RU2280128C1 - Method for offshore platform erection - Google Patents

Abstract

FIELD: underwater mineral deposit development, particularly to produce liquid and gaseous substances, namely artificial islands mounted on piles or like supports.

SUBSTANCE: method involves successively installing semisubmersible base and horizontal platform with production equipment on ground; fastening semisubmersible base body with ground by means of hollow piles to be filled with cement, wherein each pile includes outer and inner casing pipes and gap between the casing pipes is filled with cement mortar, outer casing pipe has length enough to span unstable rock layer, inner casing pipe has length to provide predetermined tie between the casing pipe and stable rock; fixedly connecting platform base and inner casing pipe with each other with the use of anchor strength joint comprising rod member, anchor and hydraulic tightening mechanism, wherein the anchor may be rigidly secured to inner casing pipe at predetermined depth; installing semisubmersible base body on ground support panel; fastening outer casing pipe of the pile with ground support panel arranged on gravel bed adapted to level ground; securing base body to ground support panel with the use of anchor strength joints with predetermined force, which is measured during platform usage in dependence of ambient conditions change.

EFFECT: increased seismic stability, possibility to erect platform on stable and unstable ground.

3 cl, 4 dwg

Description

The invention relates to the development of underwater mineral deposits, mainly liquid and gaseous, to the construction of technological complexes with a wide range of external conditions and soil characteristics of the seabed.

A technical solution is known that is aimed at solving the problem of the possibility of operating an offshore platform in the Arctic latitudes, it is envisaged that the base of the offshore platform be made of two modules with the possibility of linear movement relative to each other, removed from the base and transporting the carrier platform afloat to a safe place from the trajectory iceberg [1].

The known technical solution provides for the availability of technological satellites, since the design of the offshore platform does not provide for the possibility of installing wells directly on the platform.

A known method of constructing an offshore platform in which a semi-submerged base, a horizontal platform with technological equipment is successively installed on the ground, the base of the offshore platform being connected to the ground using hollow cemented piles, each of which contains an outer and inner casing, the space between which is filled with cement mortar , the length of the inner casing is selected from the condition of overlapping unstable rocks, the length of the outer casing is selected from the condition of cross-flow in advance of a given connection with stable rocks, the semi-submerged base of the platform and the inner casing are rigidly connected using an anchor power connection, including a rod element, an anchor and a hydraulic tensioning mechanism, the anchor being able to be rigidly connected to the inner casing at a given depth [2 prototype ].

The known technical solution can be effectively used on fairly stable soils, as for soft soils, when using anchor power connections, the platform base may be skewed due to the heterogeneity of the soil characteristics and the presence of a gap between the outer casing of the pile and the base of the platform.

The present invention is directed to solving the problem of creating seismic-resistant stationary offshore technological platforms that can be installed both on unstable soils and stable soils, ensuring economic efficiency and operational safety in seismically hazardous areas, as well as by eliminating the interaction of offshore platforms with thick ice cover and icebergs.

The specified technical result is achieved by the fact that a method of constructing an offshore platform is implemented, in which a semi-submerged base, a horizontal platform with technological equipment are successively installed on the ground, the semi-submerged base of the offshore platform being connected to the ground using hollow cemented piles, each of which contains an external and internal casing pipes, the space between which is filled with cement mortar, the length of the inner casing pipe is selected from the condition of overlap n stable rocks, the length of the outer casing is chosen from the condition of ensuring a predetermined connection with stable rocks, the base of the platform and the inner casing are rigidly connected using an anchor power connection, including a rod element, an anchor and a hydraulic tensioning mechanism, and the anchor has the possibility of rigid connection with the inner casing pipe at a given depth, while the semi-submerged base of the platform is installed on the bottom base plate, the outer casing of the cemented pile they are tightly bonded to the bottom base plate, the bottom base plate is mounted on a gravel pad, with which the soil is pre-aligned, and the base case is attached to the bottom base plate using an anchor power connection with a predetermined force, which is changed during operation depending on changes in the external conditions.

In addition, to increase the reliability of the construction of the offshore platform on unstable soils at great depths, with the exception of interacting with a thick ice cover, the base is made of two modules, the base of the lower base module is made with an underwater horizontal platform with wellhead connectors and docking elements to allow connection to the semi-submerged body the base of the platform and with the appropriate communications and fasten the lower module housing to the bottom base plate using anchor forces outlets, while the hydraulic tensioning mechanism is installed on an underwater horizontal platform.

To increase reliability by eliminating interaction with icebergs, an intermediate horizontal platform is installed on the lower module of the platform base, with the possibility of vertical movement along the guides from the corresponding drive, and the guides are arranged uniformly around the circumference relative to the production wells that are installed in the central part of the platform base, while the semi-submerged base connected to the intermediate horizontal and corresponding communications using trorazemnyh compounds.

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

Figure 1 shows an example implementation of an offshore technological platform for shallow depths, made by the proposed method.

Figure 2 is an example of an anchor power connection.

Figure 3 is an example of the implementation of the offshore platform in areas with a thick ice cover.

Figure 4 is an example of the implementation of the offshore platform in areas with the possible passage of icebergs.

The offshore technological platform for shallow depths - up to 50 m (Fig. 1) contains a semi-submerged base 1 on which a horizontal platform 2 with technological equipment 3 is installed. The semi-submerged base 1 is mounted on the bottom base plate 4, which is located on the gravel cushion 5 and is attached to soil using hollow cemented piles 6. In the central part of the base are located production wells 7 with wellhead equipment 8.

The semi-submerged base 1 is attached to the bottom base plate using anchor power connections, which include a rod element 9, one end rigidly connected to the anchor 10 installed inside the hollow cemented pile 6, and the other with a hydraulic tensioning mechanism 11, the body of which is rigidly mounted on the semi-submerged base 1.

The hydraulic tensioning mechanism 11 (FIG. 2) contains hydraulic cylinders evenly spaced around the circumference, the rods 12 of which through the washer 13 and the conical wedges 14 are able to force short circuit with the lateral surface of the rod of the free end part of the rod element 9.

Hollow cemented pile 6 contains an outer casing 15 and an inner casing 16, the space between which is filled with cement mortar 17. The outer casing 15 is rigidly connected to the bottom support plate 4. The length of the outer casing 15 is selected from the condition of overlapping unstable rocks, and the length of the inner the casing pipe 16 is selected from the condition of providing a predetermined connection with stable rocks.

At great depths and with the possibility of the formation of a thick ice cover, the base of the offshore platform is made of two modules (Fig. 3). The case of the lower base module 18 is made with an underwater horizontal platform 19 with wellhead equipment 8, docking elements and quick-disconnect connections (not shown) to enable connection with the upper module case - a semi-submerged base 1 and with the corresponding communications. The housing of the lower base module 18 is attached to the bottom base plate 4 by means of anchor power connections, while the hydraulic tensioning mechanism 11 is mounted on an underwater horizontal platform 19.

To increase reliability by eliminating interaction with icebergs (Fig. 4), the case of the lower module 18 of the base of the platform is equipped with an intermediate horizontal platform 20. The intermediate horizontal platform 20 and the case of the lower module 18 of the base of the platform are provided with guides 21 for relatively vertical movement. The guides 21 are arranged uniformly around the circumference relative to the production wells 7 installed in the central part of the platform base, and the upper base module 1 has the ability to quickly connect to the intermediate horizontal platform 20 and the corresponding communications.

The proposed method is implemented as follows.

At the construction site of the offshore technological platform, a semi-submerged base 1, a horizontal platform 2 with technological equipment 3 are successively installed on the ground, and the semi-submerged base 1 of the offshore platform is connected to the ground using hollow cemented piles 6, each of which contains an outer 15 and an inner 16 casing pipe , the space between which is filled with cement mortar 17, the length of the outer casing 15 is selected from the condition of overlapping unstable rocks, and the length of the inner casing S 16 choose from the condition of providing a predetermined connection with stable breeds. The semi-submerged base 1 of the platform and the inner casing 16 are rigidly connected by means of an anchor power connection including a rod element 9, an anchor 10 and a hydraulic tensioning mechanism 11, the anchor 10 being able to be rigidly connected to the inner casing 16 at a predetermined depth. The semi-submerged warp 1 of the platform is installed on the bottom support plate 4, the outer casing 15 of the hollow cemented pile 6 is rigidly connected to the bottom support plate 4, the bottom support plate 4 is installed on the gravel cushion 5, with which the soil is pre-aligned, and the case of the semi-submerged base 1 of the platform attached to the bottom base plate 4 by means of an anchor power connection with a predetermined force, which is changed during operation depending on changes in external conditions.

In addition, in order to increase the reliability of the construction of the offshore platform on unstable soils at great depths, with the exception of interaction with a thick ice cover (Fig. 3), the base is made of two modules, the body of the lower base module 18 is made with an underwater horizontal platform 19 with wellhead equipment 6, by connecting elements and quick-disconnect connections to ensure the possibility of connection with the upper module case - semi-submerged base 1 and with the corresponding communications, and fix the lower case module 18 of the base to the bottom base plate 4 using anchor power connections, while the hydraulic tensioning mechanism 11 is installed on an underwater horizontal platform 19.

When approaching a thick ice cover, the housing of the semi-submerged base 1 is disconnected from the housing of the lower base module 18 and taken to the technological base. At the same time, mining is carried out automatically. After passing the ice cover, the offshore technological platform is set to its original position.

In order to increase reliability by eliminating the interaction with icebergs (Fig. 4), an intermediate horizontal platform 20 is mounted on the lower module of the base of the platform 18 with the possibility of vertical movement along the guides 21 from the corresponding drive, and the guides 21 are arranged uniformly around the circumference relative to the production wells 7, which installed in the central part of the base of the platform, while the housing of the semi-submerged base 1 is connected to an intermediate horizontal platform and, accordingly, Enikeev communications via quick couplings.

When the iceberg is approaching, the case of the semi-submerged base 1 of the offshore platform is disconnected from the intermediate horizontal platform 20 and removed from the trajectory, and the intermediate horizontal platform 20 is lowered along the guides 21 to a predetermined level. At the same time, mining is also carried out automatically. After passing the iceberg, the offshore technological platform is set to its original position.

The proposed technical solution allows to increase the economic efficiency of the construction of the marine technological complex in areas of increased seismicity, as well as by ensuring the possibility of eliminating the interaction of the offshore platform with thick ice and icebergs.

The proposed method allows to provide the necessary rigidity and stability of the structure in the normal operating mode of the offshore platform and allows for uninterrupted operation of technological communications during the removal of the horizontal platform.

Thus, for the claimed invention in the form described in the independent clause of the claims below, 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.

Information sources

1. RF patent No. 2215847, cl. E 02 B 17/00, 2001.

2. RF patent No. 2232227, class. E 02 B 17/00, 2003.

Claims (3)

1. A method of constructing an offshore platform in which a semi-submerged base, a horizontal platform with technological equipment are successively installed on the ground, the body of the semi-submerged base of the offshore platform is connected to the ground using hollow cemented piles, each of which contains an outer and inner casing, the space between which filled with cement mortar, the length of the outer casing is chosen from the condition of overlapping unstable rocks, the length of the inner casing is chosen t from the condition of providing a predetermined connection with stable rocks in advance, the base of the platform and the inner casing are rigidly connected by means of an anchor power connection comprising a rod element, an anchor and a hydraulic tensioning mechanism, the anchor being able to be rigidly connected to the inner casing at a given depth, different the fact that, in order to increase the reliability of the construction of offshore platforms on unstable soils, the body of the semi-submerged base of the platform is installed on the bottom support plate that outer casing of the hollow cemented pile is rigidly connected to the bottom support plate, the bottom support plate is mounted on a gravel cushion with which the soil is pre-aligned, and the base body is attached to the bottom support plate using anchor force connections with a predetermined force, which is changed during operation, depending on changes in external conditions. 2. The method according to claim 1, characterized in that, in order to increase the reliability of the construction of the offshore platform on unstable soils at great depths with the exception of interaction with a thick ice cover, the base is made of two modules, the lower base module body is made with an underwater horizontal platform with wellhead equipment, docking elements and quick-connects to enable connection with the housing of the semi-submerged base of the platform and with the corresponding communications, and fasten the housing the lower base module to the bottom base plate using anchor power connections, while the hydraulic tensioning mechanism is installed on an underwater horizontal platform. 3. The method according to claim 2, characterized in that, in order to increase reliability by eliminating interaction with icebergs, an intermediate horizontal platform is installed on the lower module of the base of the platform with the possibility of vertical movement along the guides from the corresponding drive, and the guides are arranged uniformly around the circumference relative to production wells, which are installed in the central part of the base of the platform, while the body of the semi-submerged base is connected to the intermediate horizontally platform and associated communications via quick couplings.

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