RU2307894C1 - Method for processing platform erection - Google Patents

Abstract

FIELD: construction, particularly artificial islands mounted on piles or like supports, for example, platforms on raisable legs to be erected in wide ambient condition and surface ground characteristic range, in flood plains, water-logged ground, in permafrost zones, sandy ground characterized by varying relief and marine platforms to be erected at any depth.

SUBSTANCE: method for processing platform erection in surface ground involves installing support slab having central depression; forming wells provided with head connectors in the depression; installing load-bearing processing equipment structure on the support slab. The support slab includes rigidly connected central and peripheral parts fastened to ground by means of central and peripheral cemented piles provided with main tensioning connections. Load-bearing processing equipment structure is made as integral truss or truss composed of several modules and is connected to support slab by means of additional tensioning connections.

EFFECT: extended field of processing platform usage.

4 cl, 4 dwg

Description

The invention relates to the development of mineral deposits, mainly liquid and gaseous, to the construction of technological platforms under a wide range of external conditions and characteristics of surface soils, flooded soils at river mouths, swampy soils in mid-latitudes or in permafrost, on sandy loose soils with variable surface relief, as well as with a wide range of depths during the construction of offshore technological platforms in marine conditions.

There is a method of constructing an offshore technological platform, in which a semi-submerged base, a horizontal platform with technological equipment are 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 solution, the length of the outer casing is chosen from the condition of overlapping unstable rocks, the length of the inner casing is chosen from the condition of providing a predetermined 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 [1 ].

This technical solution, despite the possibility of evenly distributing the load on the anchor joints of the supporting structural elements of the offshore platform and increasing the counteraction to external loads acting on the offshore platform, has a fairly narrow range of its application in terms of the depth of installation of offshore platforms.

There is also known a method of constructing a technological platform, in which a base plate with a central recess is installed on surface soil, inside which wellhead connectors of wells are located, and a supporting structure of the processing equipment is installed on the base plate [2].

The well-known technical solution also does not solve in full the task of increasing the range of installation depths of technological platforms.

The present invention is directed to solving the problem of economic efficiency of the construction of offshore technological platforms by providing the possibility of increasing the range of installation depths with a wide range of changes in external conditions and characteristics of surface soils, flood soils at river mouths, marshy soils in mid-latitudes or in permafrost, and also on sandy loose soils with a variable surface topography.

The solution of this problem is achieved by the fact that a method of constructing a technological platform is implemented, in which a base plate with a central recess is installed on the surface soil, inside which wells with wellhead connectors are installed, the supporting structure of the processing equipment is installed on the base plate, and the base plate is made in the form of rigidly connected central and peripheral parts that are bonded to the ground using central and peripheral cemented piles with the corresponding basis tension joints, while the supporting structure of the process equipment is made in the form of a single truss or truss composed of several modules, and connected to the base plate using additional tension joints.

In addition, the central part of the base plate is made in the form of a polygon, the peripheral parts of the base plate are formed using beams that are rigidly connected to each other and the central part of the base plate to form a generally star-shaped structure, at the tops of which are the places for installing peripheral cemented piles and fastening means additional tension joints of the supporting structure, made in the form of a single truss or truss, composed of several modules, on which the means of creation are also installed Filling additional tension joints.

When installing a technological platform on unstable surface soils, for example, in permafrost, marshy, either flood or sand, in the central recess of the base plate until a stable rock is reached, a mine with directions for wells is removed from which unstable rocks are removed and filled with a material with low thermal conductivity while the lower surface of the base plate is located at a height that ensures the passage of flood water or the movement of sandy soil.

When installing the technological platform at sea at great depths, the supporting structure of the technological equipment is made of fixed, movable and removable modules, and the means for attaching additional tension joints to the supporting structure are installed on the moving module.

The invention is illustrated in figures 1-4.

Figure 1 presents an embodiment of the technological platform when installed on unstable, for example, in permafrost, marshy, or flood, or sandy surface soils.

Figure 2 is also a top view.

Figure 3 presents an embodiment of a technological platform at sea at great depths.

Figure 4 is a top view along aa in figure 3.

In any of the embodiments of the method (Figs. 1-4), the technological platform comprises a base plate 1 with a central recess. Wells 2 with wellhead connectors 3 are located inside the central recess of the base plate 1, and the supporting structure 4 of the processing equipment is located on the upper surface. The base plate 1 is made in the form of rigidly connected central 5 and peripheral 6 parts, which are connected with solid soil using central 7 and peripheral 8 cemented piles with the corresponding main tension joints 9. The supporting structure 4 of the technological equipment is made in the form of a single truss (figure 1 ) or truss, composed of several modules 10 (Fig.3), which is attached to the base plate 1 using additional tension connections 11.

The Central part 5 of the base plate 1 can be made in the form of any closed geometric shape - a circle, oval or polygon. In one of the cases under consideration, the central part 5 of the base plate 1 is made in the form of a square (figure 1), in another - in the form of a hexagon (figure 3).

The peripheral parts 6 of the base plate 1 are made using beams 12, rigidly interconnected and the Central part 6 of the base plate 1 with the formation of a star-shaped structure. At the tops of the star-shaped structure are the installation sites of peripheral cemented piles 8 and fastening means 13 of additional tension joints 11 of the supporting structure 4. The supporting structure 4 is made in the form of a single truss (Fig. 1) or a truss composed of several modules 10 (Fig. 3), on which also means of fastening 13 additional tension connections 11 are installed.

When installing the technological platform on unstable, surface soils (Figs. 1, 2) in the central recess of the base plate 1 until stable rocks are reached, the supporting structure comprises a shaft 14 with directions 15 for wells 2. Unstable rocks are previously removed from the shaft 14 and filled with low thermal conductivity 16. The lower surface of the base plate 1 is located at a height that ensures the passage of flood water or the unhindered movement of sandy soil.

When installing a technological platform in the sea at great depths, the supporting structure 4 of the technological equipment is made of a fixed 17, a moving 18 and a removable 19 modules. The movable module 18 can be moved relative to the fixed module 17 along the roller guides 20 using the ballast tank 21. Means of fastening 13 additional tension connections 11 of the supporting structure 4 are mounted on the movable module 18.

At the average depths of the installation of the technological platform in the sea, the mobile module 18 may be absent. This provides for the installation of means for attaching additional connections 13 to the fixed module 17 (not shown).

The invention is implemented as follows.

In one embodiment of the method, a base plate 1 with a central recess is installed on the surface soil, inside which wells 2 with wellhead connectors 3 are placed, a supporting structure 4 of the processing equipment is installed on the base plate 1. The base plate 1 is made in the form of rigidly connected central 5 and peripheral 6 parts, which are connected to the ground using central 7 and peripheral 8 cemented piles with the corresponding main tension joints 9, while the supporting structure 4 of the technological equipment is made in the form of a single truss or truss, composed of several modules 10, and connected to the base plate 1 using additional tension connections 11.

The Central part 5 of the base plate 1 is made in the form of a polygon. The peripheral parts 6 of the base plate 1 are formed using beams 12, which are rigidly connected to each other and the central part 6 of the base plate 1 with the formation of a star-shaped structure, at the tops of which are the installation sites of the peripheral cemented piles 8 and fastening means 13 of additional tension joints 11 of the supporting structure 4 made in the form of a single truss (Fig. 1, 2) or truss composed of several modules 10 (Fig. 3, 4), on which fastening means 13 of additional tension joints 11 are also installed.

When installing the technological platform on unstable, for example, in permafrost, marshy, or sandy, surface soils (Figs. 1, 2), a shaft 14 with directions 15 for wells 2 is installed in the central recess of the base plate 1 until the stable rocks are reached, from which unstable rocks are removed and filled with a material with low thermal conductivity 16, while the lower surface of the base plate 1 is positioned at a height that allows the passage of flood water or unhindered movement of sandy soil.

When installing the technological platform in the sea at great depths, the supporting structure 4 of the technological equipment is made of a fixed 17, movable 18 and removable 19 modules, and the mounting means 13 of the additional tension joints 11 of the supporting structure 4 are mounted on the movable module 18.

The implementation of this invention allows to increase the reliability of the construction of technological platforms under a wide range of external conditions and characteristics of surface soils, flood soils at river mouths, swampy soils in mid-latitudes or in permafrost, on sandy loose soils with a variable surface topography, as well as with a wide depth range for the construction of offshore technological platforms in marine conditions.

Information sources

1. RF patent No. 2232227, class. ЕВВ 17/00, 2003.

2. RF patent No. 2140516, cl. EB21 7/12, 1999.

Claims (4)

1. A method of constructing a technological platform, in which a base plate (1) with a central recess is installed on surface soil, inside which wells (2) with wellhead connectors (3) are placed, a supporting structure (4) of technological equipment is installed on the base plate (1) characterized in that the base plate (1) is made in the form of rigidly connected central (5) and peripheral (6) parts, which are connected to the ground using central (7) and peripheral (8) cemented piles with the main tension joints (9) , at The supporting structure (4) of the technological equipment is made in the form of a single truss or truss composed of several modules (10) and connected to the base plate (1) using additional tension joints (11). 2. The method according to claim 1, characterized in that the Central part (5) of the base plate (1) is made in the form of a polygon, the peripheral parts (6) of the base plate (1) are formed using beams (12), which are rigidly connected to each other and with the Central part (6) of the base plate (1) with the formation of a star-shaped structure, at the tops of which are the places for installing peripheral cemented piles (8) and fastening means (13) of additional tension joints (11) of the supporting structure (4), made in the form a single farm or a farm composed of several modules (10), on which the fastening means (13) of additional tension joints (11) are also mounted. 3. The method according to claim 2, characterized in that when installing the technological platform on unstable, for example, in permafrost, marshy or sandy surface soils in the central recess of the base plate (1), before reaching stable rocks, a shaft (14) is installed with directions (15) for wells (2), from which unstable rocks are removed and filled with a material with low thermal conductivity (16), while the lower surface of the base plate (1) is located at a height that allows the passage of flood waters or unhindered movement sandy soil. 4. The method according to claim 2, characterized in that when installing the technological platform in the sea at great depths, the supporting structure (4) of the technological equipment is made of a fixed (17), movable (18) and removable (19) modules, and the fastening means ( 13) additional tension joints (11) of the supporting structure (4) are mounted on the movable module (18).

Images