RU2229556C1 - Process of erection of deep-sea platform - Google Patents

Abstract

FIELD: exploitation of underwater deposits of mineral resources. SUBSTANCE: invention refers mainly to extraction of liquid and gaseous mineral wealth, to construction of technological complexes, which ensure conducting of operations on deep-sea shelf of open sea. In process of erection of deep-sea platform bottom fastening members are installed in point of extraction of mineral resources, half-submerged base of platform is shipped to point of extraction of mineral resources and base of platform is linked to bottom fastening members with the help of proper load-bearing elements. Upper deck with technological equipment is mounted on base of platform. Bottom fastening members come in the form of cemented piles, holes for them being drilled in advance by means of proper technological equipment. Load-bearing elements are made stiff and are connected to cemented piles and to added underwater pontoon with ballast weight to form rigid truss, for instance, in the form of truncated pyramid which has above-mentioned underwater pontoon in the capacity of upper base. Underwater pontoon is employed as load-bearing element for half-submerged base of platform. EFFECT: increased economic efficiency and operational safety of deep-sea platform thanks to its structural stiffness and small mass and size characteristics. 8 cl, 4 dwg

Description

The invention relates to the development of underwater mineral deposits, mainly liquid and gaseous, to the construction of offshore platforms of technological complexes that provide for work on the deep sea shelf of the open sea.

A technical solution is known, which provides for the construction of an offshore technological complex, including an offshore platform, underwater satellites and an onshore technological base, interconnected by appropriate technological communications, the offshore platform including a base rigidly connected to the soil using piles, and a horizontal platform is installed on the base with technological equipment, and underwater satellites include production wells with wellhead equipment [1].

The base of the offshore platform of the well-known technological module is intended to be installed at relatively shallow depths, since the design does not allow increasing resistance to external loads, in particular tipping moment, acting in conjunction with vibration loads. In addition, on soft soils with low strength characteristics, the use of the known technical solution is complex and economically unjustified.

There is also known a method of constructing a deep-sea offshore platform in which bottom fasteners are installed at the place of mineral extraction, the semi-submerged base of the platform is transported to the place of mineral extraction, and the base of the platform is connected to the bottom fasteners using appropriate power elements, and the upper deck is installed on the platform base with technological equipment [2] - prototype.

At the same time, the offshore platform is attached to the ground using flexible supporting force elements of the anchor system.

A well-known technical solution allows for the extraction of minerals on the high seas at great depths, but it is not reliable when used in the Arctic regions, since it does not have the necessary means to counter the tipping moment. Violation of the integrity of at least one of the flexible power elements of the anchor system, for example, when interacting with underwater ice (stamugs), can lead to unpredictable consequences. The need for a dynamic stabilization system using a well-known technical solution leads to an increase in cost and a decrease in reliability at any latitude with significant sea currents and sea waves.

The present invention is directed to solving the problem of creating a method of constructing a deep-sea stationary offshore technological platform with economic efficiency and operational safety due to the structural rigidity of the offshore platform with small weight and size characteristics.

The specified technical result is achieved by the fact that a method of constructing a deep-sea marine platform is implemented, in which bottom fasteners are installed in the place of mining, the semi-submerged base of the platform is transported to the place of extraction of minerals, and the platform base is connected to the bottom fasteners using the corresponding support force elements, on the base of the platform, an upper deck with technological equipment is installed, and the bottom fasteners They are installed in the form of cemented piles, the wells for which are pre-drilled using the appropriate technological equipment, the supporting force elements are rigid, the latter are connected with cemented piles and with an additionally introduced underwater pontoon with a ballast weight to form a rigid truss, for example, in the form of a truncated pyramid, in which the underwater pontoon is used as the upper base, and the underwater pontoon is used as a supporting element for the semi-submerged platform base rma.

In addition, the underwater pontoon using ballast weight previously positioned relative to the surface of the bottom and the surface of the sea, then fix its position using the auxiliary anchor system.

At the same time, the base of the platform is transported to the installation site, positioned relative to the underwater pontoon, lowered to the seats of the underwater pontoon and fixed to each other using the appropriate fastening joints.

The floating platform with the upper deck, designed for the installation of technological equipment, is transported in the surface position to the place of its installation and positioned relative to the base, reduce the tension of the auxiliary anchor system, raise the base of the marine platform by releasing the ballast tanks of the underwater pontoon, first to ensure their docking and fixing relative to each other, and then for installation in a working position at a given height relative to sea level, after which they provide work whose tension is the auxiliary anchor system.

The supporting power elements of the offshore platform are made with adjustable buoyancy, transported to the installation site in the above-water position, the power element is immersed in an adjustable manner, one of its ends is fixed with the underwater pontoon pivoting fastener, then an additional adjustable immersion of its free end is carried out by rotation relative to the underwater pontoon to ensure contact with the bottom surface with a given angle of inclination.

Using technological equipment installed on the upper deck of the offshore platform, wells are drilled under piles, and the drill pipe is located in the inner cavity of the power element that performs the function of the direction for drilling.

After drilling boreholes under the piles, piles are installed in them and cemented to provide the specified rigidity for bonding with solid soil in advance, and after reaching the specified characteristics of the mentioned rigidity, the power elements are rigidly connected with cemented piles using the appropriate fastening system, then the auxiliary anchor system is removed , and on the upper deck install the appropriate technological equipment.

During the liquidation of the offshore platform after the end of its operation, the technological equipment of the upper deck is sequentially dismantled, the upper deck is disconnected relative to the base of the platform, the fastening system elements are connected, connecting the supporting power elements with cemented piles and the underwater pontoon, and a sequential adjustable lift is achieved by releasing from the corresponding cargo, and transport the aforementioned components of the offshore platform to the technological base to a new place of their installation.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and the identification of sources containing information about analogues for the object-method, allowed to establish that the applicant did not find analogues that are characterized by signs identical to all the essential features of the claimed object-device.

The definition from the list of identified analogues of the prototype, as the closest in the set of essential features, allows you to identify the set of essential, in relation to the perceived by the applicant a single technical result, distinctive features for the claimed object set forth in the independent claim.

Therefore, the claimed object meets the requirement of "novelty" under the current law.

To verify the conformity of the claimed object with the requirement of an inventive step, the applicant conducted an additional search for known solutions in order to identify features that match the distinctive features of the claimed invention from the selected prototype, the results of which show that the claimed invention does not explicitly follow from the prior art.

Therefore, the claimed invention meets the requirement of "inventive step" under applicable law.

The invention is illustrated by the drawings shown in figures 1-4.

Figure 1 shows an example of a structural embodiment of an offshore technological platform in working condition, constructed during the implementation of the proposed method.

Figure 2 - shows the layout of the underwater pontoon with an auxiliary anchor system at the time of positioning relative to it of the upper deck.

Figure 3 - shows the technological position of the base of the platform with the upper deck at the beginning of the operation of the adjustable immersion of the supporting power elements.

Figure 4 - shows a diagram of the drilling of wells for cemented piles.

The offshore platform constructed according to the proposed method in the preferred embodiment (FIG. 1) contains a rigid truss 1 made in the form of a truncated pyramid, which includes supporting force elements 2 forming its side faces. The upper ends of the supporting force elements 2 are rigidly connected with the rotary fasteners 3 of the underwater pontoon 4, and the lower ends are supported on the corresponding end surfaces of the piles 5, connected with the hard rock of the seabed with cement mortar 6. The underwater pontoon 4 contains a tank equipped with ballast weight 7 .

The underwater pontoon 4 contains in its central part seats with fasteners 8, which are designed to locate and secure the body of the semi-submerged base 9. On the base 9 there is a floating platform 10, and on the last there is an upper deck 11 with technological equipment 12.

In a preferred embodiment, the supporting force elements 2 are made with adjustable buoyancy, which provides the corresponding ballast tanks located near its outer shell. In the central part, the supporting force elements 2 are made hollow. The supporting force elements 2 are connected to the piles using a fastening system, which includes a rod element 13 located on the Central part of the supporting force elements 2, the locking mechanism 14 and the clamping mechanism 15.

The deep-sea offshore platform in operational condition includes an underwater technological module 16 containing wellhead equipment (not shown) of the technological wells 17.

For preliminary positioning of the underwater pontoon 4 and the operations necessary for mounting the platform, an auxiliary anchor system 18 (FIGS. 2-4), as well as drilling equipment 19 (FIGS. 3-4), including a drill pipe 20, with a working tool 21 are used (figure 4).

In the most preferred embodiment, the proposed method for the construction of a deep sea platform (Fig. 1) is implemented as follows.

Underwater pontoon 4 is transported to the place of extraction of minerals and, using the auxiliary anchor system 18 (Fig. 2), it is positioned relative to the surface of the water and the bottom of the sea. Then the semi-submerged base of the platform 9 is transported, the floating platform 10 with the upper deck 11, on which the technological equipment is installed 12. The base of the platform 9 is connected with the underwater pontoon 4 and with the floating platform 10, and the underwater pontoon 4 is also with bottom fasteners - cemented piles 5 s using the appropriate supporting force elements 2. Piles 5 are fixed in hard soil with cement mortar 6, the wells for which are pre-drilled using an appropriate technological borudovaniya - drilling equipment 19 (Figures 3-4). The supporting force elements 2 are made rigid, connected to cemented piles 5 and to the additionally introduced underwater pontoon 4 with ballast weight 7 to form a rigid truss 1, for example, in the form of a truncated pyramid, in which the underwater pontoon 4 serves as the upper base, the underwater pontoon 4 is used as a supporting element for the semi-submerged base 9 of the offshore platform.

In this case, the underwater pontoon 4 using ballast weight 7 is pre-positioned relative to the bottom surface and the surface of the sea, then fix its position using the auxiliary anchor system 18 (figure 2).

In addition, the base of the platform 9 is transported to the installation site, positioned relative to the underwater pontoon 4, lower it to the seats of the underwater pontoon and fix them relative to each other using the corresponding mounting elements 8.

The floating platform 10 with the upper deck 11 of the offshore platform intended for the installation of technological equipment 12 is transported above the installation site and positioned relative to the base 9, reduce the tension of the auxiliary anchor system 18, raise the base 9 of the marine platform by releasing the tank of the underwater pontoon 4 from ballast cargo, first to ensure their docking and fixing relative to each other, and then for installation in a working position at a given height relative to the level nya the sea, after which they provide the working tension of the auxiliary anchor system.

The supporting power elements 2 of the offshore platform are made with adjustable buoyancy, transported to the installation site in the above-water position (Fig. 3), the power element 2 is immersed in an adjustable manner, one of its ends is fixed with the swivel fastener 3 of the underwater pontoon 4, and then an additional adjustable immersion of its free end by turning relative to the underwater pontoon 4 until it makes contact with the bottom surface with a given angle of inclination.

Using technological equipment - drilling equipment 19 (Fig. 4) installed on the upper deck 11 of the floating platform 10, wells are drilled under the piles, and the drill pipe 20 is located in the inner cavity of the supporting force element 2, which serves as a direction for drilling.

After drilling boreholes under the piles, piles 5 are installed in them and cemented to provide the predetermined stiffness of the bond with hard soil, and after reaching the specified characteristics of the mentioned stiffness, the power elements 2 are rigidly connected to the cemented piles using the appropriate fixing system, then the auxiliary is removed anchor system 18, and on the upper deck 11 install the appropriate technological equipment.

During the liquidation of the offshore platform after the end of its operation, sequential dismantling of technological equipment 12 of the upper deck 11, the floating platform 10 relative to the base of the platform 9 is carried out, the elements of the fastening system connecting the supporting power elements 2 with cemented piles 5 and the underwater pontoon 4 are disconnected and their sequential adjustable lifting, by releasing from the corresponding ballast cargo, and transporting the mentioned components of the offshore platform to the technological base or to a new place of their installation.

The proposed technical solution allows to increase the economic efficiency of the design of the deep-sea offshore technological platform by providing the possibility of a rigid connection with the seabed and the use of a rigid truss with a simultaneous decrease in weight and size characteristics. To optimize the platform’s parameters while ensuring operational safety when installing it at depths of over 300 m with the fulfillment of environmental safety requirements.

Thus, for the claimed invention in the form described in the independent clause below of the claims, the possibility of its implementation using the means and methods described above and known prior to the priority date with the expected technical result is confirmed.

Therefore, the claimed facility meets the requirement of “industrial applicability” under applicable law.

Sources of information

1. RF patent No. 2166065, cl. E 21 B 43/01, 2001.

2. US Patent No. 5381865, cl. B 63 B 35/44, 1995.

Claims (8)

1. A method of constructing a deep-sea offshore platform in which bottom fasteners are installed at a mining site, a semi-submerged base of the platform is transported to a mining site, and the platform base is connected to the bottom fasteners using appropriate support force elements, and the upper deck is installed on the base of the platform with technological equipment, characterized in that the bottom fasteners are made in the form of cemented piles, wells for which pre-drilled using appropriate technological equipment, the supporting power elements are rigid, the latter are connected with cemented piles and with an additionally introduced underwater pontoon with a ballast weight to form a rigid truss, for example, in the form of a truncated pyramid, in which the underwater pontoon serves as the upper base, moreover, the underwater pontoon is used as a supporting element for the semi-submerged base of the platform. 2. The method according to claim 1, characterized in that the underwater pontoon using ballast weight is pre-positioned relative to the bottom surface and the surface of the sea, then fix its position using the auxiliary anchor system. 3. The method according to claim 1 or 2, characterized in that the base of the platform is transported to the installation site, positioned relative to the underwater pontoon, lowered to the seats of the underwater pontoon and fixed relative to each other using appropriate fastening connections. 4. The method according to claim 3, characterized in that the floating platform with the upper deck, designed for the installation of technological equipment, is transported in the water position to the place of its installation and positioned relative to the base, reduce the tension of the auxiliary anchor system, raise the base of the offshore platform by releasing ballast tanks of the underwater pontoon, first to ensure their docking and fixation relative to each other, and then for installation in a working position at a given height relative to the level to the sea, and then provide a working tension of the auxiliary anchor system. 5. The method according to claim 1 or 4, characterized in that the supporting power elements of the offshore platform are made with adjustable buoyancy, transported to the installation site in the surface position, the dive of the power element is carried out, one of its ends is fixed with a swivel fastening element of the underwater pontoon , then carry out additional adjustable immersion of its free end by rotation relative to the underwater pontoon until it contacts the bottom surface with a given angle of inclination. 6. The method according to claim 5, characterized in that using technological equipment installed on the upper deck of the offshore platform, wells are drilled under the piles, the drill pipe being located in the inner cavity of the power element that performs the function of the direction for drilling. 7. The method according to any one of claims 1 to 6, characterized in that, after drilling the wells, piles are installed under the piles and cemented in order to provide a predetermined stiffness of communication with solid soil, and after reaching the specified characteristics of said stiffness, power elements are rigidly connected with cemented piles using an appropriate fixing system, then the auxiliary anchor system is removed, and the corresponding technological equipment is installed on the upper deck. 8. The method according to claim 1 or 7, characterized in that during the liquidation of the offshore platform after the end of its operation, the technological equipment of the upper deck is sequentially dismantled, the upper deck is disconnected relative to the base of the platform, the fastening system elements connecting the supporting power elements to the cemented piles are disconnected and underwater pontoon, and carry out a sequential controlled lift by releasing from the corresponding ballast weight, and transport said components of fruit drink second platform technology base or to a new place of their installation.

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