KR20230175303A - Assembled platform for offshore wind power generation monopile rock reclamation foundation construction - Google Patents

Abstract

The present invention discloses a prefabricated platform for offshore wind power generation monopile rock reclamation foundation construction, which includes an anti-sink sub-platform and an upper sub-platform connected to the upper side of the anti-sink sub-platform through a plurality of support modules, wherein the anti-sink sub-platform is The sub-platform includes a plurality of first column connection modules and a plurality of anti-sink plate modules that are connected horizontally, and each of the first column connection modules includes a first anti-sink plate, a first column, and a first main beam. Contains; Each of the anti-sink plate modules includes a second anti-sink plate and a second main beam; The upper sub-platform includes a plurality of horizontally connected second pillar connection modules and a plurality of structural modules, each second pillar connection module comprising a cubic connection framework, a connection panel and a second pillar, Each of the structural modules includes a cubic structural framework and structural panels. The present invention effectively solves the problem of low reusability of platforms for monopile foundation construction and large amount of reinforcement and modification work.

Description

Assembled platform for offshore wind power generation monopile rock reclamation foundation construction

The present invention relates to an assembled platform for offshore wind power generation monopile rock reclamation foundation construction.

The wind power industry in particular has been booming as offshore projects have increased in recent years. Offshore wind power foundation types commonly found at home and abroad include monopile foundations, conduit frame foundations, high-pile bearing platform foundations, gravity foundations, and floating foundations, where monopile foundations are both technically and economically feasible. Due to its advantages, it is widely used in offshore wind power plants at home and abroad. Ultra-large steel pipe piles are the foundation of monopile wind turbines, and their pile settlement verticality directly affects the horizontality of the foundation ring, further affecting the stability of the wind turbine tower structure, and is currently used to control the settlement of ultra-diameter monopiles. It mainly uses the file stabilization platform method.

Currently, the monopile foundation stabilization platform is designed and manufactured by combining the monopile foundation type and construction conditions during design to design and manufacture a special conduit frame pile stabilization platform, while comprehensively considering rockfill excavation equipment and auxiliary equipment during rock reclamation work. Currently, the rock reclamation pile stabilization platform has a low reusability rate and a large amount of reinforcement and modification work.

Therefore, there is an urgent need to develop a prefabricated construction platform suitable for monopile rock reclamation foundation stabilization work to maximize the utilization rate of the current platform and reduce construction costs.

The purpose of the present invention is to provide a prefabricated platform for offshore wind power monopile rock reclamation foundation construction to overcome the shortcomings of the prior art, thereby ensuring standardization of modules and interfaces through modular construction design through the platform and increasing the utilization rate of the platform. The goal is to maximize construction costs and reduce construction costs.

The assembled platform for offshore wind power generation monopile rock reclamation foundation construction of the present invention,

It includes an upper sub-platform connected to the upper side of the anti-sink sub-platform through an anti-sink sub-platform and a plurality of support modules,

The anti-sink sub-platform includes a plurality of first pillar connection modules and a plurality of anti-sink plate modules that are horizontally aligned,

Each of the first column connection modules is installed at equal intervals between a first anti-sink plate, a first column that vertically penetrates the center position of the first anti-sink plate and is fixedly connected thereto, and the first anti-sink plate. and includes a plurality of first main beams, one end of which is connected to the outer peripheral surface of the first pillar;

Each of the anti-sink plate modules includes a second anti-sink plate and a second main beam fitted to the second anti-sink plate;

The upper sub-platform includes a plurality of second pillar connection modules and a plurality of structural modules that are horizontally aligned,

Each of the second pillar connection modules includes a cubic connection framework, a connection panel mounted on an upper part of the cube connection framework, and a second pillar vertically penetrating the center position of the connection panel and fixedly connected thereto, The lower end of the second pillar is connected to the first pillar through the support module;

Each of the structural modules includes a cubic structural framework and structural panels mounted on top of the cubic structural framework.

In the prefabricated platform for the offshore wind power monopile rock embedding foundation construction, each of the support modules includes two third pillar connection sub-modules that are vertically connected and a second pillar connection sub-module located between the two third pillar connection sub-modules. Includes 4 pillars.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, each of the third pillar connection sub-modules includes a third pillar and a plurality of pillar flanges mounted at equal intervals on the outer peripheral surface of the third pillar.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, a lower end of one third pillar connection sub-module in each of the support modules is connected to the first pillar connection module using a flange connection method, The other upper end of the third pillar connection sub-module is connected to the second pillar connection module using a flange connection method, and the fourth pillar is connected to the third pillar connection module using a flange connection method.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, a plurality of anti-sink plate reinforcement ribs arranged in a cross shape are installed on the bottom surfaces of each of the first anti-sink plate and the second anti-sink plate.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, each first column connection module includes four first main beams, and the other end of each first main beam is subject to the first settlement. It is aligned with the edge of the prevention plate; Both ends of each of the second main beams are aligned with two opposing edges of the second anti-sink plate where they are located.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, the second main beam of each anti-sink plate module is connected to the first main beam using a flange connection method, or another anti-sink plate It is connected to the second main beam of the module.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, each of the cubic connection frameworks is constructed with four first support columns and eight first transverse beams, and two said first support columns are located in the same vertical plane. 1 A first reinforcing brace is vertically connected between each horizontal beam.

In the prefabricated platform for offshore wind power monopile rock reclamation foundation construction, one part of the plurality of structural modules is a first structural module and another part is a second structural module,

The cubic structural framework of each said first structural module is built with four second support columns and eight second transverse beams, with two intersecting second transverse beams every two second transverse beams located in the same vertical plane. The reinforcing braces are connected at an angle;

The cubic structural framework of each second structural module is built with four third support columns and eight third transverse beams, and the size of the structural panel of the second structural module is equal to that of the structural panel of the first structural module. Smaller than size.

In the prefabricated platform for offshore wind power monopile rock embedding foundation construction, each of the cubic connection frameworks is connected to the cubic structural framework using the method of flange connection.

Based on the above-described technical solution, the present invention forms an upper sub-platform, anti-sinking sub-platform, and support module through connection between each module and sub-module, and then connects the upper sub-platform, anti-sinking sub-platform, and support module. By forming an integrated assembly platform through connection, it effectively solves the problem of the monopile foundation construction platform among the prior technologies having a low reusability rate due to the inability to disassemble and assemble and a large amount of reinforcement and modification work, and also the stability of the present invention is relatively high. It is tall and easy to attach and detach, so it can be used repeatedly. In addition, the present invention also has advantages such as easy installation and low cost.

Figure 1 is a three-dimensional structural schematic diagram of a prefabricated platform for offshore wind power monopile rock reclamation foundation construction of the present invention.
Figure 2 is a structural plan view of the anti-sink sub-platform of the present invention.
Figure 3 is a structural perspective view of the first pillar connection module of the anti-sink sub-platform of the present invention.
Figure 4 is a structural side view of the first pillar connection module of the anti-sink sub-platform of the present invention.
Figure 5 is a structural perspective view of the anti-sink plate module of the anti-sink sub-platform of the present invention.
Figure 6 is a structural bottom view of the anti-sink plate module of the anti-sink sub-platform of the present invention.
Figure 7 is a structural plan view of the upper sub-platform of the present invention.
Figure 8 is a structural perspective view of the second pillar connection module of the upper sub-platform of the present invention.
Figure 9 is a structural side view of the second pillar connection module of the upper sub-platform of the present invention.
Figure 10 is a structural perspective view of the first structural module of the upper sub-platform of the present invention.
Figure 11 is a structural side view of the first structural module of the upper sub-platform of the present invention.
Figure 12 is a structural perspective view of the second structural module of the upper sub-platform of the present invention.
Figure 13 is a structural side view of the second structural module of the upper sub-platform of the present invention.
Figure 14 is a structural perspective view of the third pillar connection sub-module of the support module of the present invention.
Figure 15 is a structural side view of the third pillar connection sub-module of the support module of the present invention.
Figure 16 is a structural perspective view of the fourth pillar of the support module of the present invention.

The present invention will be described in more detail below with reference to the drawings.

Referring to Figure 1, the present invention, that is, the prefabricated platform for offshore wind power generation monopile rock reclamation foundation construction, is connected to the upper side of the anti-sink sub-platform (1) through an anti-sink sub-platform (1) and a plurality of support modules (2). It includes an upper sub-platform (3).

As shown in FIG. 2, the anti-sink sub-platform 1 includes a plurality of first pillar connection modules 11 and a plurality of anti-sink plate modules 12 that are horizontally aligned.

As shown in Figures 3 and 4, each first pillar connection module 11 is fixedly connected to the first anti-sink plate 111 and vertically penetrates the center position of the first anti-sink plate 111. It includes a first pillar 112 and a plurality of first main beams 113 that are installed at equal intervals and are connected to the first anti-sink plate 111, and one end of which is connected to the outer peripheral surface of the first pillar 112, A plurality of anti-sink plate reinforcement ribs 13 arranged in a cross shape are installed on the bottom surface of the first anti-sink plate 111. In this embodiment, the first pillar 112 has a hollow structure and a pillar connection flange 100 is installed at the top thereof, and each first pillar connection module 11 includes four first main beams 113. It includes and the other end of each first main beam 113 is aligned with the edge of the first anti-sink plate 111; The thickness of the anti-sink plate reinforcement rib 13 on the bottom surface of the first anti-sink plate 111 does not exceed the radius of the first main beam 113; Each first pillar connection module 11 has an all-steel structure and is formed through integrated welding and precision processing.

As shown in FIGS. 5 and 6, each anti-sink plate module 12 includes a second anti-sink plate 121 and a second main beam 122 installed between the second anti-sink plates 121. Including, a plurality of anti-sink plate reinforcement ribs 13 arranged in a cross shape are installed on the bottom surface of the second anti-sink plate 121. In this embodiment, both ends of each second main beam 122 are aligned with two opposing edges of the second anti-sink plate 121 where each tooth is located; The thickness of the anti-sink plate reinforcement rib 13 on the bottom surface of the second anti-sink plate 121 does not exceed the radius of the second main beam 122; Each anti-sink plate module 12 has an all-steel structure and is formed through integrated welding and precision processing.

In this embodiment, in each anti-sink plate module 12, one second main beam 122 is connected to the first main beam 113 using a flange connection method, or another anti-sink plate module ( It is connected to the second main beam 122 of 12), and specifically, connection flanges 200 are installed at both ends of the other end of the first main beam 113 and the second main beam 122, respectively.

When constructing a monopile rock reclamation foundation, the anti-sinking sub-platform (1) provides temporary vertical support by the ground bearing capacity of the seafloor mud surface and provides a certain degree of rigidity to the entire construction platform.

As shown in FIG. 7, the upper sub-platform 3 includes a plurality of second pillar connection modules 31 and a plurality of structural modules that are connected horizontally, and one part of the plurality of structural modules is the first structural module. (32) and the other part is the second structural module (33).

As shown in Figures 8 and 9, each second pillar connection module 31 includes a cubic connection framework 311, a connection panel 312 mounted on the top of the cubic connection framework 311, and a connection panel It includes a second pillar 313 that vertically penetrates the center position of 312 and is fixedly connected thereto, and the lower end of the second pillar 313 is connected to the first pillar 112 through the support module 2. . In this embodiment, each cubic connection framework 311 is built with four first support columns 3111 and eight first transverse beams 3112, and two first transverse beams located in the same vertical plane ( 3112), a first reinforcing brace 3113 is vertically connected to reinforce the load carrying capacity of the second pillar connection module 31 itself; The surface layer of the connection panel 312 is a steel plate, which is connected to the first transverse beam 3112 on the top surface of the cubic connection framework 311 through H-beams; The second pillar 313 has a hollow structure and pillar connection flanges 100 are installed at the top and bottom, respectively; Each second pillar connection module 31 has an all-steel structure and is formed through integrated welding and precision processing;

Each of the first structural module 32 and the second structural module 33 both comprise a cubic structural framework and structural panels mounted on top of the cubic structural framework, specifically:

10 and 11, in this embodiment, the cubic structural framework 321 of the first structural module 32 includes four second support columns 3211 and eight second transverse beams 3212. ), and two intersecting second reinforcing braces 3213 for reinforcing the load carrying capacity of the first structural module 32 itself are inclined between the two second transverse beams 3212 located in the same vertical plane. connected; In the first structural module 32, the surface layer of the structural panel 322 is a steel plate, which is connected to the second transverse beam 3212 on the top surface of the cubic structural framework 331 through H-beams; Each first structural module 32 has an all-steel structure and is formed through integral welding and precision machining.

12 and 13, in this embodiment, the cubic structural framework 331 of the second structural module 33 includes four third support columns 3311 and eight third transverse beams 3312. ) is constructed with; In the second structural module 33, the surface layer of the structural panel 332 is a steel plate, which is connected to the third transverse beam 3312 on the upper surface of the cubic structural framework 331 through H-beams, and the second structural module 33 ) is smaller than the size of the structural panel 322 of the first structural module 32; Each second structural module 33 has an all-steel structure and is formed through integral welding and precision processing.

In this embodiment, the cubic structural framework 321 of each first structural module 32 and the cubic structural framework 331 of the second structural module 33 use a flange connection method to form a cubic connection framework ( 311); Specifically, connection flanges 200 are installed at both ends of each first support pillar 3111 and each first horizontal beam 3112, and each second support pillar 3211 and each second Connection flanges 200 are installed on both ends of the horizontal beams 3212, and connection flanges 200 are installed on both ends of each third support column 3311 and each third horizontal beam 3312. do.

When constructing a monopile rock reclamation foundation, one part of the upper sub-platform (3) can be used for construction and settlement of process piles, and devices such as rock reclamation excavation equipment and auxiliary equipment can be placed on the other part, and the upper sub-platform (3) provides the pushing force of the upper lifting jack for monopile construction, provides a platform for construction personnel and observation equipment to work, and provides a certain degree of rigidity to the entire construction platform.

As shown in FIGS. 14 to 16, each support module 2 is positioned between two vertically connected third pillar connection submodules 21 and two third pillar connection submodules 21. Including the fourth pillar (22),

Each third pillar connection sub-module 21 includes a third pillar 211 and a plurality of pillar flanges 212 mounted at equal intervals on the outer peripheral surface of the third pillar 211.

In this embodiment, each of the third pillars 211 and each of the fourth pillars 22 has a hollow cylindrical structure, and pillar connection flanges 100 are installed at their upper and lower ends, respectively; Each of the third pillar connection submodules 21 and the fourth pillars 22 has a steel structure and is formed through integrated welding and precision processing.

In this embodiment, the lower end of the lower third pillar connection sub-module 21 in each support module 2 is connected to the first pillar connection module 11 using a flange connection method, and each support module ( In 2), the upper end of the third pillar connection sub-module 21 is connected to the second pillar connection module 31 using a flange connection method, and the fourth pillar 22 is connected to the third pillar connection module 31 using a flange connection method. It is connected to the pillar connection sub-module 21. Specifically, the third pillar 211 and the first pillar 112 located at the bottom of each support module 2 are connected through the pillar connection flange 100. , the third pillar 211 and the second pillar 313 located on the upper side are connected through the pillar connection flange 100, and both ends of the fourth pillar 22 are connected to two third pillars through the pillar connection flange 100. Connected to pillar 211; The first to fourth pillars 112 to 22 may be sequentially connected and then an auxiliary file may be inserted therein.

During monopile rock embedding foundation construction, the support module (2) is the main load-bearing structural member of the entire construction platform and supports the vertical load, and is covered and connected to the auxiliary pile and fixed to the auxiliary pile.

The method of using the present invention is as follows.

First, each module and sub-module described above is formed through integrated precision machining.

Next, each module is combined and assembled to form an upper sub-platform, anti-sinking sub-platform and support module, and the upper sub-platform, anti-sinking sub-platform and support module are assembled to form one integrated assembled platform, where , the size of each module or platform can be changed according to different construction environments, usage functions, design requirements, and work requirements, and can be assembled into platforms structured in different shapes.

Then, after the assembly of the entire construction platform is completed, the entire construction platform is transported to the construction site by barge transportation and lifted to the sea surface using lifting equipment.

Finally, after inserting and fixing each auxiliary pile into the first to fourth pillars, process pile sinking construction is performed to sink the piles into the rock surface, and excavation work begins using rock reclamation equipment on the upper sub-platform.

In summary, the present invention forms an upper sub-platform, anti-sinking sub-platform, and support module through connections between each module and sub-module, and then assembles them into a prefabricated platform for rock reclamation foundation construction. Through modularization of the prefabricated platform, the usage rate of the construction platform is maximized and construction costs are reduced, while reducing destruction and pollution of the marine ecological environment, which is in line with the management philosophy of green, environmental protection, and sustainable development advocated by the country.

The above-described embodiments are only for illustrating the present invention, but the present invention is not limited thereto, and those skilled in the art may make various modifications or changes without departing from the spirit and scope of the present invention, so all equivalents Technical solutions fall within the scope of the present invention, and the scope of the present invention should be defined by the claims.

Claims (10)

As a prefabricated platform for offshore wind power monopile rock reclamation foundation construction,
The assembled platform includes an anti-sink sub-platform and an upper sub-platform connected to the upper side of the anti-sink sub-platform through a plurality of support modules,
The anti-sink sub-platform includes a plurality of first pillar connection modules and a plurality of anti-sink plate modules that are horizontally aligned,
Each of the first column connection modules is installed at equal intervals between a first anti-sink plate, a first column that vertically penetrates the center position of the first anti-sink plate and is fixedly connected thereto, and the first anti-sink plate. and includes a plurality of first main beams, one end of which is connected to the outer peripheral surface of the first pillar;
Each of the anti-sink plate modules includes a second anti-sink plate and a second main beam fitted to the second anti-sink plate;
The upper sub-platform includes a plurality of second pillar connection modules and a plurality of structural modules that are horizontally aligned,
Each of the second pillar connection modules includes a cubic connection framework, a connection panel mounted on an upper part of the cube connection framework, and a second pillar vertically penetrating the center position of the connection panel and fixedly connected thereto, The lower end of the second pillar is connected to the first pillar through the support module;
A prefabricated platform for offshore wind power monopile rock reclamation foundation construction, wherein each of the structural modules includes a cubic structural framework and a structural panel mounted on top of the cubic structural framework. According to paragraph 1,
Each of the support modules includes two third pillar connection sub-modules that are vertically connected and a fourth pillar located between the two third pillar connection sub-modules. Offshore wind power generation monopile rock embedding. Prefabricated platform for foundation construction. According to paragraph 2,
Each of the third pillar connection submodules is an assembled platform for offshore wind power generation monopile rock embedding foundation construction, characterized in that it includes a third pillar and a plurality of pillar flanges mounted on the outer peripheral surface of the third pillar at equal intervals. . According to paragraph 2 or 3,
In each of the support modules, the lower end of one of the third pillar connection submodules is connected to the first pillar connection module using a flange connection method, and the upper end of the other third pillar connection submodule is connected to the first pillar connection module using a flange connection method. It is connected to the second pillar connection module using a , and the fourth pillar is connected to the third pillar connection module using a flange connection method. A prefabricated platform for offshore wind power generation monopile rock embedding foundation construction. . According to paragraph 1,
An assembled platform for offshore wind power generation monopile rock reclamation foundation construction, characterized in that a plurality of anti-sink plate reinforcement ribs arranged in a cross shape are installed on the bottom surfaces of each of the first anti-sink plate and the second anti-sink plate. . According to claim 1 or 5,
Each of the first column connection modules includes four first main beams, and the other end of each first main beam is aligned with the edge of the first anti-sink plate; An assembled platform for offshore wind power generation monopile rock embedding foundation construction, characterized in that both ends of each of the second main beams are aligned with two opposing edges of the second anti-sink plate where each tooth is located. According to clause 6,
The second main beam of each anti-sink plate module is connected to the first main beam using a flange connection method, or is connected to the second main beam of another anti-sink plate module. Offshore wind power generation Assembled platform for monopile rock reclamation foundation construction. According to paragraph 1,
Each of the cubic connection frameworks is constructed of four first support columns and eight first transverse beams, and a first reinforcing brace is vertically connected between each of the two first transverse beams located in the same vertical plane. Assembled platform for offshore wind power generation monopile rock reclamation foundation construction. According to paragraph 1,
One portion of the plurality of structural modules is a first structural module and another portion is a second structural module,
The cubic structural framework of each said first structural module is built of four second support columns and eight second transverse beams, with two intersecting second transverse beams every two second transverse beams located in the same vertical plane. The reinforcing braces are connected at an angle;
The cubic structural framework of each second structural module is built with four third support columns and eight third transverse beams, and the size of the structural panel of the second structural module is equal to that of the structural panel of the first structural module. An assembled platform for offshore wind power generation monopile rock reclamation foundation construction, characterized by a smaller size. According to paragraph 1,
A prefabricated platform for offshore wind power monopile rock reclamation foundation construction, characterized in that each of the cubic connection frameworks is connected to the cubic structural framework using a flange connection method.

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