of the horizontal on the basin acting forces reached. 12. The device according to one of claims 6 to 11, characterized in that for fastening the clamping elements ( 5 ) on the floor ( 2 ) a multi-membered foundation ring ( 3 ) is provided, the links ( 23 ) of which are preferably articulated to one another. 13. The apparatus according to claim 12, characterized in that the foundation ring ( 3 ) by means of foundation piles ( 25 ), which are hammered into the subsurface ( 2 ) and, distributed over the inner circumference of the ring, act on the inner sides of the links ( 23 ), centered around the drilling site. 14. The apparatus of claim 12 or 13, characterized in that each link ( 23 ) consists of a buoyant closed steel pontoon, which is filled with a preferably granular or granular solid, such as sand or slag and held under its own weight on the floor is. 15. The device according to one of claims 6 to 14, characterized in that the platform ( 9 ) is placed on a fixed foundation on the floating pool ( 17 ) and has a Eigenge weight that is substantially larger than that at the maximum fluid level ( H ₂ ) buoyancy forces acting on the platform.