CN217428028U - Offshore wind turbine assembly and wind turbine photovoltaic composite foundation platform thereof - Google Patents

Abstract

The utility model discloses an offshore wind turbine assembly and compound basic platform of fan photovoltaic thereof, include: the buoyancy column can float on the sea surface and is used for installing the fan main body; the photovoltaic panel can overturn relative to the buoyancy column, so that the photovoltaic panel is buckled and unfolded. In order to protect the photovoltaic board, consequently, when the photovoltaic board was installed on the buoyancy post, set up to this photovoltaic board and can overturn for the buoyancy post to make the photovoltaic board can lock and expand. When the photovoltaic panel is used, when the photovoltaic panel needs to be protected, the photovoltaic panel is turned over relative to the buoyancy column, so that the photovoltaic panel is buckled, and the front side of the photovoltaic panel is protected; when the photovoltaic panel needs to be adjusted to work, the photovoltaic panel is unfolded to absorb solar energy. It should be noted that, in the process of turning the photovoltaic panel, the angle of the photovoltaic panel can be changed, so that the photovoltaic panel can adapt to illumination in different directions, and the utilization rate of light energy is effectively improved.

Description

Offshore wind turbine assembly and wind turbine photovoltaic composite foundation platform thereof

Technical Field

The utility model relates to an offshore wind turbine technical field, in particular to offshore wind turbine assembly and compound foundation platform of fan photovoltaic thereof.

Background

At present, offshore wind power gradually steps into a deep sea area, and in order to realize the installation of the offshore wind power, a floating type platform is usually adopted in the deep sea area at present.

Because the floating platform mainly comprises a mooring system, a floating member and the like, the cost is huge, the energy utilization rate is low by simply adopting wind power generation, and the income is difficult to realize.

In view of the above, photovoltaic panels are generally disposed on the floating member to realize simultaneous collection of solar energy and wind turbine, thereby improving the utilization rate of energy and correspondingly improving the utilization rate of the floating member.

However, the continuous change of the direction of illumination can influence the collection effect of the photovoltaic panel, and in addition, when extreme weather such as rain, snow, hail and the like is met, the photovoltaic panel can be damaged, and the normal use of the photovoltaic panel is influenced.

Therefore, how to protect the photovoltaic panel to ensure the service life of the photovoltaic panel is a problem to be urgently solved by the person skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a compound foundation platform of fan photovoltaic protects the photovoltaic board to guarantee the life of photovoltaic board. Furthermore, the utility model also provides an offshore wind turbine assembly who has above-mentioned compound foundation platform of fan photovoltaic.

In order to achieve the above purpose, the utility model provides a following technical scheme:

a wind turbine photovoltaic composite foundation platform, comprising:

the buoyancy column can float on the sea surface and is used for installing the fan main body;

the photovoltaic board, the photovoltaic board can for the buoyancy post upset makes photovoltaic board lock and expansion.

Preferably, in the wind turbine and photovoltaic composite foundation platform, the photovoltaic panels are uniformly arranged along the circumferential direction of the buoyancy column, the photovoltaic panels are spliced into a conical outer profile after being buckled relative to the buoyancy column, and the photovoltaic panels float on the sea surface after being unfolded relative to the buoyancy column.

Preferably, in the above fan photovoltaic composite foundation platform, the photovoltaic panel is a bent arc-shaped member, a first end of the photovoltaic panel is hinged to the buoyancy column, and a second end of the photovoltaic panel can move close to or away from the buoyancy column.

Preferably, in the above wind turbine and photovoltaic composite foundation platform, a first driving member is further included for driving the photovoltaic panel to rotate relative to the buoyancy column.

Preferably, in the above wind turbine and photovoltaic composite foundation platform, the first driving member includes:

the winch is fixed on the mounting table inside the buoyancy column;

the connecting rope is connected with the free section through the connecting rope, and a through hole for the connecting rope to pass through and a pulley for reversing the connecting rope are arranged on the buoyancy column.

Preferably, in the above wind turbine and photovoltaic composite foundation platform, the photovoltaic panel includes:

the mounting section is connected with the buoyancy column and is a trapezoidal plate with a trapezoidal vertical projection;

the free section, the free section with the installation section rotates to be connected, just the free section can be to being close to or keeping away from the buoyancy post motion, the free section is trapezoidal cambered plate for vertical projection, the free section for when the buoyancy post lock the free section with the laminating of buoyancy post.

Preferably, in the wind turbine and photovoltaic composite foundation platform, the mounting section is welded or hinged to the buoyancy column; when the installation section is hinged with the buoyancy column, the installation section can move towards the direction close to or far away from the buoyancy column.

Preferably, in the above-mentioned wind turbine photovoltaic composite foundation platform, the wind turbine photovoltaic composite foundation platform further includes a second driving member for driving the free section to rotate relative to the mounting section.

Preferably, in the above wind turbine and photovoltaic composite foundation platform, the second driving member includes:

the winch is fixed on the mounting table inside the buoyancy column;

the connecting rope is connected with the free section through the connecting rope, and a through hole for the connecting rope to pass through and a pulley for reversing the connecting rope are arranged on the buoyancy column.

Preferably, among the compound basic platform of foretell fan photovoltaic, still include the weather radar that is used for observing the weather condition, just the weather radar can control the expansion and the lock of photovoltaic board.

An offshore wind turbine assembly comprising a wind turbine photovoltaic composite base platform as claimed in any one of the preceding claims.

The utility model provides a compound foundation platform of fan photovoltaic, in order to protect the photovoltaic board, consequently, when the photovoltaic board is installed on the buoyancy post, set up to this photovoltaic board and can overturn for the buoyancy post to make the photovoltaic board can lock and launch. When the photovoltaic panel is used, when the photovoltaic panel needs to be protected, the photovoltaic panel is turned over relative to the buoyancy column, so that the photovoltaic panel is buckled, and the front side of the photovoltaic panel is protected; when the photovoltaic panel needs to be adjusted to work, the photovoltaic panel is unfolded to absorb solar energy. It should be noted that, in the process of turning the photovoltaic panel, the angle of the photovoltaic panel can be changed, so that the photovoltaic panel can adapt to illumination in different directions, and the utilization rate of light energy is effectively improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a first structural schematic diagram of a wind turbine photovoltaic composite foundation platform disclosed in an embodiment of the present invention;

fig. 2 is a second schematic structural view of the wind turbine photovoltaic composite foundation platform disclosed in the embodiment of the present invention;

fig. 3 is a schematic structural view of the fan photovoltaic composite foundation platform after the photovoltaic panels are fastened;

fig. 4 is a schematic structural view of a photovoltaic panel disclosed in an embodiment of the present invention;

fig. 5 is a top view of a photovoltaic panel disclosed in an embodiment of the present invention;

fig. 6 is a schematic structural view of a photovoltaic panel buckle disclosed in an embodiment of the present invention;

fig. 7 is a top view of a photovoltaic panel buckle disclosed in an embodiment of the present invention;

fig. 8 is a schematic view of the connection between the buoyant columns and the anchor chains disclosed in the embodiment of the present invention;

wherein, 1 is a buoyancy column, 2 is a photovoltaic plate, 4 is a connecting rope, 5 is an installation platform, 6 is a winch, 7 is a fixed pulley, 8 is a through hole, and 9 is an anchor chain;

21 is a free section, and 22 is an installation section;

31 is a first hinge point; and 32 is the second hinge point.

Detailed Description

The utility model discloses a compound foundation platform of fan photovoltaic protects the photovoltaic board to guarantee the life of photovoltaic board. Furthermore, the utility model also discloses an offshore wind turbine assembly of having above-mentioned compound foundation platform of fan photovoltaic.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

In the following, the terms "first", "second" are used for descriptive purposes only and are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature.

As shown in fig. 1-3, the utility model discloses a float compound foundation platform of formula scene, including buoyancy post 1 and photovoltaic board 2, wherein, buoyancy post 1 is the platform main part, and it can float on the sea to as the installation basis. Specifically, for example, the floating offshore wind turbine main body may be installed on the buoyancy column 1, and in addition, the photovoltaic panel 2 is also installed on the buoyancy column 1, that is, in the present application, by additionally installing the photovoltaic panel 2 on the buoyancy column 1, the wind turbine main body and the photovoltaic panel 2 on the buoyancy column 1 can respectively absorb wind energy and solar energy, that is, the utilization rate of energy is improved, so that more electric energy is generated; in addition, the fan main body and the photovoltaic panel 2 are both arranged on the buoyancy column 1, and the utilization rate of the buoyancy column 1 can be improved, so that the number of basic platforms is reduced, and the production cost is reduced; in conclusion, the photovoltaic panel 2 is additionally arranged on the buoyancy column 1 of the offshore wind turbine, so that the benefit can be effectively improved.

In order to protect the photovoltaic panel 2, therefore, when the photovoltaic panel 2 is installed on the buoyancy column 1, the photovoltaic panel 2 is configured to be able to be turned over with respect to the buoyancy column 1, so that the photovoltaic panel 2 can be buckled and unfolded. When the photovoltaic panel 2 is used, when the photovoltaic panel 2 needs to be protected, the photovoltaic panel 2 is turned over relative to the buoyancy column 1, so that the photovoltaic panel 2 is buckled, and the front side of the photovoltaic panel 2 is protected; when the photovoltaic panel 2 needs to be adjusted to work, the photovoltaic panel 2 is unfolded to absorb solar energy. It should be noted that, in the process of turning the photovoltaic panel 2, the angle of the photovoltaic panel 2 can be changed, so that the solar photovoltaic panel can adapt to illumination in different directions, and the utilization rate of light energy can be effectively improved.

Because add photovoltaic board 2 on buoyancy post 1, can increase by the weight of support piece (including photovoltaic board 2 and fan main part), and then influence the draft of buoyancy post 1. Therefore, in order to avoid the buoyancy column 1 from being submerged into the sea to an excessive length, it is necessary to increase the buoyancy of the buoyancy column 1. In view of the above and in combination with the use of the photovoltaic panel 2, the present application is arranged such that the photovoltaic panel 2 will be in contact with the sea surface when deployed, in particular, the photovoltaic panel 2 will float on the sea surface when deployed. The contact area with the sea surface is increased by the photovoltaic panel 2, and the larger the contact area is, the larger the buoyancy is. In addition, the contact area between the buoyancy column 1 and the sea surface is increased, so that the buoyancy column is more stable and is not easy to shake.

As shown in fig. 6 and 7, in the specific embodiment, in order to ensure the stability of the buoyancy column, four photovoltaic panels 2 are arranged along the circumference of the buoyancy column 1 in the present application. It should be noted that, splice when photovoltaic board 2 is the structure that the outline is conical for buoyancy post 1 lock back, the photovoltaic board is the toper, can effectively reduce the effect of ice load to buoyancy post 1, and photovoltaic board 2 at this moment can be regarded as the ice cone. Can resist external wind, frost, rain and snow through with 2 locks of photovoltaic board, and draw in back with photovoltaic board 2 and form conical structure, can further keep out extreme weather such as external hail, further guarantee photovoltaic board 2's safety.

In a specific embodiment, as shown in fig. 1, a first end (inner circle in fig. 1) of the photovoltaic panel 2 in the present application is provided as a first hinge point 31 hinged with the buoyant column 1, and a second end of the photovoltaic panel 2 can move closer to or away from the buoyant column 1. The photovoltaic plate 2 can rotate within a certain angle range relative to the top end of the buoyancy column 1 through the arrangement, namely the included angle between the photovoltaic plate 2 and the buoyancy column 1 is adjusted, and illumination in different directions can be adapted in the overturning process. Specifically, the photovoltaic panel 2 may be hinged in any manner, for example, a hinge may be used, one side of the hinge is fixedly connected to the photovoltaic panel 2 by a thread or a flange, and the other side of the hinge is fixedly connected to the buoyancy column 1. During rotation, the photovoltaic panel 2 rotates relative to the buoyancy column 1 through rotation of the hinge shaft of the hinge.

Preferably, the included angle range between the photovoltaic panel 2 and the floating column 1 can be set according to different requirements, for example, the included angle range can be rotated within a range of 60 degrees to 150 degrees. The rotation process can realize the illumination opposite to different angles, and the absorption rate of solar energy is improved. In addition, the included angle between the photovoltaic panel 2 and the buoyancy column 1 can be within the range of 0-120 degrees, so that the photovoltaic panel 2 can be buckled and unfolded relative to the buoyancy column 1, and the buckling and unfolding of the photovoltaic panel 2 are completed. In combination with the above two ranges, the angle range between the photovoltaic panel 2 and the buoyant column 1 can also be set to be larger to have the above two functions. But it is essential that: in the maximum angle range of photovoltaic board 2 pivoted, when needing to guarantee to transfer photovoltaic board 2, can not lead to photovoltaic board 2 to get into the aquatic because of the accident.

In practice, in order to make the photovoltaic panel 2 form a conical shape after being fastened, the photovoltaic panel 2 itself is required to be an arc-shaped member which is bent, specifically, the bent portion extends along the width direction of the photovoltaic panel 2, referring to the middle transverse line shown in fig. 5.

It should be noted that, in the present application, the photovoltaic panel 2 may also be configured as a flat plate structure capable of being fastened and unfolded, and when fastened, the photovoltaic panel 2 may be completely attached to the buoyant column 1, and may also resist extreme weather. In particular, the structure can be arranged in a connection mode similar to the folding and unfolding of an umbrella, and the mode is also in a protection range.

The rotation range of the hinge between the photovoltaic panel 2 and the buoyancy column 1 is limited, the control and the limit of the rotation angle of the hinge can be driven by a driving piece, and the driving piece can be a cylinder or a motor. Specifically, when being the cylinder, can fix the cylinder block on buoyancy post 1 to with the telescopic link articulated with photovoltaic board 2, realize the regulation to photovoltaic board 2 angles through the flexible process of telescopic link. When the motor is a bidirectional motor and is fixed on the buoyancy column 1, the output rotating shaft drives the hinge to rotate, and the hinge is fixed by stopping the rotation of the output shaft through power failure.

As shown in fig. 1, the driving member of the photovoltaic panel 2 may further be a winch 6, and the photovoltaic panel 2 and the winch 6 are connected by a connecting rope 4, specifically, the winch 6 is installed on an installation platform 5 inside the buoyancy column 1, and the connection rope is reversed and connected by a through hole 8 and a fixed pulley 7 on the surface of the buoyancy column 1.

As shown in fig. 2, fig. 4, fig. 5, and fig. 6, in the present application, the photovoltaic panel 2 may be further configured as a foldable structure, specifically, the foldable structure includes an installation section 22 connected to the buoyancy column 1 and a free section 21 hinged to the installation section 22, where the hinged position of the free section 21 and the installation section 22 forms a second hinge point 32, and the free section 21 is connected to the buoyancy column 1 through a connection rope 4, and the buoyancy column 1 is provided with a winch 6 for winding and unwinding the connection rope 4 to complete the buckling and unfolding of the photovoltaic panel 2. When the photovoltaic panel 2 is opened, the contact area with the sea surface can be further increased, and further the buoyancy is increased; and can make photovoltaic board 2 form the toper after photovoltaic board 2 locks, shelter from the front of photovoltaic board 2, so, when meetting weather sink sunless time or when having ice load or other floaters, can draw in the photovoltaic board, make 2 tops of photovoltaic board agree with buoyancy post 1 to protection photovoltaic board 2 openly suffers rainwater erosion, in addition, photovoltaic board 2 is the toper, can also effectively reduce the effect of ice load to buoyancy post 1, and photovoltaic board 2 at this moment can be seen as the icicle.

When the buoyancy column is installed, the installation section 22 can be welded or hinged with the buoyancy column 1. When hinged, different states of the photovoltaic panel 2 can be added, meeting different requirements. And the hoist engine 6 can be arranged on the mounting table 5 in the buoyancy column 1 to avoid the damage of the hoist engine 6 caused by seawater and illumination and ensure the service life of the hoist engine 6. In order to connect the winch 6 and the photovoltaic panel 2, a lifting lug may be disposed on the free section 21 of the photovoltaic panel 2 for the connection rope 4 to pass through, and the other end of the connection rope 4 is connected to the winch 6 through a through hole 8 (refer to fig. 1) of the buoyancy column 1. Specifically, a fixed pulley 7 is arranged in the floating column 1, and the connecting rope 4 passes through a through hole 8 (refer to fig. 1) in the floating column 1, changes the direction through the fixed pulley 7, and is connected with the winch 6. When the device works, the connection rope 4 is retracted and released by controlling the positive rotation and the negative rotation of the winch 6. The connecting rope 4 referred to in the application is preferably a steel wire rope, and the light aging can be avoided while the strength is ensured.

In other embodiments, the hoisting machine 6 may be replaced by a hydraulic rod, specifically, the turning of the free section 21 may be realized by the extension and contraction of the hydraulic rod, and it will be understood by those skilled in the art that the manner for driving the turning of the free section 21 may also be other structures, such as a ball screw, and all of them are within the protection scope.

For the concrete structure and shape of the photovoltaic panel 2, reference can be made to fig. 4 and 5, wherein the mounting section 22 is a trapezoidal panel whose vertical projection is trapezoidal; while the free section 21 is an arc panel with a trapezoidal vertical projection, and it needs to be ensured that: when the free section 21 is closest to the buoyancy column 1, that is, when the photovoltaic panel 2 is buckled, the free section 21 is attached to the buoyancy column 1, so that complete protection of the interior of the photovoltaic panel 2 can be realized. In addition, the bottom edge of the free section 21 is common to the bottom edge of the mounting section 22, and the height of the free section 21 is greater than the height of the mounting section 22, so that the mounting section 22 can be completely shielded during the folding of the free section 21 to protect the photovoltaic panel 2. The specific size of the photovoltaic panel 2 needs to be set in combination with the diameter of the buoyancy column 1 and is within the protection range. The structure of the photovoltaic panel 2 can be in other shapes as long as the structure can meet the requirements of the large lower part and the small upper part, so that the photovoltaic panel 2 is tapered after being folded.

In view of the above, there are various ways to achieve the unfolding and buckling of the photovoltaic panel 2, one of which is to hinge the photovoltaic panel 2 to the floating column 1 (shown in fig. 1), and the specific shape of the photovoltaic panel 2 is not particularly limited; secondly, the photovoltaic panel 1 and the buoyancy column 1 can be welded, and the photovoltaic panel 2 is arranged to be a foldable structure, so that the photovoltaic panel 2 can be unfolded and buckled (shown in fig. 2); thirdly, the photovoltaic panel 2 may be hinged to the buoyant column 1 and the photovoltaic panel 2 may be provided as a collapsible structure (combination of fig. 1 and 2). Of the three modes described above, the third mode is the most preferred mode.

In order to limit the position of the buoyancy column 1, the end of the buoyancy column 1 in the sea surface is fixed by four mooring members in different directions, for example, the mooring members may be uniformly arranged along the circumference of the buoyancy column 1, as shown in fig. 8. In practice, the mooring element may be a chain 9, but also a mooring line. Carry on spacingly to buoyancy post 1 through four directions, can effectively prevent that buoyancy post 1 position from changing, accomplish the relatively fixed to buoyancy post 1 for buoyancy post 1 is more stable. In practice, the number of mooring elements may also be varied, for example three or another number may also be arranged evenly along the circumference of the buoyancy column 1.

On the basis of the technical scheme, the offshore wind turbine assembly disclosed in the application is further provided with a radar (not shown in the figure) for observing weather, the radar is in signal connection with the winch 6 and/or the driving piece, and the radar can be installed at the wind turbine main body. When the radar works, when the radar detects severe weather such as cloudy weather or rain, snow, ice, hail and the like, the photovoltaic panel 2 can be controlled to be folded so as to protect the photovoltaic panel 2; and when the radar detects that the weather is clear and suitable for collecting solar energy, the photovoltaic panel 2 is controlled to be unfolded. Automatic control is realized by adopting the radar and controlling the radar, and the sensitivity and the real-time performance of control are improved.

In a particular embodiment, the buoyancy columns 1, anchor chains 9 and photovoltaic panels 2 may be transported apart for ease of transportation and assembled after transportation to a machine site. In practice, also can assemble photovoltaic board 2 and buoyancy post 1 earlier, transport after drawing in photovoltaic board 2 in the transportation to reduce on-the-spot concatenation process, improve assembly efficiency.

In addition, this application still discloses offshore wind turbine assembly, including the compound basic platform of fan photovoltaic. Wherein, this compound basic platform of fan photovoltaic is the compound basic platform of fan photovoltaic that discloses in the above-mentioned embodiment, consequently, the marine fan subassembly that has this compound basic platform of fan photovoltaic also has all above-mentioned technological effects, no longer gives unnecessary details here one by one.

It should be noted that the buoyant column 1 may be of any floating foundation, such as semi-submersible, barge or floating.

As used in the present application and in the claims, the terms "a," "an," "the," and/or "the" are not intended to be exhaustive or to include the plural as well, unless the context clearly indicates otherwise. In general, the terms "comprises" and "comprising" merely indicate that steps and elements are included which are explicitly identified, that the steps and elements do not form an exclusive list, and that a method or apparatus may include other steps or elements. An element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, method, article, or apparatus that comprises the element.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (11)

1. The utility model provides a compound basic platform of fan photovoltaic which characterized in that includes:

the buoyancy column can float on the sea surface and is used for installing the fan main body;

the photovoltaic panel can overturn relative to the buoyancy column, so that the photovoltaic panel is buckled and unfolded.

2. The wind turbine and photovoltaic composite foundation platform of claim 1, wherein the photovoltaic panels are uniformly arranged along the circumferential direction of the buoyancy columns, the photovoltaic panels are in a conical shape relative to the outer contour formed by buckling and splicing the buoyancy columns, and the photovoltaic panels float on the sea surface after being unfolded relative to the buoyancy columns.

3. The wind turbine and photovoltaic composite foundation platform of claim 2, wherein the photovoltaic panel is a bent arc-shaped member, a first end of the photovoltaic panel is hinged to the buoyant column, and a second end of the photovoltaic panel can move toward or away from the buoyant column.

4. The wind turbine and photovoltaic composite foundation platform of claim 3, further comprising a first drive member for driving the photovoltaic panel to rotate relative to the buoyancy column.

5. The wind turbine photovoltaic composite foundation platform of claim 4, wherein the first drive member comprises:

the winch is fixed on the mounting table inside the buoyancy column;

the winch is connected with the free section of the photovoltaic panel through the connecting rope, and a through hole for the connecting rope to pass through and a pulley for reversing the connecting rope are arranged on the buoyancy column.

6. The wind turbine photovoltaic composite base platform according to claim 2, wherein the photovoltaic panel comprises:

the mounting section is connected with the buoyancy column and is a trapezoidal plate with a trapezoidal vertical projection;

the free section, the free section with the installation section rotates to be connected, just the free section can be to being close to or keeping away from the buoyancy post motion, the free section is trapezoidal cambered plate for vertical projection, the free section for when the buoyancy post lock the free section with the laminating of buoyancy post.

7. The wind turbine and photovoltaic composite foundation platform of claim 6, wherein the mounting section is welded or hinged to the buoyant column; when the mounting section is hinged with the buoyancy column, the mounting section can move towards the direction close to or away from the buoyancy column.

8. The wind turbine and photovoltaic composite foundation platform of claim 6, further comprising a second driving member for driving the free section to rotate relative to the mounting section.

9. The wind turbine photovoltaic composite foundation platform of claim 8, wherein the second drive comprises:

the winch is fixed on the mounting table inside the buoyancy column;

the connecting rope is connected with the free section through the connecting rope, and a through hole for the connecting rope to pass through and a pulley for reversing the connecting rope are arranged on the buoyancy column.

10. The wind turbine and photovoltaic composite foundation platform of any one of claims 1 to 9, further comprising a weather radar for observing weather conditions, wherein the weather radar is capable of controlling the deployment and buckling of the photovoltaic panels.

11. Offshore wind turbine assembly, comprising a wind turbine photovoltaic composite base platform according to any of claims 1 to 10.

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