JP6872920B2 - Suction basics - Google Patents

Description

The techniques disclosed herein relate to the suction basis.

Conventionally, a suction foundation has been known as a foundation for installing a structure at sea or in the sea. For example, Patent Document 1 discloses a suction foundation having a ceiling portion and a peripheral wall portion and having a partition wall having an open bottom. The partition wall exerts its holding power by being sunk in the submerged ground. The suction foundation is firmly fixed to the submerged ground by this holding force. A structure such as a skeleton is installed or connected to the partition wall.

Japanese Unexamined Patent Publication No. 2005-23730

As described above, a structure such as a skeleton is installed or connected to the suction foundation. When the vibration of this structure is transmitted to the partition wall, the holding force of the suction foundation may gradually decrease. Furthermore, even when an impact force due to waves, wind, or the like acts on the structure, the impact force may be transmitted to the partition wall, and the holding force of the suction foundation may decrease.

The technique disclosed herein was made in view of this point, and the purpose thereof is to suppress a decrease in the holding power of the suction foundation.

The suction foundation disclosed herein includes a first partition wall in which a structure is installed or connected, and a first partition wall having a first ceiling portion and a first peripheral wall portion connected to the first ceiling portion and having an open bottom. A second partition wall that is arranged inside the first partition wall at a distance from the first partition wall and has a second ceiling portion and a second peripheral wall portion connected to the second ceiling portion and has an open bottom. , A connecting portion for connecting the first partition wall and the second partition wall is provided.

According to the suction foundation, it is possible to suppress a decrease in the holding force of the suction foundation.

FIG. 1 is a schematic diagram of a suction foundation. FIG. 2 is a cross-sectional view of the suction foundation in line II-II of FIG. FIG. 3 is a plan view of the suction foundation. FIG. 4 is a schematic diagram of a suction foundation according to another embodiment.

Hereinafter, exemplary embodiments will be described in detail with reference to the drawings.

FIG. 1 is a schematic view of a suction foundation 100. FIG. 2 is a cross-sectional view of the suction foundation 100 in line II-II of FIG. FIG. 3 is a plan view of the suction foundation 100. In FIGS. 2 and 3, the illustration of the wind turbine 40, which will be described later, is omitted.

The suction foundation 100 is a foundation for installing a structure on or under water, and is sunk in the bottom ground G. In the example of FIG. 1, the suction foundation 100 is a foundation for installing the wind turbine 40 at sea. The suction foundation 100 includes a first partition wall 10 on which the wind turbine 40 is installed, a second partition wall 20 arranged inside the first partition wall 10, and a connecting portion 30 connecting the first partition wall 10 and the second partition wall 20. It has.

The first partition wall 10 is formed in the shape of a container in which the ceiling is closed and the bottom is open. Specifically, as shown in FIG. 2, the first partition wall 10 includes a substantially disk-shaped first ceiling portion 11 and a substantially cylindrical first peripheral wall portion 12 connected to the peripheral edge of the first ceiling portion 11. have. A wind turbine 40 is installed on the first ceiling portion 11 (see FIG. 1).

The second partition wall 20 is formed in the shape of a container in which the ceiling is closed and the bottom is open. That is, although the second partition wall 20 is smaller than the first partition wall 10, it has the same shape as the first partition wall 10. Specifically, the second partition wall 20 has a substantially disk-shaped second ceiling portion 21 smaller than the first ceiling portion 11 and a substantially cylindrical second peripheral wall portion connected to the peripheral edge of the second ceiling portion 21. It has 22 and. The second partition wall 20 is arranged apart from the first partition wall 10. That is, a gap is formed between the first ceiling portion 11 and the second ceiling portion 21, and a gap is formed between the first peripheral wall portion 12 and the second peripheral wall portion 22.

The connecting portion 30 connects the first ceiling portion 11 and the second ceiling portion 21. The connecting portion 30 has a function of physically connecting the first partition wall 10 and the second partition wall 20 and a function of reducing vibration or impact force transmitted from the first partition wall 10 to the second partition wall 20. The connecting portion 30 is made of anti-vibration rubber. That is, the connecting portion 30 includes an elastic element and a viscous element. Anti-vibration rubber is an example of anti-vibration material.

The first partition wall 10 is provided with a first drain port 13 for draining water inside the first partition wall 10 (strictly speaking, inside the first partition wall 10 and outside the second partition wall 20). ing. The first drainage port 13 is formed through the first ceiling portion 11. For example, a drainage device including a drainage pump sucks water in the space inside the first partition wall 10 through the first drainage port 13 and discharges the water. The first drainage port 13 is an example of the first drainage section.

Further, the first partition wall 10 is provided with a second drain port 14 for draining water inside the second partition wall 20. The second drainage port 14 is formed through the first ceiling portion 11. Further, the second partition wall 20 is provided with a third drain port 23 for draining the water inside the second partition wall 20. The third drainage port 23 is formed through the second ceiling portion 21. The second drainage port 14 and the third drainage port 23 are connected via a drainage pipe 24. That is, the second drainage port 14 communicates with the space inside the second partition wall 20. The drainage pipe 24 is formed of a flexible pipe and has flexibility. For example, by a drainage device including a drainage pump (a drainage device different from the drainage device of the first drainage port 13), the water inside the second partition wall 20 is collected by the second drainage port 14, the drainage pipe 24, and the third drainage port 23. It is sucked through and discharged. That is, the water inside the second partition wall 20 is discharged from the outside of the first partition wall 10. The second drainage port 14, the drainage pipe 24, and the third drainage port 23 are drainage routes of a system different from that of the first drainage port 13. As a result, the water inside the second partition wall 20 can be sucked at a pressure different from the water in the space inside the first partition wall 10 and outside the second partition wall 20. The second drainage port 14, the drainage pipe 24, and the third drainage port 23 are examples of the second drainage section.

In this way, the first drainage port 13 and the second drainage port 14 are formed on the first ceiling portion 11. As shown in FIG. 3, the first drainage port 13 and the second drainage port 14 are arranged at positions deviating from the center X of the first ceiling portion 11. Specifically, the first drainage port 13 and the second drainage port 14 are point-symmetrical with respect to the center X of the first ceiling portion 11 and are arranged at positions different from each other by 180 degrees.

The wind turbine 40 is an example of a structure installed on the suction foundation 100. The wind turbine 40 has a tower 41 and a rotor 42 provided in the tower 41. The tower 41 is installed on the first partition wall 10. Specifically, the tower 41 is installed at the center X of the first ceiling portion 11. The rotor 42 is rotatably provided at the tip of the tower 41.

Subsequently, a method of installing the suction foundation 100 will be described.

The suction foundation 100 is towed to the installation site with the wind turbine 40 installed on the first partition wall 10 (however, the blade of the rotor 42 is not attached), and is sunk on the seabed of the installation site. First, the suction foundation 100 sinks to the seabed due to its own weight or ballast load. At this time, the lower end portion of the first peripheral wall portion 12 and the lower end portion of the second peripheral wall portion 22 penetrate into the seabed ground G to some extent by the own weight of the suction foundation 100 or the ballast load. The sandy submarine ground G is selected as the installation location of the suction foundation 100.

After that, the water inside the first partition wall 10 is drained through the first drain port 13, and the water inside the second partition wall 20 is drained through the second drain port 14. At this time, sand may be discharged together with water. As a result, a suction load acts on each of the first partition wall 10 and the second partition wall 20, and the first peripheral wall portion 12 and the second peripheral wall portion 22 further penetrate into the seabed ground G. When the first peripheral wall portion 12 and the second peripheral wall portion 22 penetrate into the seabed ground G to a predetermined depth, drainage is stopped. For example, the first partition wall 10 and the second partition wall 20 penetrate until the depth of the second ceiling portion 21 of the second partition wall 20 reaches the seabed ground G (note that in FIGS. 1 and 2, the first ceiling of the first partition wall 10). Part 11 reaches the submarine ground G). After that, the blade is attached to the rotor 42 of the wind turbine 40.

At the time of penetration, the lower end surfaces of the first peripheral wall portion 12 and the second peripheral wall portion 22 receive a resistance force from the seabed ground G, and the outer peripheral surface and the inner peripheral surface of the first peripheral wall portion 12 and the second peripheral wall portion 22 receive the seabed ground G. The frictional force with and acts as a resistance force. Since the dimensions of the first peripheral wall portion 12 and the second peripheral wall portion 22 are different, the resistance force acting on the first peripheral wall portion 12 and the resistance force acting on the second peripheral wall portion 22 are different. Therefore, the suction pressure when draining the water inside the first partition wall 10 and the suction pressure when draining the water inside the second partition wall 20 are set to different values. As a result, the first partition wall 10 and the second partition wall 20 can be appropriately penetrated.

In the suction foundation 100 installed on the seabed ground G, a frictional force acts on a portion of the first partition wall 10 and the second partition wall 20 that is buried in the seabed ground G. As a result, the suction foundation 100 is firmly fixed to the seabed ground G.

Since the wind turbine 40 is installed on the suction foundation 100 configured in this way, the vibration of the wind turbine 40 acts on it. For example, the rotation of the rotor 42 causes the wind turbine 40 to vibrate, and the vibration is transmitted to the suction base 100 via the tower 41. Further, the impact force that the wind turbine 40 receives from the wind and waves also acts on the suction base 100.

On the other hand, the suction foundation 100 adopts the double structure of the first partition wall 10 and the second partition wall 20 described above, so that the vibration and impact force transmitted to the suction foundation 100 is transmitted to the first partition wall 10 and the second partition wall 20. Can be dispersed. As a result, it is possible to suppress a decrease in the holding force of the suction foundation 100.

Specifically, the vibration or impact force from the wind turbine 40 (hereinafter referred to as “vibration or the like”) acts directly on the first partition wall 10 via the tower 41. The vibration or the like transmitted to the first partition wall 10 is transmitted to the second partition wall 20 via the connecting portion 30. That is, the vibration or the like from the wind turbine 40 acts indirectly on the second partition wall 20 via the tower 41. In this way, the vibration and the like from the wind turbine 40 are dispersed in the first partition wall 10 and the second partition wall 20, and are received by the first partition wall 10 and the second partition wall 20. The ratio of vibration and the like dispersed in the first partition wall 10 and the second partition wall 20 depends on the connecting portion 30. The higher the vibration isolation performance of the connecting portion 30, the less the vibration and the like transmitted to the second partition wall 20. In this example, the connecting portion 30 disperses vibration and the like so that the component acting on the second partition wall 20 is smaller than the component acting on the first partition wall 10. As a result, the influence of vibration from the wind turbine 40 on the holding force of the second partition wall 20 can be reduced, and the decrease in the holding force of the second partition wall 20 can be suppressed. Even if the holding force of the first partition wall 10 decreases, the holding force of the second partition wall 20 is maintained. On the other hand, although vibration or the like from the wind turbine 40 acts on the first partition wall 10, a part of the vibration or the like is dispersed in the second partition wall 20. Therefore, it is possible to suppress a decrease in the holding force of the first partition wall 10 as compared with the case where all vibrations and the like act on the first partition wall 10. In this way, the holding power of the suction foundation 100 as a whole can be secured.
Further, the spring constant and the damping coefficient of the connecting portion 30 are set so that the natural frequency of the wind turbine 40 and the natural frequency of the suction foundation 100 do not match. As a result, resonance between the wind turbine 40 and the suction base 100 is prevented.

As described above, the suction foundation 100 has a windmill 40 (structure) installed, and has a first ceiling portion 11 and a first peripheral wall portion 12 connected to the first ceiling portion 11, and the bottom is opened. A bottom having a first partition wall 10 and a second peripheral wall portion 22 arranged inside the first partition wall 10 at a distance from the first partition wall 10 and connected to a second ceiling portion 21 and a second ceiling portion 21. A second partition wall 20 is provided, and a connecting portion 30 for connecting the first partition wall 10 and the second partition wall 20 is provided.

According to this configuration, vibrations and the like from the wind turbine 40 can be dispersed and received by the first partition wall 10 and the second partition wall 20. As a result, the vibration or the like acting on each of the first partition wall 10 and the second partition wall 20 can be reduced as compared with the case where the vibration or the like acts on only one partition wall. As a result, it is possible to suppress a decrease in the holding force of each of the first partition wall 10 and the second partition wall 20.

Further, the connecting portion 30 is formed of a vibration-proof material.

According to this configuration, vibration and the like transmitted from the first partition wall 10 to the second partition wall 20 via the connecting portion 30 can be damped from the wind turbine 40 and the like. As a result, the decrease in the holding force of the second partition wall 20 can be further suppressed.

Further, the first partition wall 10 is provided with a first drainage port 13 (first drainage portion) for draining water inside the first partition wall 10, and the second partition wall 20 is inside the second partition wall 20. A second drainage port 14, a drainage pipe 24, and a third drainage port 23 (second drainage section), which are separate systems from the first drainage port 13, are provided for draining the water.

According to this configuration, the water inside the first partition wall 10 and the water inside the second partition wall 20 can be sucked at different pressures. That is, individual suction loads can be applied to the first partition wall 10 and the second partition wall 20. Since the first partition wall 10 and the second partition wall 20 have different dimensions, the resistance force at the time of penetration into the seabed ground G is different. By sucking the water inside the first partition wall 10 and the water inside the second partition wall 20 at different pressures, the first partition wall 10 and the second partition wall 20 can be penetrated with appropriate suction loads. ..

Specifically, the second drainage port 14, the drainage pipe 24, and the third drainage port 23 communicate with the space inside the second partition wall 20 and penetrate the first partition wall 10.

According to this configuration, even if the second partition wall 20 is arranged inside the first partition wall 10, the water inside the second partition wall 20 can be drained from the outside of the first partition wall 10.

The structure installed on the first partition wall 10 is a wind turbine 40.

The wind turbine 40 vibrates due to the rotation of the rotor 42. Further, the impact force of wind or waves acts on the wind turbine 40. These vibrations and impact forces are transmitted from the wind turbine 40 to the suction base 100. According to the above configuration, it is possible to suppress a decrease in the holding force of the suction foundation 100 due to vibration from the wind turbine 40 or the like.

<< Other Embodiments >>
As described above, the above-described embodiment has been described as an example of the technology disclosed in the present application. However, the technique in the present disclosure is not limited to this, and can be applied to embodiments in which changes, replacements, additions, omissions, etc. are made as appropriate. It is also possible to combine the components described in the above embodiment to form a new embodiment. In addition, among the components described in the attached drawings and the detailed description, not only the components essential for solving the problem, but also the components not essential for solving the problem in order to exemplify the above-mentioned technology. Can also be included. Therefore, the fact that those non-essential components are described in the accompanying drawings and detailed description should not immediately determine that those non-essential components are essential.

For example, the embodiment may have the following configuration.

The shapes of the first partition wall 10 and the second partition wall 20 are not limited to a substantially cylindrical shape. The first partition wall 10 and the second partition wall 20 can be formed in any shape as long as they have a ceiling portion and a peripheral wall portion and do not have a bottom. For example, the first partition wall 10 and the second partition wall 20 may be formed in a square tubular shape having a substantially quadrangular cross section or a substantially pentagonal cross section. Further, the first partition wall 10 and the second partition wall 20 may be formed in a dome shape having a curved ceiling portion.

The connecting portion 30 may be formed of a member other than the anti-vibration rubber as long as the first partition wall 10 and the second partition wall 20 can be connected. The connecting portion 30 is preferably formed of a vibration-proof material. The anti-vibration material is not limited to the anti-vibration rubber, and may be an anti-vibration spring, an anti-vibration pad, an anti-vibration gel, or the like. Further, the vibration isolator may be a vibration isolator such as an MR damper having a magnetic fluid. Further, the number of connecting portions 30 is not limited to one, and a plurality of connecting portions 30 may be provided.

Further, a first drainage port 13 for draining water inside the first partition wall 10, a second drainage port 14, a drainage pipe 24, and a third drainage port 23 for draining water inside the second partition wall 20. Is composed of a separate system, but is not limited to this. For example, the second drain port 14 and the drain pipe 24 may be omitted. In this case, the water inside the second partition wall 20 is drained through the third drain port 23, the space inside the first partition wall 10, and the first drain port 13.

Further, the structure installed or connected to the suction foundation 100 is not limited to the wind turbine 40. The structure may be a caisson or the like. Alternatively, the suction foundation 100 may be used as a foundation for mooring a floating body such as a mooring buoy. FIG. 4 is a schematic view of the suction foundation 100 according to another embodiment. In FIG. 4, the suction foundation 100 moored the floating body 200. A floating body 200 is connected to the first partition wall 10 via a cable 210. Vibration and impact force from the floating body 200 are transmitted to the suction base 100 via the cable 210. As described above, the suction foundation 100 has a double structure of the first partition wall 10 and the second partition wall 20 connected by the connecting portion 30, so that the vibration and impact force from the floating body 200 are applied to the first partition wall 10 and the second partition wall 20. It can be dispersed and received by the two partition walls 20. As a result, it is possible to suppress a decrease in the holding force of each of the first partition wall 10 and the second partition wall 20.

As described above, the techniques disclosed herein are useful for suction foundations.

100 Suction foundation 10 1st partition wall 11 1st ceiling 12 1st peripheral wall 13 1st drainage port (1st drainage section)
14 Second drainage port (second drainage section)
20 2nd partition wall 21 2nd ceiling 22 2nd peripheral wall 23 3rd drainage port (2nd drainage section)
24 Drainage pipe (second drainage section)
30 Connecting part 40 Wind turbine (structure)

Claims (5)

A first partition wall in which the structure is installed or connected and has an open bottom having a first ceiling portion and a first peripheral wall portion connected to the first ceiling portion.
A second partition wall that is arranged inside the first partition wall at a distance from the first partition wall and has a second ceiling portion and a second peripheral wall portion connected to the second ceiling portion and has an open bottom. ,
A connecting portion for connecting the first partition wall and the second partition wall is provided .
The first partition wall and the second partition wall are suction foundations characterized in that they penetrate into the bottom ground by a suction load. In the suction basis according to claim 1,
The connecting portion is a suction foundation characterized in that it is made of a vibration-proof material. In the suction basis according to claim 1 or 2,
The first partition wall is provided with a first drainage portion for draining water inside the first partition wall.
A suction foundation characterized in that the second partition wall is provided with a second drainage section having a system different from that of the first drainage section for draining water inside the second partition wall. In the suction basis according to claim 3,
The suction foundation is characterized in that the second drainage portion has a drainage pipe that communicates with the space inside the second partition wall and penetrates the first partition wall. In the suction basis according to any one of claims 1 to 4,
The structure is a suction foundation characterized by being a wind turbine.

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