METHOD FOR FABRICATING A GRAVITY-BASED STRUCTURE (GBS) AT A SPECIALIZED FABRICATION SITE

Abstract

A gravity-based structure (GBS) includes central and protruding parts having a common base slab. For the central part, outer and inner walls and a top slab are cast in concrete so that the GBS forms a rectangular prism. As casting of individual outer wall sections is completed, a reinforcement cage is assembled, formwork is installed, and protruding part outer and inner walls are cast, the outer walls being formed along the base slab perimeter with a height lower than the central part outer wall height. As separate protruding part wall sections are cast, a reinforcing cage is assembled, formwork is installed for a protruding part top slab, and then cast. Post-tensioning of central part base and top slabs and central and protruding part outer and inner walls is done as central and protruding part top slab casting is completed and the concrete is cured, increasing buoyancy and reducing submersion.

Claims

1: A method for fabricating a gravity-based structure (GBS), comprising assembling a reinforcement cage for a rectangular base slab, installing base slab formwork and then concreting the base slab, assembling, as separate sections of the base slab are concreted, reinforcement cages for inner and outer walls and concreting the inner and outer walls by slipforming, assembling, as separate wall sections are concreted, a reinforcement cage for a top slab, installing a top slab formwork and then concreting the top slab, and post-tensioning with reinforcement strands the top slab and base slab, as well as inner and outer walls, wherein the GBS is fabricated including a central part and protruding part that have the common base slab, besides the inner and outer walls as well as the top slab are concreted for the central part of GBS, that takes form of a rectangular prism, as separate sections of the outer walls of the central part are concreted, a reinforcement cage is assembled, formwork is installed and concreting is performed for inner and outer walls of the GBS protruding part, the outer walls of which are made along the perimeter of the base slab, and at the same time the height of the outer walls of the protruding part is lower than the height of the outer walls of the central part, as separate wall sections of the protruding part are concreted, a reinforcement cage is assembled and formwork is installed for a top slab of the protruding part and then concreted, and the base and top slabs of the central part, as well as the inner and outer walls of the central part and protruding part are post-tensioned as the top slabs of the central part and protruding part are concreted and the concrete of the post-tensioned structures is cured.

2: The method according to claim 1, wherein the top slab is concreted with upward bending of its central part so that the central part of the slab lowers on its own weight to a design position.

3: The method according to claim 1, wherein, as soon as separate sections of the top slab of the central part are concreted, a reinforcement cage is assembled, a formwork is installed, embedments are set and supports for equipment are concreted on the top slab.

4: The method according to claim 1, wherein, in the course of the outer and inner walls of the central part being concreted, openings are left for formwork removal and further installation of equipment inside the GBS compartments shaped by the walls and slabs.

5: The method according to claim 3, wherein, simultaneously with concreting of the walls of the central part, a reinforcement cage is assembled, a formwork is installed and an intermediate slab is concreted, post-tensioned, and inside at least one compartment shaped by the walls, intermediate slab and top slab, a tank for storage of liquids is arranged with panels, delivered through temporary wall openings.

Description

LIST OF DRAWINGS

[0045] FIG. 1 shows fabrication of the base slab and walls of the GBS central part between the base slab and the intermediate slab.

[0046] FIG. 2fabrication of the base slab and intermediate slab as well as inner walls of the GBS central part.

[0047] FIG. 3fabrication of the inner and outer walls of the GBS central part.

[0048] FIG. 4fabrication of the outer walls of the GBS central part, top slab, topside supports on the top slab, outer walls of the GBS protruding part and tanks for liquids storage inside the GBS.

[0049] FIG. 5fabrication of the top slab of the GBS central part, top slab of the GBS protruding part and top structure supports.

[0050] FIG. 6the fabricated GBS when towed out of a dock, front view.

[0051] FIG. 7the fabricated GBS when towed out of the dock, side view.

EXAMPLES OF THE INVENTION IMPLEMENTATION

[0052] The production program implies mass production of GBSs as part of a staged process at a specialized fabrication site with dry docks. The location of the fabrication site facilities allows producing materials for every separate stage of fabrication within limits of a separate facility with subsequent transportation to dry docks for use in the GBS fabrication. The GBS fabrication sequence is designed to optimize the use of equipment and personnel and reduce construction time through parallel performance of part of the work stages.

[0053] The GBS is fabricated as follows.

[0054] The dry dock is isolated from the adjacent water area using a dock gate, then the dock is drained with pumps. Then, at the bottom of the dock, an area with a cover of compacted crushed rock is prepared for fabrication of the GBS foundation slab.

[0055] Reinforcement is cut and bent and reinforcement cages are fabricated and labelled in a reinforcement shop. Reinforcement elements are transported to the dry dock by road and fed at the GBS reinforcement cage assembly site with loaders or lifting cranes. The GBS reinforcement cage is assembled by welding, lashing, and sleeving.

[0056] Simultaneously with the reinforcement cage, duct tubes for bundles of post-tensioning reinforcement strands are installed in the tensioned structures, as well as the anchors and embedments for equipment to be installed.

[0057] Three types of formworks are used for the GBS concreting: traditional formwork, inventory formwork and permanent formwork. In a formwork shop, traditional and permanent formwork is produced, and inventory formwork assembly sections are assembled. Completed sections are stored in a formwork laydown area and, when needed, they are transported to the dry dock and installed for concreting of the GBS structure.

[0058] Traditional formwork panels are produced from cut wood and laminated plywood in the formwork shop. The traditional formwork is used to concrete objects of smaller height, mainly for slabs and supports.

[0059] Basic elements of the inventory formwork are panels or blocks, frames, bearing structures, connectors and fastenings. Depending on the structure to be concreted, two types of inventory formwork are applied: panel-type formwork and slipforming.

[0060] Panel-type formwork is collapsible and consists of large-sized elements, accelerating construction of large-scale objects. Slipforming consists of two identical rows of panels, 1.0-1.2 m high, rigidly connected to one another by bolts and attached to a special frame, which is moved upwards by jacks along with the structure's concreting process. Slipforming is used for the GBS walls concreting. With slipforming applied, concreting is monolithic, that is, without the cold seams, thus improving the structure's performance parameters. Moreover, the use of slipforming enables the GBS walls to be concreted very fast-over 2.5 meters upwards per day.

[0061] Permanent formwork is used when formwork removal is impossible, e.g. during concreting of the intermediate ceiling slab when the equipment is installed inside the compartment. This type of formwork is also used for construction of pit structures in LNG tanks and other parts of the GBS, removal of which is labor-intensive after closure of outer structures.

[0062] Concrete, which is the main construction material for GBS production, is mixed at a concrete batching plant, located close to the dry docks. Location of the concrete batching plant ensures the least distance for concrete to be transported to the pouring point.

[0063] Bulk materials for concrete mixing may be delivered to the fabrication site via a quay, located in front of the concrete batching plant, and it secures the shortest way for the materials from the offloading point to the place where they are stored and consequently used.

[0064] The GBS production employs special concrete mix designs of high strength, having the pre-requisite density and durability features. The use of concrete of different densities in combination with weight control allows to achieve optimal targets for mass, buoyancy and stability of the structure. The concrete mix is delivered to the dry dock by truck mixers. The concrete is poured into the formwork with concrete pumps.

[0065] Concreting starts with sectionalized concrete casting of the base slab 1, which is common for the GBS central and protruding parts (FIG. 1). A reinforcement cage is assembled for the rectangular base slab 1, a formwork for the base slab 1 is installed and the base slab 1 is then concreted. As individual sections of the base slab 1 are completed, reinforcement cages are assembled in the central part of the GBS for internal walls 2 with the help of an inventory formwork. In parallel, reinforcement installation is performed for internal walls 3 and external walls 4 in the GBS central part (FIG. 2, 3), which are slipformed. During this process, the GBS central part is shaped as a rectangular prism. For the purposes of formwork removal and subsequent equipment installation in GBS compartments, relatively small service openings are left in the walls to be further thoroughly closed and sealed once the work inside the compartments is finished.

[0066] In case the GBS is fabricated with an intermediate slab 7 to accommodate at least one liquid storage tank 8 (FIG. 4), as concreting of individual sections of the walls 2 of the central part between the base slab 1 and intermediate slab 7 is completed, concreting of the GBS intermediate slab 7 begins, in parallel with concreting of the internal and external walls 3 and 4 in the GBS central part. For this purpose, a reinforcement cage is assembled, formwork is erected and the intermediate slab 7 is concreted.

[0067] As individual sections of the external walls 4 of the central part are concreted, a reinforcement cage is assembled, formwork is installed, and external and internal walls of the protruding part are concreted section by section, using slipforming. The external walls 5 of the GBS protruding part are erected all along the base slab perimeter, with the external walls 5 of the protruding part being lower than the external walls 4 of the central part.

[0068] In parallel, in the sections where concreting of walls 3, 4 of the GBS central part is completed, concreting of the top slab 9 of the GBS central part begins. For this purpose, a reinforcement cage is assembled for the top slab 9, formwork is erected for the top slab 9 and the top slab 9 is concreted. In addition, to erect the formwork, the scaffolding and trestles are installed inside the GBS compartments allowing to avoid using roof beams. Using scaffolding in combination with the formwork provides their universal usage both for building the top slab 9 and for performing subsequent preparation and installation of structural elements of tanks 8 at different heights, which ultimately results in overall construction acceleration.

[0069] To offset the downward bending of the top slab 9 due to its weight, the central part of the slab is bent upwards before concreting to ensure camber in the opposite direction. Once the concreting is completed and the formwork is removed, the slab settles down due to its weight and takes design configuration enabling partial offset of downward bending. Using a beamless design for the top slab 9 with uneven thickness similar to an arc where the slab is thicker near its edges than in the span (not shown in the drawings) enables better target specifications for weight and rigidity as well as accelerated formwork installation through simplification of the slab bottom surface, which has no protruding parts.

[0070] At least in one of the compartments formed by internal reinforced-concrete walls 3, intermediate slab 7 and top slab 9, the liquid storage tank 8 is locally erected from panels delivered through the openings in the walls.

[0071] In parallel, as the external walls 5 of the GBS protruding part are completed, concreting of top slabs 6 of the GBS protruding part begins (FIG. 4, 5). The top slabs 6 of the GBS protruding part are connected to the external walls 4 of the central part by extending and tying protruding reinforcements into sleeves and anchor rods that were earlier flush-mounted during slipforming of walls 4 in accordance with the design.

[0072] If the intended use of the GBS includes berthing of vessels, supports are built from reinforced concrete along the outer edge of the GBS protruding part above the top slab 6 for the purpose of installation of berthing structures and fenders for berthing and mooring of vessels enabling the use of GBS structures as a berth. These supports are erected with the help of an inventory formwork.

[0073] Should it be required to fabricate a GBS with supports 10 for a topside equipment to be installed on the top slab 9, then a reinforcement cage is assembled, formwork is installed, embedments are set in and the supports 10 are concreted to provide support for load-bearing structures of the topside cages which may house process equipment (FIG. 5).

[0074] The post-tensioning materials workshop accommodates storage of reinforcement strands, duct tubes and anchors, preparation of materials and equipment to perform post-tensioning. In the areas where sequence of works makes it possible to start this type of work, the equipment is installed in the dry dock. Once the equipment is ready, the post-tensioning materials are transported to the dry dock where strand bundles are installed and tensioned to the design values with anchoring and transmission of tensioning force to anchoring devices on reinforced concrete structures of the GBS.

[0075] Concrete structures are post-tensioned using tension on concrete with bonding restoration, which means that after the concrete of the tensioned reinforced concrete structures of the GBS is poured, the strands are forced/pulled through the pre-installed duct tubes made of corrugated steel. After the concrete has reached the minimum required strength, the strand bundles are tensioned and fixed thus transmitting the tensioning force to steel anchoring devices pre-installed onto the short ends of the structure body.

[0076] Reinforcement strands are tensioned with hydraulic jacks. After strand bundles are tensioned and pull-out testing is done, the duct tubes are filled with nonshrink cement mortar and all temporary openings and niches are filled up. The duct tubes will protect the reinforcement strands from external impact and partially transfer load from the strands to the concrete along the entire length of the structure.

[0077] With post-tensioning during GBS construction, the targeted performance can be achieved more efficiently, especially for limit states group II, such as crack resistance and impermeability. As a result, it reduces the amount of non-tensioned reinforcement required and contributes to reducing the structure weight, as well as increases the overall spatial stiffness of the load-bearing reinforced concrete cage of the GBS.

[0078] Closing of process openings in the GBS walls, concreting of post-tension anchors, and cleaning of concrete surface take place in the end.

[0079] After the GBS fabrication is complete, equipment 11 is installed inside compartments and on the top slab 9 and a modular topside structure 12 is installed onto the supports 10 on the top slab 9 (see FIGS. 6 and 7). Topside modules 12 may be fabricated in parallel and independently of the GBS construction schedule, and then installed on the supports 10 with the help of a specialized jacking and skidding system. The supports 10 are also the main load-carrying elements supporting the bearing guardrails of the topsides skidding system.

[0080] Besides the skidding system, cranes are also used in the dry docks, allowing to install heavy equipment and steel structures onto the GBS from the area near the dock.

[0081] After the GBS construction and equipment installation are complete, the dry dock 13 with the GBS inside is gradually filled with water 14 from the nearby water area with the help of pumps. At each stage of the dock flooding, GBS compartments are checked for leak tightness by hydraulic and pneumatic tests. Along with the dock flooding, GBS ballast compartments are flooded as well, to increase the structure's weight and thus ensure its steadiness on the dock bottom.

[0082] Once tests are complete, GBS is fixed inside the dock with mooring hawsers and retention and guiding dolphins located at the bottom of the dry dock. Once GBS testing and mooring is complete, water is pumped out of the compartments of the moored GBS to ensure its floating up during the high tide.

[0083] The GBS is towed out of the dock by tugboats. After being towed out of the dry dock, the GBS is towed to the installation site. By the onshore winches and by tugs, the GBS is installed in the point of destination at a quayside, where the GBS is connected to onshore communication lines in the deposit area. Once its position is confirmed as correct, the GBS is ballasted to be installed onto a foundation, previously arranged in the bottom of a water body.