FR2876123A1 - METHOD FOR INSTALLING THE LEGS ON A BRIDGE OF A PLATFORM FOR OPERATING AT SEA. - Google Patents

Abstract

The subject of the invention is a method of installing the legs (2) on a deck (1) of an offshore operating platform, in which the different elements of each leg (2 ), the bridge (1) and the legs (2) are brought to an assembly site, the legs (2) are horizontally floated, and each leg is gradually tilted from its horizontal position to a substantially vertical position, vertically and progressively immerses each leg (2) to bring the upper end of each leg below the lower surface of the bridge (1), each leg is moved in line with a receiving opening in the bridge ( 1), each leg is progressively raised and each leg (2) is secured to the bridge (1) of the platform.

Description

The present invention relates to a method of installing the legs on a

  deck of an offshore operating platform.

  The offshore platforms of self-elevating type, such as oil rigs, generally comprise legs, including three in number, resting on the seabed with a foot formed by a caisson.

  The platform also comprises a movable and adjustable height-adjustable bridge along the legs and including operating equipment and living quarters.

  The different elements of this type of platform are generally built and assembled on the same manufacturing site. For this purpose, the deck of the platform and the legs are manufactured in a construction site and these legs are made in independent sections to form legs each having a height for example of the order of 160 meters, each section having a height. from 6 to 12 meters.

  For the assembly and mounting on the bridge sections of each leg, two methods are used so far.

  According to a first method of assembly, a first prefabricated section in vertical position and forming a base section is engaged vertically in a corresponding opening in the bridge, then the other sections also prefabricated, are positioned one above the other and assembled on each other for example by welding.

  However, such an assembly method makes it difficult to install the last sections making up each leg, since it is necessary to raise these sections to a high height and in particular to a height of about 160 meters for the last section, which implies the construction of heavy facilities to raise these sections to the proper height, which makes the various operations delicate, tedious and weather-dependent. Thus, in high winds, assembly and assembly operations must be stopped because of the risks incurred by the personnel.

  According to a second method of assembly, the bridge made on the ground is raised by a set of cranes to a determined height and a first section of a first leg is positioned below the bridge in line with an opening arranged in this bridge. This first section which is intended to form the upper section of the leg, is engaged in this opening, then is moved vertically upwards by gears which meshing with racks carried by this section. Then, a second section is placed in alignment with the first section and these sections are assembled together, for example by welding. These first two sections are moved vertically upwards and so on for all the sections making up the leg. The same operations are performed for each leg.

  In this case also, the assembly of the legs with the bridge requires a heavy infrastructure and the construction of important supports, for example of concrete, to support the bridge, and many handling operations thus increasing the manufacturing cost of the platform. form.

  Then, the assembly thus assembled by one or the other method is towed by floatation or transported by barge on the site to be installed.

  The object of the invention is therefore to avoid these drawbacks by proposing a method of installing the legs on a bridge of a platform which makes it possible to simplify assembly and assembly operations and to be able to manufacture the legs on any their length on a site and possibly build the bridge in parallel on another site and thereby reduce manufacturing costs.

  The invention therefore relates to a method for installing the legs on a deck of an offshore operating platform, characterized in that it consists of the following steps: - to assemble between them and horizontally the different elements of each leg, - to fix at the lower end of each leg a support box and on the upper half of each leg at least one floating tank 30 - to bring to an assembly site the bridge and the legs of the platform, the support box and said at least one floating tank being filled with air, - horizontally placing the legs in a floating position, - gradually tilting a first leg from its horizontal position to a substantially vertical position by ballasting the box support of this leg, said leg being held in this position by said at least floating reservoir, - to connect the leg to the bridge by at least one connecting member, - to immerse vertically and rogressively the leg ballast-both said at least floating reservoir to bring the upper end of the leg below the lower surface of the bridge, - to move the leg by the connecting member to bring it to the plumb a reception opening formed in the bridge, - to gradually raise the leg by filling the said at least one tank with air, to engage it in the opening, - to secure the leg to the deck of the platform, and to perform the same operations for each leg of the platform.

  According to particular embodiments: at least one floating reservoir is fixed at least one-third of the height of the leg relative to the upper end of this leg, and at least one floating tank is attached to the outside. of the leg, and - at least said floating tank is fixed to the inside of the leg, - the at least one reservoir is removed after having secured the leg to the bridge of the platform.

  The invention will be better understood on reading the description which will follow, given by way of example and with reference to the appended drawings, in which: FIG. 1 is a schematic elevational view of an offshore operating platform, FIG. 2 is an elevational view of a barge carrying two legs of the platform, FIG. 3 is a rear view of the barge of FIG. 2, - FIG. 4 is an elevational view of the barge during the floatation of the two legs of the platform, and FIGS. 5 to 10 are elevational views showing the different steps of assembling a leg with the deck of the platform.

  In FIG. 1, there is shown schematically an offshore operating platform including self-elevating comprising a bridge 1 provided with the usual operating equipment and living quarters.

  Conventionally, the bridge 1 is movably mounted on vertical legs 2 by means of drive mechanisms, not shown, housed for each leg, in a supporting frame 3 also called by the specialists "jack-house". Each supporting frame 3 is supported by the bridge 1 and the drive mechanisms are conventionally formed by geared motor assemblies each driving an output gear cooperating with racks disposed on each leg 2. These legs 2 are intended to bear on the seabed 4 when the platform is in the drilling or operating position and, for this purpose, each leg 2 ends, at its lower part, by a foot formed by a support box 5, intended to bear on the seabed 4.

  In the exemplary embodiment shown and as can be seen in FIG. 3, each leg 2 has a triangular section. These legs 2 may also have a square or circular section.

  Conventionally, each leg 2 is formed of several sections 20 for example of 6, 12 or 24 meters each and the height of each leg is of the order of 160 meters. Each section 20 of the legs 2 is formed of three members 21 interconnected by a lattice of metal beams 22.

  The assembly of the sections 20 of each leg 2 and the installation of the legs 2 on the bridge 1 of the platform are made as follows.

  After assembling together the elements of each section 20, that is to say the ribs 21 and the beams 22, the sections 20 of each leg 2 are arranged horizontally one after the other and are assembled together for example by welding.

  Thus, the assembly of all the sections 20 of each leg 2 is carried out horizontally so as to obtain a complete leg of a length of the order of 160 meters and, at the lower end of each leg 2, is fixed the support box 5.

  After the assembly of each leg 2, at least one floating tank 6 is fixed on each leg 2. Preferably, four floating tanks 6 are fixed on the upper half of each leg 2 and outside the ribs 21 of these legs. 2, as shown in Figs. 2 and 3. These tanks 6 are preferably fixed to one third of the height of each leg 2 relative to the upper end of said leg 2.

  Then, the legs 2 are arranged horizontally on transport barges 30, as shown in Figs. 2 and 3. In the embodiment shown in these figures, two legs 2 are arranged staggered on a barge 30. The legs 2 are then transported by the barge 30 to a deep water assembly site with the bridge 1 .

  When the barge 30 arrives at this site, this barge 30 is immersed by known ballasting means, as shown in FIG. 4. Each leg 2 is found in floating thanks to the support box 5 and floating tanks 6 which are filled with air. Each leg 2 is then removed from the barge 30 by a suitable vessel.

  The following steps therefore consist in assembling each leg 2 with deck 1 of the platform.

  Referring now to Figs. 5 to 10, there will be described these steps for a leg 2, the steps for the other legs 2 being identical.

  As shown in FIG. 5, the lower end of the leg 2 is connected to a cable 32 whose unwinding is controlled by a winch 33 disposed on a ship 31. The leg 2 is gradually tilted from its horizontal position to a substantially vertical position, as shown in FIG. FIG. 5, by ballasting the support box 5 of this leg 2, ie by progressively filling this support box 5 with water so as to allow the lower end of the leg 2 to immerse and thus to tilt this leg 2 substantially vertically along an axis of rotation located in the vicinity of the floating tanks 6 which are filled with air.

  The tilting of the leg 2 is controlled by the cable 32 and the winch 33.

  After positioning the leg 2 vertically, as shown in FIG. 6, the next step is to engage this leg 2 in an opening 10 in the bridge 1 which has been brought to the assembly site for example by flotation.

  For this step, the cable 32 which has been separated from the box 5 is connected to the upper end of the leg 2 which is also connected by a cable 34 whose unwinding is controlled by a winch 35 disposed on the bridge 1.

  In addition, the upper end of each frame 21 of the leg 2 is connected by a cable 36 whose unwinding is controlled by a winch 37 disposed above the opening 10 formed in the bridge 1.

  The tanks 10 of the leg 2 are then ballasted by gradually filling them with water which has the effect of immersing the leg 2 below the water level and at a depth sufficient to allow the passage of the upper end of the water. this leg 2 below the lower surface of the bridge 1, as shown in FIG. 7. The immersion of the leg 2 is also controlled by the cables 32 and 34 and the winches 33 and 35.

  As soon as the leg 2 is sufficiently submerged, the cables 32 and 34 are separated from the upper end of this leg 2 and the winches 37 move through the cables 36, the leg 2 to bring it gradually to the plumb of the opening 10 of the bridge 1, as shown in FIG. 8. Then, the floating tanks 6 are emptied and filled with air which causes the leg 2 to rise in the opening 10, as shown in FIG. 9. The leg 2 thus positioned in the opening 10 of the bridge 1 is secured to this bridge 1 by the rack-and-pinion type drive systems provided on the bridge 1 and the floating tanks 6 are removed one after the other. others (Fig. 10) and the leg 2 is moved vertically by the drive system.

  The same operations are performed for each leg 2 of platform 1.

  Then, the platform thus assembled is moved to the production site.

  Alternatively, the floating tanks 6 can be installed in the leg 2 between the ribs 21 which avoids having to dismount when installing the leg 2 on the bridge 1 of the platform.

  The method according to the invention makes it possible to assemble the legs sections between them horizontally which avoids the installation of a heavy infrastructure to perform these operations.

  In addition, the method according to the invention has the advantage of being able to manufacture the legs and the bridge on two independent manufacturing sites which imposes less constraints and more mobility and better use of the manufacturing sites depending on the skills of each.

Claims (5)

  1. A method of installing the legs (2) on a deck (1) of an offshore platform, characterized in that it consists of the following steps: - to assemble between them and horizontally the different elements ( 20, 21, 22) of each leg (2), - to attach to the lower end of each leg (2), a support box (5) and on the upper half of each leg (2) at least one floating tank (6), - to bring to an assembly site the bridge (1) and the legs (2) of the platform, the support box (5) and said at least floating tank (6) being filled with air - to horizontally float the legs (2), - to gradually tilt a first leg (2) from its horizontal position to a substantially vertical position by ballasting the support box (5) of this leg (2), said leg (2) being held in this position by said at least floating reservoir (6), - to connect the leg (2) to the bridge (1) by at least one connecting member (36, 37), - to immerse vertically and progressively the leg (2) by ballasting said at least floating reservoir (6) to bring the upper end of the leg (2) below the lower surface of the bridge (1), - to move the leg (2) by the connecting member (36, 37) to bring it in line with a receiving opening (10) formed in the bridge (1), - progressively raising the leg (2) by filling said at least one tank (6) with air to engage it in the opening (10), - securing the leg (2) to the bridge (1) of the platform and - to perform the same operations for each leg (2) of the platform.   2. Method according to claim 1, characterized in that said at least one floating reservoir (6) is preferably fixed at one-third of the height of the leg (2) relative to the upper end of this leg (2). .   3. Method according to claim 1 or 2, characterized in that said at least floating reservoir (6) is fixed to the outside of the leg (2).   4. Method according to claim 1 or 2, characterized in that said at least one floating reservoir (6) is fixed inside the leg (2).   5. Method according to any one of claims 1 to 4, characterized in that said at least one reservoir (6) is removed after securing the leg (2) to the deck (1) of the platform.