RU2446249C2 - Ice-resistant support block of marine engineering facility - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: ice-resistant support block of a marine engineering facility comprises a cylindrical shaft, a support unit and supporting braces. The shaft is made as hollow. The shaft is hingedly connected to supporting braces. The support unit comprises a support ring. The support ring is formed by at least three rectilinear pontoons. Pontoons are rigidly connected by their ends. The support ring is rigidly fixed to the cylindrical shaft by hollow radial spacers. Supporting braces are rigidly connected to the support ring by lower ends. Pontoons of the support ring, radial spacers, a cylindrical shaft and hollow supporting braces are made as capable of their floatability adjustment from positive to negative one.

EFFECT: invention provides for the possibility of serial construction, reduced labour intensiveness of installing a support block on site and its removal from soil, high repairability and capability of re-equipment in the dock.

8 cl, 6 dwg

Description

The invention relates to offshore engineering structures (offshore platforms) and can be used as artificial grounds for placing oil and gas drilling equipment in solving problems of developing shelf resources.

Known support block of the marine hydraulic structures, made in the form of an end-to-end spatial spatial structure of steel rolling profiles, containing a prefabricated trunk resting on its lower end on the seabed, supporting struts, articulated to the middle part of the trunk (see US No. 46669917, class E 02B 17 / 00, 1987). In this case, the platform is rigidly connected to the upper end of the barrel.

The disadvantages of this support block of the offshore hydraulic structure of the offshore platform include the great complexity of its design due to the presence of a large number of nodes and elements of its spatial structure. In addition, the named design features of the technical solution do not allow to provide ice resistance of the structure.

An ice-resistant support block of an offshore engineering structure is also known, comprising a hollow cylindrical barrel, the lower end of which is equipped with a support assembly, and hollow supporting struts pivotally connected to the barrel (see RU No. 2074926, IPC ЕВВ 17/00, 1992).

The disadvantages of this technical solution include the dependence of the quality of the “supporting effect” of each of the supporting struts on the quality of their contact with the corresponding section of the bottom and the strength parameters of the bottom layer into which the lower end of the supporting strut is fixed, while the structural elements of the support block “work” disconnected from each other from a friend, all this together does not provide sufficient structural rigidity, which does not ensure its trouble-free operation under the influence of an ice field. In addition, the installation of the claimed design is quite complicated and requires the use of powerful floating cranes.

The task to which the proposed technical solution is directed is to increase the rigidity of the structure and simplify its installation.

The technical result is that high structural rigidity is ensured by ensuring the compatibility of all its elements with the formation of a spatial structure from interconnected elements with the formation of rigidly triangular frames by them and its installation is simplified. In addition, a reduction in installation costs is provided; the possibility of serial construction; reduction of complexity when setting the support block in place, as well as when removing from the ground; high maintainability and the possibility of conversion in the dock.

The problem is solved in that the ice-resistant support block of an offshore engineering structure comprising a hollow cylindrical barrel, the lower end of which is provided with a support assembly, and hollow support braces pivotally connected to the barrel, is characterized in that the support assembly comprises a support ring formed by at least three rigidly rectilinear pontoons connected by their ends, which are given the shape of an isosceles trapezoid in plan, while the support ring is rigidly fastened to the walls of the cylindrical trunk hollow radial spacers, while the lower ends of the support braces are rigidly connected to the support ring, and the longitudinal axis of the support braces and radial struts lie in the same vertical plane, while the pontoons of the support ring, radial struts, a cylindrical barrel and hollow support braces are made with the possibility of regulating their buoyancy from positive to negative. In addition, the ends of the supporting braces facing the vertical trunk and the support ring are given a shape that repeats the surface of the sections of the structural elements in contact with them. In addition, the swivel of the supporting braces with a cylindrical barrel is made detachable. In addition, the hinges are placed on a reinforcing ring belt mounted on the wall of the cylindrical shaft at a depth exceeding the average thickness of the ice fields at the installation site of the support block. In addition, the lower ends of the braces are fixed to the wall of the support ring by welding. In addition, the edges of the ends of the supporting braces facing the vertical trunk are rigidly connected to the surface facing them, for example, by electric welding. In addition, additional longitudinal ballast compartments are placed in the cavities of the supporting braces, the cavities of which are symmetrical with respect to the shortest forming shell of the brace body. In addition, the vertical barrel is equipped with a through longitudinal technological cavity isolated from the rest of its volume.

A comparison of the features of the claimed solution with the features of analogues and prototype indicates its compliance with the criterion of "novelty."

The features of the characterizing part of the claims solve the following functional tasks:

The signs "... the support unit contains a support ring formed by at least three rectilinear pontoons rigidly connected to their ends ..." provide the perception of the load transmitted (or perceived) by the hollow support braces, while ensuring the stability of the working conditions of all braces and the possibility of joint operation of nodes and elements reference block.

Signs indicating that the straight-line pontoons are “shaped like an isosceles trapezoid” provide the possibility of “areal” conjugation of the ends of straight-line pontoons and thereby ensure the strength of the support ring.

The signs "... the support ring is rigidly bonded to the walls of the cylindrical barrel with hollow radial struts ..." provide a rigid connection between the base of the support block and the support ring and, taking into account the signs "the longitudinal axes of the supporting braces and radial struts lie in one vertical plane" provide the formation of "triangular trusses" perceiving loads (redistributing them to the support ring) arising from the action of ice fields on the vertical trunk of the support block.

The signs "... the lower ends of the supporting braces are rigidly connected to the support ring ..." provide an increase in the overall rigidity of the structure.

The signs "... pontoons of the support ring, radial struts, a cylindrical trunk and hollow support braces are made with the possibility of regulating their buoyancy from positive to negative ..." provide the possibility of transporting the elements of the support block by towing, and their installation using ballasting - adjustable reception (or pumping) of water ballast.

The signs of the second claim provide a snug fit to each other of the abutting surfaces of the elements of the support block and, accordingly, the alignment and reduction of stress levels at the contacts of the braces.

The characteristics of the third paragraph of the claims provide, if necessary (for example, in case of damage or the need for modernization) the ability to dismantle the support braces by disassembling the hinges (of course, after releasing the edges connected by welding).

The features of the fourth claim provide the possibility of minimizing the thickness of the remaining part of the wall of the cylindrical barrel (and its damage by welding or sharp during the formation or destruction) of the joints at the corresponding edges of the ends of the supporting struts and exclude the impact of ice fields on this site.

The features of the fifth claim specify the possible form of a rigid connection between the brace and the support ring.

The signs of the sixth claim provide the rigidity of the connection of the supporting braces with a cylindrical barrel, which provides an increase in the overall rigidity of the structure.

The features of the seventh claim provide the possibility of such differentiation of the braces during the installation process, in which they are oriented upwards by the "long" generatrix, which simplifies the assembly of the structure (assembly of the swivel joint of the brace and the vertical trunk).

The features of the eighth claim provide the possibility of free passage of the drilling tool through the vertical shaft.

The invention is illustrated by drawings, in which Fig. 1 shows a side view of an ice-resistant support block of an offshore engineering structure, Fig. 2 is a view of a support assembly, Fig. 3 shows mounting units in a dock, Fig. 4 shows mounting units in a water area with sufficient depth for their docking, figure 5 shows the installation process of assembly units afloat, figure 6 shows the ice-resistant support block of a marine engineering structure after docking afloat.

The drawings show: a hollow cylindrical barrel 1, a support assembly 2, supporting braces 3, a support ring 4, pontoons 5, struts 6, ballast compartments 7, hinges 8, an annular belt 9. The lugs 10 and 11 are also shown in the drawings.

The ice-resistant support block of the marine engineering structure (Fig. 1) contains a hollow cylindrical barrel 1, the lower end of which is equipped with a support node 2, and hollow supporting braces 3, articulated with the barrel 1. The vertical barrel 1 is provided with a through longitudinal process cavity isolated from the rest volume. The support node 2 (Fig. 2) contains a support ring 4 formed by at least three rectilinear pontoons 5 that are rigidly connected with their ends and are shaped like an isosceles trapezoid, while the support ring 4 is rigidly fastened to the walls of the cylindrical barrel 1 by hollow radial struts 6. Components of the support unit (pontoons 5, struts 6) and supporting braces 3 - tubular elements of rectangular, round or other cross section. The lower ends of the support braces 3 are fixed to the wall of the support ring 4, for example, by welding. The edges of the ends of the supporting braces 3, facing the vertical barrel 1, are rigidly connected to the surface facing them, for example, by electric welding. The ends of the supporting braces 3, facing the vertical barrel 1 and the support ring 4, are given a shape that repeats the surface of the sections of the structural elements in contact with them. Moreover, the longitudinal axis of the supporting braces 3 and the radial struts 6 lie in one vertical plane. In the cavities of the supporting braces 3, additional longitudinal ballast compartments 7 are placed, the cavities of which are symmetrical with respect to the shortest forming shell of the brace body 3. The pontoons 5 of the support ring 4, the radial struts 6, the cylindrical barrel 1 and the hollow supporting braces 3 are made with the possibility of regulating their buoyancy from positive to negative. In the manufacture of the vertical barrel using the technologies used in the construction of hulls of submarines. The remaining structural elements are simpler, and the technology for their manufacture is not particularly difficult. Swivel support braces 3 with a cylindrical barrel 1 made detachable. The hinges 8 are placed on a reinforcing ring belt 9, mounted on the wall of the cylindrical barrel 1 at a depth exceeding the average thickness of the ice fields at the installation site of the support ring 4. A reinforcing ring belt 9 with eyes 10, fixed on the outer surface of the vertical barrel.

The manufacture and installation of an ice-resistant support block of an offshore engineering structure is as follows.

The construction of installation units is carried out in the dock by known methods (figure 3). The first mounting unit includes a vertical barrel 1 and a support node 2. The support node 2 is made in the form of a closed polyhedral ring 4, the faces of which are composed of separate pontoons 5, the ends of which are rigidly fastened to each other, while the support ring 4 is rigidly fastened to the vertical barrel 1 radial struts 6, made in the form of individual pontoons. As the rest of the mounting units, the supporting braces 3 are used. One end of each of the braces 3 is provided with lugs 11 that are capable of articulating with the lugs 10 of the vertical barrel 1, and the other end is made to fit snugly to the corresponding section of the support ring 4.

After the construction of the components of the support block, the dock is filled with water, they float up due to their own support forces, and they are brought to the water area with sufficient depth for docking (Fig. 4). During the installation process, the first mounting unit is heated down to give the longitudinal axis of the vertical trunk a vertical position and its eyes 10 are brought out to a level above the sea surface, which makes it possible to swivel with the eyes 11 of the supporting braces 3 (Fig. 5). The supporting braces 3 are ballasted before installation, giving them a spatial position that makes it possible to swivel their eyes 10 with the eyes 11 of the vertical barrel 1, ensuring that the braces are afloat when they are turned upward by a long generatrix (in this position, the brace eyes protrude above the water surface).

Then (Fig. 5), by ballasting the pontoons 5, immersion is performed, then the joints in the swivel joints 8 of the cylindrical barrel 1 and the braces 3 are joined. After performing the swiveling of the braces 3 with the vertical barrel 1, the ballast is pumped out of the pontoons 5 of the support ring 4 and / or radial struts 6 and / or vertical barrel 1, ensuring the approach of the free ends of the braces 3 with the surface portion of the support ring 4 facing them, and provide contact (preload) of the corresponding ends of the braces 3 with the support ring 4 due to float the first mounting unit. Under the action of gravity, the braces 3 rotate in hinges 8 and lower to regular places (Fig.6). The speed and volume of the received and pumped ballast must be calculated so that the braces 3 descended on the support ring 4 smoothly. After the sub-float of the support block 2 and the drying of the sections of the support ring 4 fastened to the braces 3, the braces are rigidly fixed with the structural elements in contact with them, for example, by welding, ensuring the rigidity of the entire structure of the support block.

After rigid fixation of the braces 3 with the structural elements in contact with them, the pontoons 5 of the assembly thus assembled are ballasted, ensuring its transportation and lowering to the prepared bottom section.

Pontoons 5 and braces 3 are used both for buoyancy and ballasting during towing and as ballast or cargo compartments in operation. The support block is installed on the ground with its support node 2. After the assembly of the support block is completed, a platform is installed on it (in a known manner) for technological equipment. If necessary, the support block by flooding the ballast pops up and is towed for repair or to another place of operation. The proposed design provides in comparison with reinforced concrete structures cost reduction; the possibility of serial construction; reducing the complexity when installing the support block in the field, as well as when removing from the ground; high maintainability and the possibility of conversion in the dock.

Claims (8)

1. An ice-resistant support block of an offshore engineering structure, comprising a hollow cylindrical barrel, the lower end of which is provided with a support assembly, and hollow support braces pivotally connected to the barrel, characterized in that the support assembly comprises a support ring formed by at least three rectilinear rigidly connected to their ends pontoons, which in the plan are given the shape of an isosceles trapezoid, while the support ring is rigidly fastened to the walls of the cylindrical trunk by hollow radial struts, while the lower the ends of the support braces are rigidly connected to the support ring, and the longitudinal axis of the support braces and radial struts lie in the same vertical plane, while the pontoons of the support ring, radial struts, a cylindrical barrel and hollow support braces are made with the possibility of regulating their buoyancy from positive to negative. 2. The ice-resistant support block according to claim 1, characterized in that the ends of the supporting braces facing the vertical shaft and the support ring are given a shape that repeats the surface of the sections of the structural elements in contact with them. 3. The ice-resistant support block according to claim 1, characterized in that the articulated joints of the supporting braces with the cylindrical barrel are made detachable. 4. The ice-resistant support block according to claim 1, characterized in that the hinges are placed on a reinforcing ring belt mounted on the wall of the cylindrical shaft at a depth exceeding the average thickness of the ice fields at the installation site of the support block. 5. The ice-resistant support block according to claim 1, characterized in that the lower ends of the braces are fixed to the wall of the support ring by welding. 6. The ice-resistant support block according to claim 1, characterized in that the edges of the ends of the supporting braces facing the vertical shaft are rigidly connected to the surface facing them, for example, by electric welding. 7. The ice-resistant support block according to claim 1, characterized in that additional longitudinal ballast compartments are placed in the cavities of the supporting braces, the cavities of which are symmetrical with respect to the shortest forming shell of the brace body. 8. The ice-resistant support block according to claim 1, characterized in that the vertical shaft is provided with a through longitudinal process cavity isolated from the rest of its volume.

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