ES2386268B1 - REDUNDANT SYSTEM OF SEALING, FLOATABILITY AND DIVING CONTROL FOR FLOATING PLATFORMS - Google Patents

Abstract

Redundant sealing, buoyancy and immersion control system for a floating platform equipped with a foundation slab that makes a controlled speed dive until it rests on the sea floor and a deck that remains afloat at all times, said redundant system comprising a primary, secondary and tertiary buoyancy system located on the foundation slab and formed by floats and / or sheets of geotextile material, a buoyancy system for equipment and operation and maintenance plants formed by a set of floats located on the deck , a set of submersible pumps, a control console and automation of immersion operations and a set of programmable valves. This redundant system allows any platform to be easily towed to its final location in the sea, ocean, lake ... regardless of its size, shape or weight and weather conditions.

Description

DIVING FOR FLOATING PLATFORMS

Technical Sector of the Invention The present invention consists of a redundant system to make any platform or device that requires it floating and unsinkable. The system also allows control of the immersion of the platform or device in question at a controlled speed. BACKGROUND OF THE INVENTION In the current state of the art innumerable applications have been found to pneumatic floats. The industry has also developed specific materials for each application, including the development of textile materials capable of withstanding the impact of machine gun bullets and used in military boats for landing operations. Therefore, the industry offers a wide range of materials and manufacturing procedures that provide a large base capacity for the design of specific applications. In the present invention it discloses a system of watertightness, buoyancy and immersion control that makes use of pneumatic floats, so that the platform that has this system can be easily towed to its final location in the sea, ocean, lake ... regardless of its size, shape or weight and the weather conditions. Also, this system allows immersion at controlled speed once the platform is in its final location. Description of the invention The present invention consists of a set of floats to make any device unsinkable, such as, for example, a platform. The set of repeated systems, guaranteed even that, in the case of collapse of all the floats of a system, the platform or the device put afloat is unsinkable and can reach the classification of new ship in an intact condition, which allows its towing to any location. To guarantee this condition, the set of buoyancy systems consists of the following units: - Primary buoyancy system. -Secondary buoyancy system.

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Buoyancy system of equipment and operation and maintenance plants, which must remain afloat during the immersion of the platform foundation. The primary and secondary buoyancy systems are formed by a series of pneumatic floats protected by a cover formed by a geotextile material and a light and waterproof material such as expansive clay, expanded polystyrene, polyurethane, etc. Each float is in turn composed of a set, variable in number, of individual floats each with its inflation and emptying valve and connected to each other by a device that allows simultaneous inflation and emptying. The floats are linked together by a steel cable to facilitate recovery. The floats are fixed to the foundation of the platform either by introduction into the gaps of the beams that stiffen it or by means of holes created especially with steel bridges embedded in the foundation slab when it is stiff by edge. The primary flotation system, so named because it is the one that is installed first, is formed by the set of floats located centrally and radially in the foundation of the platform. The secondary flotation system, so named because it is the one that is installed in second place, is formed by the set of floats located on the perimeter of the foundation and attached to a board constructed with two sheets of steel or any other resistant material between the that a light, low-density and shear-resistant panel is arranged, the assembly being configured with a sandwich of steel or resistant material, light core and steel or resistant material, at the bottom of this sandwich panel a high-strength geotextile constructed is fixed with two blankets of permeable geotextile that inside integrate from outside to inside a protective material formed by expansive clay or polyurethane or expanded polystyrene pellets, then a waterproof sheet. This secondary system retains the breakwater that is located in the enclosed space between the sandwich panel and the geotextile attached to them. The function of the breakwater is, once released, to protect the foundation from erosion when the foundation is perched on the sea floor. In the upper part of the high-strength geotextile material, the steel cables for the recovery of the floats and others that, through the sandwich panel, are attached to a cocktail located on the deck, are firm.

firmly the geotextile that is part of the secondary system and forms a closed bag inside which the breakwater is housed.

The tertiary buoyancy and safety system is formed by a sandwich structure. The manufacturing process of this system is as follows: A geotextile sheet is extended, radial steel wheels are glued on it. The space between the tires is filled with expansive clays until they are flush with the tires. On these a sheet of waterproof material is glued and on it an inner geotextile. When the floating platform or artifact is floated, as the geotextile is permeable, the clays get wet and expand creating a completely impermeable layer that also protects the impermeable sheet from an eventual puncture and if this occurs, it would plug them instantly. The tertiary system is embedded under the foundation slab and continuously surrounds the entire platform, reaching the deck or operation and maintenance plant where the tertiary system is fixed. The tertiary system is formed by a sandwich structure of geotextile material, which has radially inserted tires. The tires allow fixing to the cover, for this they have a hole in their upper end. The geotextile material has eyelets reinforced with metal rings. A round steel bar is passed through the holes of the tires and the eyelets, folding them, to adjust their dimension to that of the side of the tire. The steel bars are fixed to a cable cocktail which allows them to be tensioned on the roof. During the immersion, the tractel are releasing cable at the same speed as the immersion, once the bottom is reached the fixing of the bars is released so that they fall down on the bottom. Once the foundation of the artifact in question is possessed on the sea floor, the tertiary system formed by a sandwich structure is deployed and extends around the foundation; likewise, the cables that hold the geotextile of the secondary system are released, the breakwater falls by its weight and the sandwich panels with positive buoyancy ascend towards the surface dispersing the breakwater over the geotextile of the tertiary system, which will have been previously deployed on the bottom of the sea. Pulling with the tractel located on the cover of the cables attached to the sandwich panels, the dispersion of the breakwater is improved and the recovery of the primary and secondary systems is facilitated and guaranteed.

It is formed by other floats with the same characteristics as those of the primary and secondary system and are arranged both perimetrically and radially between the gaps of the roof beams. Its mission is to keep the equipment and operation and maintenance plants afloat. Its displacement, much higher than its weight, guarantees even more buoyancy to the whole set. The installation procedure for these and other types of floats is as follows: The partially deflated floats are placed in the holes and finished inflating, which increases their volume and compresses and closes on their supports. The redundant system of watertightness, buoyancy and immersion control also has the complementary, auxiliary and basic units that allow immersion control once the platform is in its final location. These units give the following:

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Plugs that close the gaps in the roof for flooding the watertight compartments.

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A set of submersible pumps located on the perimeter of the platform. The pumps, which allow the flooding of the watertight compartments created in the floating platform or device in question, are placed on articulated dampers equipped with turning actuators that allow the pumps to be submerged and raised.

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A control console and automation of immersion operations.

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A set of programmable valves in two off / on positions. On off they are closed for the transport of the platform and on they open when the pressure of the internal air of the floats reaches the predetermined Once located in the final location, the foundation of the platform must be submerged in a controlled way so that there is no large impact against the sea floor. For this, water is introduced into the watertight compartments by means of the pumps, previously removing the plugs, so that this water is pressing the floats of the primary and secondary system and these are deflated, always in a controlled way, as the flow rate of the Air is controlled by float valves. Therefore, the decrease in displacement volume and immersion speed is controlled. The secondary and primary systems are recovered on the surface once the immersion is carried out.

To complete the description that is being made and in order to help a better understanding of the characteristics of the invention, a set of drawings is attached where, with an illustrative and non-limiting nature, the following has been represented: Figure 1: View in elevation of a platform with all the buoyancy systems installed Figure 2: Plan view of the float assembly of the equipment and operation and maintenance plant in which the deck of the latter has been removed. Figure 3: Perspective view of recoverable floats of all buoyancy systems. Figure 4: Plan view of a deployed tertiary system, the primary system and the secondary system Figure 5: Detail of the floats that form the systems. Figure 6: Perspective views of a secondary system float attached to a high strength geotextile material and the sandwich panel. Figure 7: Details of davits and pumps for flooding the watertight compartments and controlled immersion of the whole. The following is a list of the references used in the figures: 1-Floats of the primary system 2-Floats of the secondary system 3-Geotextile material of the secondary system 4-Sandwich panel of the secondary system 5-Floats of the buoyancy system of the plant of equipment and operation and maintenance 6-Individual floats 7-Valve 8-Submersible pumps 9-Davits 10-Wheels 11-Geotextile material of the tertiary system 12-Watertight compartments

Detailed description of the invention

In order to achieve a better understanding of the invention, the redundant system of sealing, buoyancy and

The redundant sealing, buoyancy and immersion control system of an oceanic platform comprises the following units: -A primary buoyancy system consisting of two-lobe floats (1) between which there is a recess to be inserted between the stiffening beams central and radial of the foundation slab of the platform. -A secondary system formed by other floats (2) of a single lobe that attached to sandwich panels (4), are inserted perimetrically to the foundation slab. These floats are attached to a high strength geotextile material (3) on which the jetty is placed and folded over it, closing on the beam. -A tertiary system formed by a geotextile material (11) with a sandwich structure and which has wheels (10), a layer of expansive clay and a layer of impermeable material. The tertiary system is embedded under the foundation slab and continuously surrounds the entire platform, reaching the deck or operation and maintenance plant where it is fixed. The rims (10) allow fixing to the cover, for this they have a hole in their upper end. The geotextile sheets (11) have eyelets reinforced with metal rings. A round steel bar is passed through the holes of the tires and the eyelets, folding them, to adjust their dimension to that of the side of the tire. The steel bars are fixed to a cable cocktail which allows them to be tensioned on the roof. During the immersion, the tractel are releasing cable at the same speed as the immersion, once the bottom is reached the fixing of the bars is released so that they fall down on the bottom. - Buoyancy system of the equipment and operation and maintenance plant, which is formed by floats (5) arranged radially and perimetrically in the gaps of the beams of the deck of the platform. This system is what keeps the equipment and operation and maintenance plant floating and unsinkable at all times, from the towing of the platform to its final location and during the immersion of the foundation of the platform. The set of floats of the primary and secondary system, compressed together or against the beams of the foundation slab of the platform, gives rise to a series of watertight compartments (12). The floats of the primary, secondary and buoyancy system of the equipment and operation and maintenance plant are lined with a sheath of geotextile material and expanded polystyrene pellets. Each float is in turn

one of them with its inflation and emptying valve (7) and connected to each other by a device that allows simultaneous inflation and emptying. The redundant system object of the invention also has submersible pumps (8) placed on davits (9) that allow the pumps to be moved, submerged or hoisted, as required. These pumps are responsible for filling the watertight compartments created by the set of floats of the primary and secondary system system to produce the immersion of the platform foundation. As the pumps fill the compartments with water, the water pressures the floats and they deflate, decreasing the volume of displacement and, therefore, causing the platform foundation to submerge. This immersion process is carried out at a controlled speed thanks to a control console and automation of immersion operations, as well as the presence of programmable valves on the floats that allow the control of air flow output. When the foundation of the platform rests on the sea floor, the geotextile of the tertiary system (11) is released and falls extending along the entire perimeter of the platform, the breakwater between the floats (2) and the geotextile material of the secondary system ( 3) buoyancy, is released, so that it is scattered around the foundation and on the extended geotextile of the tertiary system (11), protecting the foundation from erosion. The redundant system object of the present invention makes any platform unsinkable, since it makes it possible to achieve the classification of a new ship in an intact condition that allows its towing to any location, by creating sealed, closed compartments that prevent entry of water.

Claims (4)

1.-Redundant sealing system, buoyancy and immersion control of a floating platform consisting of a foundation slab stiffened by beams or edge and a cover, also provided with beams, said system allowing the platform towing to its platform final location regardless of size, shape, weight and weather conditions, as well as controlled speed immersion of the foundation slab until resting on the sea floor once the platform is in its final location, maintaining the deck of the platform afloat at all times, said redundant system characterized by comprising the following units:

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primary sealing system formed by a set of floats (1) located centrally and radially in the foundation slab of the floating platform

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Secondary sealing system formed by a set of floats (2) located on the perimeter of the foundation of the floating platform and attached to a panel with a sandwich structure (4) to which bottom is fixed a sheet of high strength geotextile material (3) that folds over said panel forming a bag where the breakwater is housed, which, once released, protects the foundation slab from erosion when the foundation is perched on the sea floor

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tertiary sealing and safety system formed by a sandwich structure of geotextile material (11), said tertiary system being embedded under the foundation slab and surrounding it continuously, reaching the roof

or operation and maintenance plant of the platform where said tertiary system is fixed

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buoyancy system of equipment and operation and maintenance plants located on the deck, formed by floats (5) that are arranged both perimetrically and radially between the gaps of the roof beams; This system is the one that keeps the equipment and operation and maintenance plant floating and unsinkable at all times, from the towing of the platform to its final location and during the immersion of the foundation slab of the platform

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plugs that close the gaps in the cover for flooding the watertight compartments (12) to which the float assembly of the

primary and secondary system compressed together or against the beams of the foundation slab of the platform - a set of submersible pumps (8) located on the perimeter of the platform, that allow the flooding of the watertight compartments (12) -a control console and automation of immersion operations -a set of programmable valves (7) for the inflation and emptying of the primary and secondary system floats in a controlled manner 2.-Redundant sealing, buoyancy and immersion control system, according to claim 1, characterized in that the floats of the primary system, those of the secondary and those of the buoyancy system of equipment and operation plants and maintenance are in turn composed of a set of individual floats (6) each of them with its inflation and drain valve (7) and connected to each other by a device that allows simultaneous inflation and emptying. 3.-Redundant system of tightness, buoyancy and immersion control, according to claim 1, characterized in that the floats of each of the systems are connected to each other by a steel cable to facilitate recovery. 4.-Redundant system of tightness, buoyancy and immersion control, according to claim 1, characterized in that the floats of the primary system, those of the secondary system and those of the buoyancy system of the equipment and operation and maintenance plants are protected by a material Light and waterproof and a cover formed by a geotextile material. 5.-Redundant system of watertightness, buoyancy and immersion control, according to claim 4, characterized in that the lightweight and waterproof material that protects the floats is expansive clay, expanded polystyrene or polyurethane. 6.-Redundant system of tightness, buoyancy and immersion control, according to claim 1, characterized in that the floats of the primary and secondary system are fixed to the foundation either by introduction into the gaps of the beams that stiffen it or by means of gaps specially created with steel bridges embedded in the foundation slab when it has the stiffness of edge. 7.-Redundant system of watertightness, buoyancy and immersion control, according to claim 1 characterized in that the sheet of high strength geotextile material (3) of the secondary system is constructed, in turn, with two permeable geotextile blankets that in its Inside they integrate from outside to inside a protective material formed by expansive clay or polyurethane or expanded polystyrene pellets and an impermeable sheet. 8.-Redundant sealing, buoyancy and immersion control system according to claim 1, characterized in that the sandwich structure of the tertiary system (11) is formed by a geotextile sheet on which radial steel wheels (10) have been glued , a layer of expansive clay, a sheet of waterproof material and an inner geotextile sheet. 9.-Redundant system of watertightness, buoyancy and immersion control according to claim 1 characterized in that the pumps (8) are placed on articulated davit (9) provided with rotary actuators that allow the pumps to be submerged and raised. 10.-Procedure for the controlled immersion of the foundations of a floating platform using the redundant system of sealing, buoyancy and immersion control described in previous claims, characterized in that water is introduced into the watertight compartments (12) by means of the pumps ( 8), previously removing the plugs, so that this water is pressing the floats of the primary and secondary system and these are deflated, always in a controlled way thanks to a control console and automation of the immersion operations, as well as the presence of programmable valves (7) on the floats that allow the control of air flow output and, once the foundation rests on the sea floor, the sandwich structure of geotextile material (11) of the tertiary system is released by releasing the cable that keeps it moored on deck and falls extending around the perimeter of said foundation; likewise, the breakwater falls by its own weight when the cables that hold the geotextile sheet (3) of the secondary system that retains it are released, so that the breakwater is scattered around the foundation and on the extended geotextile of the tertiary system ( 11), protecting the foundation from erosion. 11.-Procedure for the controlled immersion of the foundation of a floating device according to claim 10, characterized in that the floats of the secondary and primary system are recovered on the surface once the immersion is carried out thanks to the steel cables that hold all the floats together. each of the primary and secondary systems. . "