Patent Application
20250116256
This application claims priority from the Chinese patent application 202311303308.9 filed Oct. 9, 2023, the content of which is incorporated herein in the entirety by reference.
The present disclosure relates to the technical field of offshore wind power, in particular to a mud floating type offshore wind turbine system and an installation method thereof.
With the increasingly prominent energy crisis, offshore wind power, as renewable energy, has become an important part of a current energy structure. In the related art, only one anchor structure is designed for an offshore wind turbine system to restrain a position of the wind turbine system in a vertical direction, without considering a position of the wind turbine system in a horizontal direction. Thus, when a marine environment is steady, the wind turbine system can operate steadily, but when the marine environment is harsh, the wind turbine system will skew when blown by wind and waves, horizontal displacement of the wind turbine system is too large, and even the wind turbine system may topple.
At present, it is urgent to provide a mud floating type offshore wind turbine system and an installation method thereof to solve the above technical problems.
One or more embodiments of the present disclosure describe a mud floating type offshore wind turbine system and an installation method thereof, which restrain displacement of the wind turbine system in a vertical direction as well as a horizontal direction, thus having high safety.
In a first aspect, an embodiment of the present disclosure provides a mud floating type offshore wind turbine system, comprising: a plurality of gravity anchors, a plurality of suction anchors, an upper wind turbine, a tower drum, a tower drum connector and a wind turbine foundation; wherein the upper wind turbine, the tower drum, the tower drum connector and the wind turbine foundation are sequentially connected in a vertical direction, the wind turbine foundation includes a hollow column body, a first spherical shell, a second spherical shell, a plurality of third spherical shells, a plurality of hollow first connecting rods, a plurality of second connecting rods and a plurality of hollow supporting rods;
In a second aspect, an embodiment of the present disclosure provides an installation method of a mud floating type offshore wind turbine system, applied to the offshore wind turbine system in the above embodiment and including:
According to the offshore wind turbine system and the installation method thereof provided by the embodiments of the present disclosure, in a first aspect, the plurality of suction anchors are arranged, each suction anchor is connected with one first anchor chain, and the other end of each first anchor chain penetrates through the corresponding third spherical shell and the corresponding supporting rod to be connected with the corresponding telescopic anchor disc in the first spherical shell. Since each suction anchor is located beneath the corresponding third spherical shell, the upper wind turbine can be adjusted to the designated height by adjusting the length of each first anchor chain. In addition, when each first anchor is adjusted to a tensioned state, the first anchor chain can restrain displacement of the upper wind turbine in the vertical direction, so that the upper wind turbine is prevented from disengaging from the seabed in a harsh environment. In a second aspect, the plurality of gravity anchors are arranged, each gravity anchor is connected with one second anchor chain, and the other end of each second anchor chain penetrates through the corresponding third spherical shell and the corresponding first connecting rod to be connected with the corresponding telescopic anchor disc in the second spherical shell. Since each gravity anchor is located on the side face of the corresponding third spherical shell, when adjusted to a tensioned state, each second anchor chain is used for restraining displacement of the upper wind turbine in the horizontal direction, so that the upper wind turbine is prevented from rolling over in the harsh environment. Thus, the present disclosure can restrain displacement of the wind turbine system in the vertical direction and the horizontal direction at the same time, so the present disclosure has high safety.
In order to more clearly explain the embodiments of the present disclosure or the technical solutions of the prior art, the drawings needed in the description of the embodiments or the prior art will be briefly described below. Apparently, the drawings in the following description are some embodiments of the present disclosure. For those ordinarily skilled in the art, other drawings can be obtained in accordance with these drawings without involving any inventive effort.
In order to make the objectives, technical solutions and advantages of the embodiments of the present disclosure clearer, the technical solutions in the embodiments of the present disclosure will be clearly and completely described below with reference to the drawings in the embodiments of the present disclosure; and apparently, the described embodiments are merely part, rather than all of the embodiments of the present disclosure. All other embodiments obtained by those ordinarily skilled in the art without involving inventive effort based on the embodiments in the present disclosure fall within the scope of protection of the present disclosure.
In order to better understand the solutions, a mud floating type offshore wind turbine system is explained herein:
The mud floating type offshore wind turbine system may be switched between a floating state and a mud floating state, the floating state refers to that a wind turbine foundation floats on a sea surface or seawater, an upper wind turbine works at a high height in this state, which is beneficial to improving power generation efficiency, and it is suitable for a better marine environment; and the mud floating state refers to that the wind turbine foundation is fixed to a mud layer of the seabed, the upper wind turbine works at a low height in this state, which is conducive to improving safety, and it is suitable for a harsh marine environment.
As shown in
In this embodiment, in a first aspect, the plurality of suction anchors 10 are arranged, each suction anchor 10 is connected with one first anchor chain 608, and the other end of each first anchor chain 608 penetrates through the corresponding third spherical shell 604 and the corresponding supporting rod 607 to be connected with the corresponding telescopic anchor disc in the first spherical shell 602. Since each suction anchor 10 is located beneath the corresponding third spherical shell 604, the upper wind turbine 30 can be adjusted to a designated height by adjusting a length of each first anchor chain 608. In addition, when each first anchor chain 608 is adjusted to a tensioned state, the first anchor chain 608 can restrain displacement of the upper wind turbine 30 in the vertical direction, so that the upper wind turbine is prevented from disengaging from the seabed in a harsh environment. In a second aspect, the plurality of gravity anchors 20 are arranged, each gravity anchor 20 is connected with one second anchor chain 609, and the other end of each second anchor chain 609 penetrates through the corresponding third spherical shell 604 and the corresponding first connecting rod 605 to be connected with the corresponding telescopic anchor disc in the second spherical shell 603. Since each gravity anchor 20 is located on the side face of the corresponding third spherical shell 604, when each second anchor chain 609 is adjusted to a tensioned state, each second anchor chain 609 is used for restraining displacement of the upper wind turbine 30 in the horizontal direction, so that the upper wind turbine is prevented from rolling over in the harsh environment. It can be shown that the present disclosure can restrain displacements of the wind turbine system in the vertical direction and the horizontal direction at the same time, so that safety is high.
It is to be noted that when the wind turbine foundation 60 is in a balanced state, a sphere center of the second spherical shell 603, a sphere center of each third spherical shell 604 and a sphere center of each first connecting rod 605 are located in the same horizontal plane, and a distance between the sphere center of each third spherical shell 604 and the sphere center of the second spherical shell 603 is equal. In addition, the quantity of the suction anchors 10, the quantity of the gravity anchors 20 and the quantity of the third spherical shells 604 are not specifically limited in the present disclosure, which may be selected as 3, 6, 8 or another value according to requirements. When three gravity anchors 20, three suction anchors 10 and three third spherical shells 604 are selected, a structural diagram of the wind turbine system is shown in
In addition, in order to further improve the buoyancy of the wind turbine system, as shown in
As shown in
In some implementations, as shown in
In some implementations, as shown in
In this embodiment the first bases 70 are arranged, when the wind turbine system is in the mud floating state, as shown in
In some implementations, as shown in
In this embodiment, the inner layer, the middle layer and the outer layer are not communicated. Wherein the inner layer acts as an anchor chain passageway, and the middle layer is a sludge scouring layer used for scouring sludge in the groove of the first base 70, and the sludge can be completely scoured by arranging the plurality of first cabins 610, so that the third spherical shell 604 can better abut against the groove of the first base 70, thereby ensuring the stability of the wind turbine system. The outer layer is a ballast tank, when water is charged to the outer layer through the gas-water displacement valve, ballast of the outer layer increases, and the third spherical shell 604 sinks; when water is discharged from the outer layer through the gas-water displacement valve, the ballast of the outer layer decreases, and the third spherical shell 604 floats; and thus, balance of the wind turbine foundation 60 can be kept by adjusting the ballast of each third spherical shell 604. In addition, by arranging the plurality of second cabins 611, ballast of each second cabin 611 is adjusted independently, and the adjusting process can be more accurate, thereby further improving the stability of the wind turbine system.
In addition, a skirt plate is arranged at a bottom end of each gravity anchor 20, and the gravity anchor 20 can be sinked to a deeper position of the mud bed through the skirt plate, thereby improving the stability of the wind turbine system.
As shown in
The method provided by this embodiment is applied to the offshore wind turbine system, and balance capacity of the wind turbine system can be improved by uniformly arranging the plurality of third spherical shells 604 along the circumferential direction of the second spherical shell 603. Thus, when the wind turbine system is installed, the gravity anchors 20 and the suction anchors 10 may be installed firstly, and the upper wind turbine 30 may reach the designated working height only by adjusting the lengths of the anchor chains after the gravity anchors 20 and the suction anchors 10 are installed in place, thereby completing overall installation of the wind turbine system. Specifically, the wind turbine foundation 60 requires to be kept in the balanced state in the process of adjusting the anchor chains, so that the wind turbine system is prevented from toppling, thereby ensuring safety of the installation process. According to the installation method, the wind turbine system can be overall mounted by installing the gravity anchors 20 and the suction anchors 10 based on the ship navigation and positioning system, then keeping the wind turbine foundation 60 in the balanced state, and continuously adjusting the lengths of the anchor chains, and the installation process is simple and high in efficiency.
In some implementations, as for step 1002, the step of keeping a wind turbine foundation 60 in a balanced state, includes:
Acquiring an inclination angle of the wind turbine foundation 60 every first time interval; and
In this embodiment, the first time interval may be determined according to a marine environment, when the marine environment is harsh, the time interval is set as a smaller value, and otherwise it is set as a larger value, for example, the first time interval may be set as 5 seconds. Since the overall wind turbine and the wind turbine foundation 60 are as a whole, and the whole is a rigid part, the measured inclination angle of the wind turbine foundation 60 is the inclination angle of the whole. In addition, the preset inclination angle may be 5°, the target inclination angle being greater than 5° indicates that the wind turbine system inclines greatly, and is prone to toppling, so it is necessary to adjust the ballast of each third spherical shell 604 to straighten the wind turbine foundation 60, thereby ensuring normal installation of the wind turbine foundation 60. It is to be noted that after the gas-water displacement valve is turned on, water can be charged to or discharged from the corresponding third spherical shell 604 through a water pump. The larger the opening degree of the valve, the higher the water charging and discharging rate, and the higher the ballast adjusting speed.
In some implementations, the step of adjusting an opening degree of a gas-water displacement valve on each third spherical shell 604, includes:
For each third spherical shell 604 on the side tilted upward, increasing the opening degree of the gas-water displacement valve on each third spherical shell 604 where located on an upwards-inclined side, wherein the opening degree of the gas-water displacement valve on the third spherical shell 604 located in a middle location is the maximum, and the opening degree of the gas-water displacement valve on each third spherical shell 604 is gradually decreased in a direction away from the third spherical shell 604 located in the middle location; and a water charging rate of the corresponding third spherical shell 604 is increased by increasing the opening degree of the gas-water displacement valve.
In this embodiment, when the wind turbine foundation 60 inclines, the wind turbine foundation 60 is subjected to single-side adjustment, that is, only the ballast of each third spherical shell 604 on the upwards-inclined side is adjusted without adjusting the ballast of each third spherical shell 604 on the downwards-inclined side, thereby ensuring the stability of the adjusting process. In addition, by increasing the opening degree of the gas-water displacement valve of each third spherical shell 604, the water charging rate of the corresponding third spherical shell 604 can be increased, so as to increase the ballast thereof, thus straightening the wind turbine foundation 60. The opening degrees of the gas-water displacement valves of all the third spherical shells 604 are different, and the leveling rate and stability of the wind turbine foundation 60 can be improved.
It is further to be noted that when the wind turbine foundation 60 is in the balanced state, an axis of each first connecting rod 605, a sphere center of the second spherical shell 603 and a sphere center of each third spherical shell 604 are located on the same horizontal plane. As for any moment, the horizontal plane where the center of each third spherical shell 604 is located in the balanced state of the wind turbine system is used as a reference plane, the third spherical shells 604 with sphere centers above the reference plane are determined as the third spherical shells 604 inclining upwards, and the third spherical shells 604 with sphere centers below the reference plane are determined as the third spherical shells 604 inclining downwards.
In some implementations, the step of adjusting an opening degree of a gas-water displacement valve on each third spherical shell 604, further includes:
Each third spherical shell 604 on the side tilted downward, increasing the opening degree of the gas-water displacement valve on each third spherical shell 604 where located on a downwards-inclined side, wherein the opening degree of the gas-water displacement valve on the third spherical shell 604 located in a middle is the maximum, and the opening degree of the gas-water displacement valve on each third spherical shell 604 is gradually decreased in a direction away from the third spherical shell 604 located in the middle location; and a water discharging rate of the corresponding third spherical shell 604 is increased by increasing the opening degree of the gas-water displacement valve.
This embodiment is specific to the situation where the wind turbine system has large inclination angle and high risk of rollover. At this moment, the wind turbine foundation 60 is subjected to bilateral adjustment, that is, the ballast of the third spherical shells 604 on the upwards-inclined side and the downwards-inclined side is adjusted at the same time; on one hand, the ballast of the third spherical shells 604 on the upwards-inclined side is increased, and on the other hand, the ballast of the third spherical shells 604 on the downwards-inclined side is decreased, thereby accelerating balance adjustment. At this moment, the change of the inclination angle requires to be closely detected, so as to prevent the system from reversing the inclination of the system. In addition, the opening degrees of the gas-water displacement valves of all the third spherical shells 604 are different, and the leveling rate and stability of the wind turbine foundation 60 can be improved.
It needs to be noted that in this text, relation terms such as first and second are only used for distinguishing one entity or operation from another entity or operation, and they do not necessarily require or imply that these entities or operations have any actual relation or sequence. In addition, “include”, “comprise” or any other variant thereof are intended to contain comprising of nonexcludability, thereby the process, the method, the commodity, or device that makes to comprise a series of key elements not only comprises those key elements, but also comprises other key elements that are not listed clearly, or be also included as the intrinsic key element of this process, method, commodity or device. Without more constraints, the key element being limited by statement “including one . . . ” doesn't preclude, within the process, the method, the commodity, or the device that includes the described key element, there are also other identical elements.
Consequently, it is to be noted that the above-mentioned description is only illustrative of the preferred embodiments of the present disclosure, rather than to limit the scope of the present disclosure. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present disclosure fall within the scope of protection of the present disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202311303308.9 | Oct 2023 | CN | national |
