JP7465509B2 - Foundation structure for offshore wind power generation facilities - Google Patents

Description

The present invention relates to the foundation structure of an offshore wind power generation facility.

Fixed-bottom offshore wind power generation has been known for some time (see, for example, Patent Document 1 below). In the future, the foundations of offshore wind power generation facilities may be installed on the relatively hard bedrock beneath the sedimentary layers along the coast of Japan.

JP 2020-190152 A

However, the monopile foundations that have the most proven track record in Europe have very large pile diameters of over 4m, and since there are no machines that can efficiently drill holes in rock, construction is difficult when installing on relatively hard rock. When construction of a monopile foundation is difficult, a pile-type jacket foundation with multiple piles can be considered as an alternative. However, because the jacket foundation has a truss structure, it has high rigidity, and the issue is that the damping effect of the ground against vibrations during earthquakes is smaller than that of a monopile foundation. On the other hand, gravity foundations have the issue that their application is limited to solid ground, but they are known to have a damping effect on the ground, especially in short-period vibration zones.

In view of the above circumstances, the present invention provides a foundation structure for offshore wind power generation facilities that is easy to construct and can reduce earthquake response.

In order to achieve the above object, the present invention employs the following means.
In other words, the foundation structure for offshore wind power generation equipment of the present invention is a foundation structure for offshore wind power generation equipment that supports the offshore wind power generation equipment and is installed on the water bottom ground, and comprises a plurality of piles that penetrate the water bottom ground, a flat first seismic isolation device that is supported by the plurality of piles and installed along the water bottom ground, and a second seismic isolation device that is installed on the first seismic isolation device, and the second seismic isolation device has an outer layer formed in a cylindrical shape from a deformable material, and an inner layer in which granular material is filled inside the outer layer.

In the foundation structure for an offshore wind power generation facility configured in this manner, the outer layer of the second seismic isolation device is made of a deformable material, and therefore has a large damping force. The inner layer of the second seismic isolation device is filled with granular material and has a certain weight, and when an earthquake force acts on the second seismic isolation device, it has a restoring force in the opposite direction to the earthquake force. Therefore, the outer layer exerts a damping force while the inner layer exerts a restoring force, thereby reducing the earthquake response.
In addition, because earthquake response can be reduced, the piles (cross-section and length) can be made slimmer than those used with conventional jacket foundations.

In addition, in the foundation structure of the offshore wind power generation facility according to the present invention, the first seismic isolation device may be formed of a steel plate.

In the foundation structure of an offshore wind power generation facility configured in this manner, the first seismic isolation device is formed from a steel plate, and the bending rigidity (EI) of the steel plate is lower than the bending rigidity of the concrete footing. Therefore, the first seismic isolation device is more likely to follow the movements of the water bottom ground, thereby reducing the earthquake response.

The foundation structure for offshore wind power generation equipment according to the present invention is easy to construct and can reduce earthquake response.

FIG. 1 is a perspective view showing a schematic foundation structure of an offshore wind power generation facility according to an embodiment of the present invention. FIG. 2 is a front view showing a schematic foundation structure of an offshore wind power generation facility according to an embodiment of the present invention. 1 is a plan view showing a schematic foundation structure of an offshore wind power generation facility according to an embodiment of the present invention. FIG. 4 is a cross-sectional view taken along line AA in FIG. 3. 1 is a cross-sectional oblique view of a second seismic isolation device of a foundation structure of an offshore wind power generation facility according to one embodiment of the present invention. FIG. FIG. 11 is a plan view showing a schematic foundation structure of an offshore wind power generation facility according to a modified example of an embodiment of the present invention. FIG. 11 is a front view showing a schematic foundation structure of an offshore wind power generation facility according to a modified example of an embodiment of the present invention.

Below, the foundation structure of an offshore wind power generation facility according to one embodiment of the present invention will be described with reference to the drawings.

As shown in FIG. 1, the foundation structure (hereinafter referred to as the "foundation structure") 100 for an offshore wind power generation facility is installed on the bottom ground G (see FIG. 2) and supports the offshore wind power generation facility (not shown). The foundation structure 100 comprises a pile foundation 101 and a substructure 102. The pile foundation 101 supports the substructure 102. The foundation structure 100 is a hybrid foundation that combines the damping characteristics of a gravity type and a monopile type.

The pile foundation 101 has a plurality of piles 1, a first seismic isolation device 2, a plurality of pile head joints 3, and a plurality of second seismic isolation devices 4.

As shown in FIG. 2, the pile 1 extends in the vertical direction. As shown in FIG. 4, the pile 1 has a cylindrical steel pipe 11 and concrete 12 filled in the upper part of the steel pipe 11. The pile 1 penetrates into the water bottom ground G. In this embodiment, there are four piles 1, but the number of piles 1 can be set appropriately as long as it is three or more.

The first seismic isolation device 2 is disposed along the ground surface G1 of the water bottom ground G. The first seismic isolation device 2 is formed of a steel plate. The plate surface of the first seismic isolation device 2 faces the up-down direction. The first seismic isolation device 2 is a bottom plate formed in a flat plate shape. As shown in FIG. 3, the first seismic isolation device 2 has a shape that is approximately rectangular in plan view, with the middle of each side recessed inward into the rectangle. The four piles 1 are located at each vertex of the rectangle in plan view of the first seismic isolation device 2. The first seismic isolation device 2 is formed of a deformable steel plate, and therefore has low rigidity. This allows the first seismic isolation device 2 to easily follow the movements of the water bottom ground G.

As shown in FIG. 4, the first seismic isolation device 2 has a mounting hole 2a that penetrates in the vertical direction at the location where the pile 1 is placed. The upper part of the pile 1 is inserted into the mounting hole 2a.

The pile head joint 3 has a joint concrete section 31, a sheath pipe 32, and grout material 33. As shown in FIG. 1, the joint concrete section 31 is made of concrete and has a ring shape in a plan view. As shown in FIG. 4, a sheath pipe 32 is provided inside the joint concrete section 31, penetrating it in the vertical direction.

The sheath pipe 32 has a tubular shape that extends in the vertical direction. In this embodiment, the sheath pipe 32 is a steel pipe. In the sea, the upper end 1u of the pile 1 is inserted into the inside of the sheath pipe 32, and the space formed between the inside of the sheath pipe 32 and the upper end 1u of the pile 1 is filled with grout material 33, thereby joining the pile 1 and the joint concrete section 31. The grout material 33 is covered with the concrete of the joint concrete section 31, which has high rigidity. In this way, by restraining the pile 1 and the grout material 33 with concrete, the load acting on the grout material 33 of the pile head joint section 3 can be reduced.

The first seismic isolation device 2 is joined to the joint concrete portion 31 of the pile head joint portion 3 by a joining means such as attaching a stud dowel (not shown) provided on the first seismic isolation device 2 to the joint concrete portion 31 of the pile head joint portion 3.

As shown in FIG. 1, the second seismic isolation device 4 is disposed on the first seismic isolation device 2. The second seismic isolation devices 4 are disposed radially from the center of the first seismic isolation device 2, which is substantially rectangular in plan view, toward the pile 1. Four second seismic isolation devices 4 are installed. As shown in FIG. 5, the second seismic isolation device 4 has an outer layer 41 and an inner layer 42.

The outer layer 41 is formed in a rectangular tube shape from a deformable material. In this embodiment, the outer layer 41 is formed from a steel plate. The shape of the outer layer 41 can be set as appropriate.

The inner layer 42 is formed by filling granular material inside the outer layer 41. As the granular material, for example, slag, sand, soil, etc. can be used. The saturated unit weight of the granular material is preferably 19 kN/ ^m3 or more.

As shown in FIG. 4, the second seismic isolation device 4 is joined to the first seismic isolation device 2 by a joining means such as welding or bolting. An end of the second seismic isolation device 4 is disposed inside the pile head joint 3. The second seismic isolation device 4 is joined to the pile head joint 3 by a joining means such as welding an end of the second seismic isolation device 4 to the sheath pipe 32 and attaching a stud dowel 44 provided on the second seismic isolation device 4 to the joint concrete portion 31.

As shown in FIG. 1, the substructure 102 comprises a main pipe 5 and a branch pipe 6. The main pipe 5 extends upward from the first seismic isolation device 2. The main pipe 5 is formed in a tubular shape. The lower end of the main pipe 5 is joined to the upper surface of the first seismic isolation device 2. The branch pipe 6 is arranged at an angle to the vertical plane. The upper end of the branch pipe 6 is joined to the main pipe 5. The lower end of the branch pipe 6 is joined to the upper surface of the second seismic isolation device 4.

In the foundation structure 100 configured in this manner, the outer layer 41 of the second seismic isolation device 4 is formed from a steel plate, which is a deformable material, and therefore has a large damping force. In addition, the inner layer 42 of the second seismic isolation device 4 is filled with granular material, has a certain weight, and has a restoring force in the opposite direction to the seismic force when an earthquake force acts on the second seismic isolation device 4. Therefore, the outer layer 41 exerts a damping force while the inner layer 42 exerts a restoring force, thereby reducing the earthquake response.

In addition, because earthquake response can be reduced, the piles (cross-section and length) can be made slimmer than with conventional jacket foundations.

The first seismic isolation device 2 is also made of steel plate, and the bending rigidity (EI) of the steel plate is lower than the bending rigidity of the concrete footing. Therefore, the first seismic isolation device 2 can easily follow the movement of the water bottom ground G, thereby reducing the earthquake response.

In addition, since the pile 1 is shorter than the jacket foundation, construction work can be easily performed by penetrating the pile into the water bottom ground G and installing it.

In addition, by combining the first seismic isolation device 2, the pile head joint 3, and the second seismic isolation device 4 with the pile 1, it is possible to increase the foundation bearing capacity and reduce the weight of the foundation structure 100.

In addition, by adjusting the length of the pile 1, it is possible to accommodate layered ground of different depths.

(Modification)
Next, a foundation structure of an offshore wind power generation facility according to a modification of the embodiment shown above will be described mainly with reference to Figures 6 to 7. In the following modification, the same members as those used in the above-mentioned embodiment are given the same reference numerals, and the description thereof will be omitted.

As shown in Figures 6 and 7, the foundation structure 100A according to this modified example has three piles 1. The first seismic isolation device 2A has a generally triangular shape in plan view, with the middle of each side recessed inwards into a rectangle. The three piles 1 are located at each vertex of the rectangle in plan view of the first seismic isolation device 2A.

In the foundation structure 100A configured in this manner, the outer layer 41 of the second seismic isolation device 4 is formed from a steel plate, which is a deformable material, and therefore has a large damping force. In addition, the inner layer 42 of the second seismic isolation device 4 is filled with granular material, has a certain weight, and has a restoring force in the opposite direction to the seismic force when an earthquake force acts on the second seismic isolation device 4. Therefore, the outer layer 41 exerts a damping force while the inner layer 42 exerts a restoring force, thereby reducing the earthquake response.

In addition, because earthquake response can be reduced, the piles (cross-section and length) can be made slimmer than with conventional jacket foundations.

In addition, since there are only three piles 1, the structure can be made more compact than the foundation structure 100.

The above describes one embodiment of the foundation structure for offshore wind power generation facilities according to the present invention, but the present invention is not limited to the above embodiment and can be modified as appropriate without departing from the spirit of the invention.

For example, in the above-described embodiment and modified example, the first seismic isolation device has a generally rectangular or triangular shape in plan view, but the present invention is not limited to this. The shape of the first seismic isolation device can be appropriately set to a generally circular or polygonal shape in plan view, etc.

For example, in the embodiment and modified example shown above, the lower structure 102 includes a main pipe 5 and multiple branch pipes 6, but the present invention is not limited to this. The configuration of the upper foundation can be set as appropriate.

1 Pile 2, A First seismic isolation device 3 Pile head joint 3
4 Second seismic isolation device 5 Main pipe 6 Branch pipe 41 Outer layer portion 42 Inner layer portion 100, 100A Foundation structure (foundation structure of offshore wind power generation facility)
101 Pile foundation 102 Substructure G Water bottom ground

Claims (2)

A foundation structure for offshore wind power generation equipment that supports the offshore wind power generation equipment and is installed on the bottom of the water,
A plurality of piles penetrated into the water bottom ground;
A flat-plate-shaped first seismic isolation device supported by the plurality of piles and installed along the water bottom ground;
A second seismic isolation device installed on the first seismic isolation device,
The second seismic isolation device is
An outer layer portion formed into a cylindrical shape from a deformable material;
A foundation structure for offshore wind power generation equipment having an inner layer portion in which granular material is filled inside the outer layer portion. The foundation structure for offshore wind power generation facilities according to claim 1, wherein the first seismic isolation device is formed of a steel plate.

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