JP2016141986A - Construction system for foundation of floating structure and construction method for foundation of floating structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a construction system and a construction method for the foundation of floating structures, which can efficiently construct the foundation of the floating structures.SOLUTION: A construction system 10 for the foundation of floating structures is to construct the foundation of the floating structures comprising a foundation unit 5 floatable in the sea and having a plurality of plan-view polygonal bottomed cylindrical cells 7 arranged in a horizontal array. The construction system 10 comprises: a pouring unit 20 which pours concrete on the lower side 5A of the foundation unit 5 that is fabricated and launched in the sea in advance; a lifting unit 30 which can lift the pouring unit 20; and a support unit 40 which is detachable inside the cell 7, supports the pouring unit 20 and the lifting unit 30 and can be lifted by the lifting unit 30.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a construction system for a foundation portion of a floating structure and a construction method for the foundation portion of the floating structure.

In recent years, floating structures that can effectively use ocean space have been proposed (see, for example, Patent Documents 1 and 2). Recently, there is also a concept of a marine city to construct a high-rise building or a super high-rise building as a floating structure.
When constructing such a floating structure, members constituting the floating structure are manufactured in a land production yard, and these members are transported by sea and connected on the ocean.

JP 2010-101033 A JP 2008-095417 A

By the way, in the case of a large-scale floating structure, the base portion thereof is large-scale, and it is difficult to manufacture it at once on a land or coastal production yard. For this reason, in a large-scale floating structure, it is necessary to manufacture the base part by dividing it into a plurality of members, transport these members by sea, and connect them offshore.
Further, when the entire member is large and difficult to manufacture in the manufacturing yard, it is necessary to manufacture a part of the member in the manufacturing yard and to manufacture the rest on the ocean. For this reason, the construction of the foundation of a large-scale floating structure tends to be costly and costly.

  The present invention has been made in view of the above-described problems, and it is possible to efficiently construct a base part of a floating structure, and to provide a construction system for a base part of a floating structure and a base part of the floating structure. The purpose is to provide a construction method.

  In order to achieve the above-mentioned object, the construction system for a base part of a floating structure according to the present invention can float on the sea while a plurality of bottomed cylindrical cells having a polygonal shape in plan view are arranged in the horizontal direction. A construction system for a base part of a floating structure for constructing a base part of a floating structure having a base unit, in which concrete is placed on an upper part of the base unit that has been manufactured and sent to the sea. An installation unit, a lifting unit capable of lifting the placement unit, and detachable from the inside of the cell, and supports either the placement unit or the lifting unit from below and the lifting unit. And a support unit capable of lifting.

  Moreover, the construction method of the foundation part of the floating structure according to the present invention is a construction method of the foundation part of the floating structure using the construction system of the foundation part of the floating structure, and the foundation unit A base unit manufacturing process for producing and sending to the ocean, a system installation process for installing the placement unit, the lifting unit and the support unit on the foundation unit, and after the system installation process, After the placing step of placing the concrete on the upper side of the foundation unit and the system installation step, the placing unit and the support unit are lifted by the lifting unit and moved into the other cells. And placing the concrete on the upper side of the foundation unit for each cell by repeating the placing step and the moving step. To.

In the present invention, the construction system for the foundation part of the floating structure has a placing unit, so that the foundation unit manufactured in a production yard such as on land or on the coast is transported to the vicinity of the place where the foundation unit is installed. In this place, the concrete can be placed on the upper part of the foundation unit that has been manufactured in advance so that the foundation unit has a desired height using the placement unit.
For this reason, compared with the case where the whole foundation unit is manufactured in a production yard and carried by sea, the sea transportation of a foundation unit can be performed easily. Further, the production yard can be made smaller and the cost can be reduced as compared with the case where the entire basic unit is produced in the production yard.

  Also, by having a lifting unit capable of lifting the placing unit and the support unit, the concrete on the upper side of the foundation unit can be placed while moving the same placing unit and support unit inside the foundation unit. Can do. Thereby, even if it is a large-scale foundation unit, the concrete placement of the whole foundation unit can be efficiently performed without preparing a large-scale placement unit or preparing a large number of placement units. .

Further, in the construction system for the foundation of the floating structure according to the present invention, the placing unit has a nozzle capable of placing concrete on the upper part of the cylindrical wall portion of the cell, It is preferable that it is movable along the upper part of the wall part of the cell.
By being comprised in this way, concrete can be easily placed in the upper part of the wall part of a cell.

Moreover, in the construction system of the base part of the floating structure according to the present invention, the support unit extends in the vertical direction and can be connected to the placing unit and the lifting unit. And a plurality of beams projecting radially in a plan view and extending in the horizontal direction, and the plurality of beams are disposed inside the cell, and each tip portion is a cylindrical shape of the cell. It is preferable to be fixed to the inside of the cell by being pressed from the inside while being in contact with the wall portion.
With this configuration, the support unit can be easily installed inside the cell, and the support unit can be installed at a desired height inside the cell.

Moreover, in the construction system of the base part of the floating structure according to the present invention, it is preferable that the support column is provided to be extendable in the vertical direction.
By setting it as such a structure, a placing unit and a lifting unit can be installed in desired height by expanding and contracting a support | pillar part and adjusting protrusion length.

  According to the present invention, the foundation of a floating structure can be efficiently constructed.

It is an elevational view showing an example of a floating structure according to an embodiment of the present invention. It is a top view which shows the base part of a floating body type structure. It is the sectional view on the AA line of FIG. It is a top view explaining a core part. (A) is a top view which shows a basic unit, (b) is a perspective view of (a). It is a perspective view which shows an example of the construction system of the foundation part of the floating body structure by embodiment of this invention. It is an elevation view which shows an example of the construction system of the foundation part of the floating type structure by embodiment of this invention. It is an elevation view of a placing unit and a support unit. It is the BB sectional drawing of FIG. It is a C direction arrow directional view of FIG. It is the DD sectional view taken on the line of FIG. It is an elevation view explaining a lifting unit. It is an elevation view explaining the lifting unit with the post extended. It is the EE sectional view taken on the line of FIG.

Hereinafter, a construction system and a construction method for a foundation of a floating structure according to an embodiment of the present invention will be described with reference to FIGS. 1 to 14.
As shown in FIG. 1, the floating structure 1 according to the present embodiment is provided on the sea, and includes a base part 2 floating on the sea, a base auxiliary part 3 attached to the base part 2, and an upper part of the base part 2. And the upper structure 4 constructed in the above.
The base auxiliary | assistant part 3 is provided in order to receive buoyancy with the base part 2, or to maintain the base part 2 in the stable state on the sea, for example.
The upper structure 4 is a tower-like high-rise building or a super-high-rise building, and is provided with recreational facilities such as a living space, an office space, a commercial facility, and a park.

As shown in FIG. 2, in this embodiment, the base part 2 is formed so that the center part 2b protrudes below rather than the edge part 2a side.
The base portion 2 includes a core portion 21 disposed in the central portion 2b in plan view, a first outer peripheral portion 22 formed in an annular shape along the outer peripheral portion of the core portion 21 in plan view, and a first outer periphery in plan view. And a second outer peripheral portion 23 formed in an annular shape along the outer peripheral portion of the portion 22.
In the present embodiment, the upper structure 4 is constructed above the core portion 21.

The core part 21 has four foundation structures 211A (200) to 211D (200) connected in the vertical direction. In the present embodiment, the four basic structures 211A to 211D are formed in a substantially hexagonal shape having the same planar view shape. In FIG. 2, the four basic structures 211 </ b> A to 211 </ b> D are not shown in a plan view, but are circular.
Here, the foundation structure disposed at the bottom of the four foundation structures 211A to 211D is a first foundation structure 211A, and a second foundation structure 211B, a third foundation structure 211C, Assume that the four basic structures 211D are arranged in this order.
As shown in FIG. 4, these four foundation structures 211 </ b> A to 211 </ b> D respectively have a plurality of foundation units 5, 5... Connected in the horizontal direction and outer peripheries of the plurality of foundation units 5, 5. And a connecting portion 6 that is provided so as to surround and to which the inner foundation structures 221A to 221C of the first outer peripheral portion 22 are connected. And when the connection part 6 is provided in the outer periphery of the some basic | foundation unit 5,5 ..., respectively, the four foundation structures 211A-211D will become a substantially hexagonal shape in planar view.

As shown in FIG. 5, each of the plurality of basic units 5, 5 is a substantially hexagonal cylindrical wall portion 71 when viewed from the axial direction, and a bottom portion 72 provided on one side of the wall portion 71 in the axial direction. Are formed in a honeycomb structure in which a plurality of bottomed cylindrical cells 7 are arranged in the same plane. The plurality of cells 7, 7... Are arranged in such a direction that the axis of the cylindrical wall portion 71 extends in the vertical direction and the bottom portion 72 is on the lower side.
Such a plurality of foundation units 5, 5... Are made of, for example, full precast concrete. The plurality of basic units 5, 5... Are configured to be able to float on the sea.
In the present embodiment, the plurality of cells 7, 7... Constituting one base unit 5 are integrally formed to form a honeycomb structure. A plurality of cells 7, 7... Constituting one basic unit 5 may be formed individually and connected to form a honeycomb structure.
The plurality of basic units 5, 5... Are formed in different shapes depending on the number and arrangement of cells 7, 7.

The connecting portion 6 has a plurality of cells 7, 7... Arranged along the entire outer periphery of the plurality of connected base units 5, 5... For the connection between the connecting portion 6 and the base unit 5, for example, a PC steel material or a grout material is used in the same manner as the connection between the base units 5 and 5. In addition, it is preferable that the connection part 6 and the base unit 5 are connected more firmly than the connection between the base units 5 and 5.
Moreover, the connection part 6 may be provided with connection means, such as PC steel material, for connecting with the connection part 6 of the other foundation structure 200 connected.

Returning to FIG. 2 and FIG. 3, the first outer peripheral portion 22 includes three inner foundation structures 221 </ b> A (200) to 221 </ b> C (200) arranged on the central portion 2 b side of the foundation portion 2 and connected in the vertical direction. Three outer foundation structures 222A (200) to 222C (200) that are arranged on the edge 2a side of the foundation portion and are connected in the vertical direction with respect to the inner foundation structures 221A to 221C of the above. The inner foundation structures 221A to 221C and the outer foundation structures 222A to 222C are connected.
Here, among the three inner foundation structures 221A to 221C, the foundation structure disposed at the bottom is the first inner foundation structure 221A, and the second inner foundation structure 221B and the third inner foundation structure are formed thereon. Assume that the bodies 221C are arranged in this order. Further, a base structure disposed at the bottom of the three outer base structures 222A to 222C is a first outer base structure 222A, and a second outer base structure 222B and a third outer base structure are formed thereon. Assume that they are arranged in the order of 222C.

  These inner foundation structures 221A to 221C and outer foundation structures 222A to 222C are respectively a plurality of foundation units 5 connected in the horizontal direction, similarly to the foundation structures 211A to 211D of the core portion 21 shown in FIG. .. And a connecting portion 6 provided so as to surround the outer periphery of the plurality of connected base units 5, 5... And connected to another base structure 200.

  The base units 5, 5... Of the inner base structures 221A to 221C and the outer base structures 222A to 222C have a plurality of cells 7, 7... Similar to the base units 5 of the base structures 211A to 211D of the core portion 21. It is formed in a honeycomb structure. The number and arrangement of the cells 7, 7... Of the base units 5 of the inner base structures 221A to 221C and the outer base structures 222A to 222C are the same as the inner base structures 221A to 221C and the outer base structures 222A to 222C, respectively. Designed for configurable numbers and arrays.

  The second outer peripheral portion 23 is an inner foundation structure 231 (200) arranged on the center portion 2b side of the foundation portion 2 and an intermediate foundation arranged on the edge 2a side of the foundation portion 2 relative to the inner foundation structure 231. It has a structure 232 (200) and an outer foundation structure 233 (200) arranged closer to the edge 2a of the foundation 2 than the intermediate foundation structure 232. The inner foundation structure 231 and the intermediate foundation structure 232 are connected, and the intermediate foundation structure 232 and the outer foundation structure 233 are connected.

  These inner foundation structure 231, intermediate foundation structure 232, and outer foundation structure 233 are each a plurality of foundation units connected in the horizontal direction, similarly to the foundation structures 211A to 211D of the core portion 21 shown in FIG. And a connecting portion 6 that is provided so as to surround the outer periphery of the plurality of connected base units 5, 5, and is connected to another base structure 200.

  The base units 5, 5... Of the inner base structure 231, the intermediate base structure 232, and the outer base structure 233 are a plurality of cells 7, 7. It is formed in the structure which has. The number and arrangement of the cells 7, 7... Of the base unit 5 of the inner base structure 231, the intermediate base structure 232, and the outer base structure 233 are respectively the inner base structure 231, the intermediate base structure 232, and the outer base structure 233. The number and arrangement of the structures 233 are designed.

Next, the construction system of the foundation part of the floating structure for constructing the foundation unit 5 described above will be described.
The base unit 5 according to the present embodiment is manufactured in a manufacturing yard in which the lower side 5A of the base unit 5 on the bottom 72 side of the cell 7 is provided on land or along the coast. And the lower side 5A of the manufactured foundation unit 5 is sent out to the sea, and the concrete of the upper side 5B is stepped on the upper end of the lower side 5A of the foundation unit 5 on the sea. . In addition, in the following description, the part already manufactured among the basic units 5 is demonstrated as basic unit 5A.

  As shown in FIG. 6 and FIG. 7, the construction system 10 for the foundation part of the floating structure is constructed by placing concrete on the upper part of the foundation unit 5A (bottom 72 side of the cell 7) produced in the production yard and sent to the sea. A placing unit 20 for installing, a lifting unit 30 capable of lifting the placing unit 20, a removable unit inside the cell 7, and the placing unit 20 and the lifting unit 30 are supported on the top of the cell 7. And a support unit 40. The lifting unit 30 can lift the support unit 40 as well.

  As shown in FIG. 8, the placement unit 20 includes a placement column 210 that extends in the vertical direction and is connected to an upper portion of the support column 410 of the support unit 40, and a concrete accommodation unit 220 that contains concrete. The concrete placement portion 230 for placing the concrete in the concrete housing portion 220 on the upper end portion of the foundation unit 5A, and the rotation support portion for supporting the concrete placement portion 230 so as to be rotatable about the axis of the placement support column 210. 240.

The axis of the support column 40 of the support unit 40 to which the placement column 210 and the support column 210 are connected is arranged at a position overlapping the axis of the cell 7 in which the support unit 40 is installed.
As shown in FIGS. 9 and 10, the concrete placing section 230 includes six nozzle tanks 232, 232... Provided with nozzles 231 for placing concrete on the upper end 71 a of the wall portion 71 of the cell 7. One end portion is connected to the placing column portion 210, and the other end side protrudes horizontally from the placing column portion 210 to support six nozzle tanks 232, 232. ,..., And six flexible pipes 234, 234,... For pressure-feeding the concrete in the concrete accommodating portion 220 to the six nozzle tanks 232, 232,.

The six nozzle support beams 233, 233,... Are arranged radially with respect to the placement column 210 in plan view.
In addition, the six nozzle support beams 233, 233,... Are configured to be rotatable at an interval of at least 60 ° around the axis of the placing column 210. The range in which each of the six nozzle support beams 233, 233... Is rotated is set so as to be shifted by 60 ° about the axis of the placement column 210.
Further, the six nozzle support beams 233, 233... Are formed so that their tip portions reach the upper portions of the corner portions 71b (see FIG. 9) of the wall portion 71 of the cell 7 in which the placement unit 20 is installed. .

As shown in FIGS. 8 and 11, the rotation support unit 240 supports the six nozzle support beams 233, 233... The rotation support part 240 is disposed above the nozzle support beams 233, 233, and is projected in a radial manner with respect to the placing column part 210 in plan view, and extends in the horizontal direction. The first curved beam 242 joined to the projecting end of the horizontal beams 241, 241... And formed in an annular shape around the axis of the placing post 210, and the extending direction of the horizontal beams 241, 241. And a second curved beam 243 formed in an annular shape centering on the axis of the placing post portion 210.
The six horizontal beams 241, 241... Are arranged so as to be spaced from each other by 60 ° around the axis of the placing post 210. The front ends of the six horizontal beams 241, 241... Are connected to a portion above the horizontal beams 241, 241.

Further, as shown in FIGS. 8 and 10, six plates 245, 245... That are rotatable along the first curved beam 242 are provided below the first curved beam 242. One nozzle support beam 233 is joined to each lower part of 245, 245. For this reason, the nozzle support beams 233, 233... Are configured to rotate while being supported by the first curved beam 242 from above.
As a result, the nozzle tanks 232, 232... Each rotate the nozzle support beam 233 around the axis of the placement column 210, and move along the nozzle support beam 233. The concrete is configured so that concrete can be placed on the entire upper end 71a of the wall 71 of the cell 7 installed.
Further, the nozzle support beams 233, 233,... Are configured to be able to rotate around the axis of the placing column part 210 in a stable state by being supported by the rotation support part 240.

As shown in FIG. 12, the lifting unit 30 includes a post 310 extending in the vertical direction and connected to an upper portion of the support column 410 of the support unit 40, and extending in the horizontal direction about the axis of the post 310. It has a swivelable jib 320 and a suspension hook 330 that can move in the horizontal direction along the jib 320 and can be moved up and down.
The axis of the support post 40 of the support unit 40 to which the post 310 and the post 310 are connected is arranged at a position overlapping the axis of the cell 7 in which the support unit 40 is installed.

Further, the post 310 is arranged on the lower side and the lower end portion is connected to the support column 410 of the support unit 40, and the post 310 is arranged on the upper side and the lower side can be inserted into the tube body, and the jib 320 on the upper end portion. Are connected to each other. The tube body 311 and the column body 312 are configured to be relatively movable in the vertical direction.
As shown in FIGS. 12 and 13, the column body 312 is configured to be fixed to the tube body 311 at a predetermined height with respect to the tube body 311. Thereby, the post 320 can change its height dimension, and is configured to be able to support the jib 320 at a predetermined height.

The jib 320 has one end side connected to the column 312 of the post 310 so as to be rotatable around the axis of the column 312 and the other end adjacent to the cell 7 in which the lifting unit 30 is installed. The upper part of 7 is comprised so that turning is possible.
The suspension hook 330 can lock the placing unit 20 and the support unit 40, and is configured to be able to move the placement unit 20 and the support unit 40 to desired positions by raising and lowering the suspension hook 330 and horizontally moving along the jib 320. Has been.

As shown in FIGS. 8, 12, and 14, the support unit 40 includes a support column 410 that extends in the vertical direction and is disposed on the axis of the cell 7, and a support column unit on the upper side of the support column 410. Three upper beams 420, 420, 420 that project radially from 410 in a plan view and extend in the horizontal direction, respectively, and radially support the support column 410 on the lower side of the support column 410 in a plan view. There are three lower beams 430, 430, 430 that protrude and extend in the horizontal direction.
On the upper side of the support column 410, a driving column 210 of the driving unit 20 and a post 310 of the lifting unit 30 are configured to be connectable.

  The three upper beams 420, 420, 420 are arranged so as to be spaced from each other by 120 ° about the axis of the support column 410. The upper beams 420, 420, and 420 can be expanded and contracted in the horizontal direction, respectively, and are configured such that when extended, the distal end reaches the inside of the corner 71 b of the wall 71 of the cell 7. The upper beams 420, 420, 420 are provided with pressing means 421 that urges the upper beams 420 in the extending direction so as to press the wall portions 71 of the cells 7.

  The three lower beams 430, 430, 430 are arranged so as to be spaced from each other by 120 ° about the axis of the support column 410. The lower beams 430, 430, and 430 can be expanded and contracted in the horizontal direction, respectively, and are configured such that the distal end reaches the inside of the corner portion 71 b of the wall portion 71 of the cell 7 when extended. The lower beams 430, 430, and 430 are provided with pressing means 431 that urges the lower beam 430 in the extending direction so as to press the wall 71 of the cell 7.

The support unit 40 includes three upper beams 420, 420, 420 and three lower beams 430, 430, 430, respectively, which press the corners 71 b of the wall 71 of the cell 7 from the inner side by the pressing means 421, 431. By being pushed to each other, they can be arranged at a predetermined height inside the cell 7 so as to stretch each other.
The cell 7 is provided with concrete jaws 73, 73,... Projecting inward inside the corner portion 71b of the wall portion 71 and immediately below the height at which the upper beams 420, 420, 420 are installed. Yes. And upper beam 420,420,420 is mounted on the upper part of these concrete jaws 73,73 ....

Next, the construction method of the foundation unit 5 of the foundation part 2 of the floating structure 1 using the above-described construction system 10 of the foundation part of the floating structure will be described.
First, the base unit 5A on the bottom 72 side of the cell 7 is manufactured on land or in a manufacturing yard provided along the coast, and the manufactured base unit 5A is sent to the sea.
Subsequently, the construction system 10 for the foundation of the floating structure is installed in the foundation unit 5A sent out to the sea. Installation of the construction system 10 for the foundation of the floating structure on the foundation unit 5A is performed using, for example, a crane provided on the ship. In this embodiment, one placing unit 20, two lifting units 30, 30, and four support units 40, 40,. One of the two lifting units 30, 30 is a first lifting unit 30A, and the other is a second lifting unit 30B. The four support units 40, 40... Are assumed to be first to fourth support units 40A, 40B, 40C, 40D.

And the 1st support unit 40A is installed inside the cell 7 which performs concrete placement, and the placement unit 20 is connected to the upper part of this 1st support unit 40A. Further, the second support unit 40B and the third support unit 40C are respectively installed inside the cell 7, the first lifting unit 30A is connected to the upper part of the second support unit 40B, and the upper part of the third support unit 40C is connected to the upper part of the third support unit 40C. Connects the second lifting unit 30B. Then, the fourth support unit 40D is installed inside the cell 7 where the concrete is placed next.
At this time, the placing unit 20, the lifting units 30, 30, and the support units 40, 40,... Are installed in a range where at least one of the first lifting unit 30A and the second lifting unit 30B can lift.

  Subsequently, the concrete is pumped from the concrete accommodating part 220 to each of the six nozzle tanks 232, 232..., And the concrete is placed on the upper end 71 a of the wall part 71 of the cell 7 from each nozzle 231, 231. At this time, the six nozzle support beams 233, 233... Are rotated, and the nozzle tanks 232, 232... Are moved along the nozzle support beams 233, 233. Place concrete in the part.

Subsequently, the placing unit 20 is lifted by the first lifting unit 30A or the second lifting unit 30B, and then placed on the upper part of the fourth support unit 40D installed inside the cell 7 where the concrete is placed. The placing unit 20 is connected. Then, concrete is placed on the upper end portion 71a of the wall portion 71 of the cell 7 where the placing unit 20 is installed.
Subsequently, in the first lifting unit 30A or the second lifting unit 30B, the first support unit 40A is installed inside the cell 7 in which concrete is next placed. Then, the placing unit 20 is installed above the first support unit 40A, and concrete is placed on the upper end portion 71a of the wall portion 71 of the cell 7 where the placing unit 20 is installed.
In this way, concrete is placed on the upper end portions 71a of the wall portions 71 of all the cells 7 while moving the placing unit 20, the first support unit 40A, and the second support unit 40B.

  When the placement unit 20, the first support unit 40A, and the second support unit 40B cannot be installed inside the cells 7, 7... Of the base unit 5 by the first lifting unit 30A and the second lifting unit 30B. The one lifting unit 30 of the first lifting unit 30A and the second lifting unit 30B lifts the other lifting unit 30 and the lifted lifting unit 30 is moved to the first support unit 40A and It connects with the upper part of the support unit 40 in which the placement unit 20 is not installed among the fourth support units 40D. Then, the placement unit 20 and the support unit 40 are moved using the moved lifting unit 30.

In this way, concrete is placed on the upper ends 71 a of the wall portions 71 of all the cells 7 while moving the placement unit 20 and the support unit 40 or the placement unit 20, the lifting unit 30 and the support unit 40.
Then, concrete is placed in stages on the upper ends 71a of the wall portions 71 of all the cells 7, the upper side 5B of the foundation unit 5 is manufactured, and the foundation unit 5 having a predetermined height is constructed.
The concrete placement by the placement unit 20 may be a general method of placing concrete by placing a formwork, or by extracting concrete from the nozzle 231 and the upper end of the wall portion 71 of the cell 7. A method of arranging the portion 71a may be used.

  The connecting portion 6 is also constructed in the same manner as the basic unit 5. First, the lower side of the connecting portion 6 is manufactured in a manufacturing yard, and the lower side of the manufactured connecting portion 6 is sent to the sea. Then, the upper part side of the connection part 6 is manufactured using the construction system 10 of the base part of a floating structure in the sea.

And the some foundation unit 5,5 ... and the connection part 6 which were constructed are connected, and the foundation structure 200 is constructed | assembled. In addition, the connection between the adjacent basic units 5 and 5 and the connection between the basic unit 5 and the connecting portion 6 are performed using, for example, PC steel, and the gap between the adjacent basic units 5 and 5 and the basic unit 5 are connected. The grout material is filled in the gap with the connecting portion 6.
And the constructed | founded foundation structure 200 is connected to an up-down direction and a horizontal direction, and the foundation part 2 is constructed | assembled.

Next, the operation and effect of the above-described construction system 10 for the foundation of the floating structure and the construction method for the foundation of the floating structure will be described with reference to the drawings.
In the construction system 10 for the foundation part of the floating structure and the construction method for the foundation part of the floating structure according to the present embodiment described above, it is possible to place concrete on the upper part of the foundation unit 5A that is manufactured in advance and sent to the sea. Since the placing unit 20 is supported by the base unit 5 by the support unit 40, the upper part of the base unit 5 can be manufactured at sea. The lifting unit 30 can lift and move the support unit 40 and the placing unit 20 to prepare a large-scale placing unit 20 or a large number of placing units 20 even for the large-scale foundation unit 5. Even if the installation unit 20 is not prepared, it is possible to efficiently place the concrete in the entire base unit 5.

Further, the nozzle tanks 232, 232... Are supported by the nozzle support beams 233, 233..., So as to be movable along the upper end 71a of the wall portion 71 of the cell 7. Concrete can be easily placed on the upper end 71a.
The support unit 40 has the upper beams 420, 420, 420 and the lower beams 430, 430, 430 arranged inside the cell 7, and the respective tip portions thereof are in contact with the wall portion 71 of the cell 7. The support unit 40 can be easily installed inside the cell 7 by being pushed and pushed from the inside, and the support unit 40 can be installed at a desired height inside the cell 7.
Thus, in the construction system 10 for the base part of the floating structure and the construction method for the base part of the floating structure according to the present embodiment, the base part 2 of the floating structure 1 can be efficiently constructed.

As mentioned above, although the embodiment of the construction system 10 of the foundation part of the floating structure according to the present invention and the construction method of the foundation part of the floating structure has been described, the present invention is not limited to the above embodiment, Changes can be made as appropriate without departing from the spirit of the invention.
For example, in the above-described embodiment, the cells 7, 7... Are formed in a bottomed cylindrical shape having a hexagonal shape in plan view. However, other than the hexagonal shape in plan view, the cells 7, 7. It may be formed in a bottom cylindrical shape.

Further, in the above embodiment, the base portion 2 is configured by the core portion 21, the first outer peripheral portion 22, and the second outer peripheral portion 23, but such a configuration is not necessary. The base portion 2 only needs to be configured by combining a plurality of base units 5, 5... And a base structure 200, 200.
Moreover, in said embodiment, although the foundation structure 200 has the foundation units 5, 5 ... and the connection part 6, it does not have the connection part 6, but other periphery part of the foundation unit 5 has other. The structure by which the foundation unit 5 of the foundation structure 200 is connected may be sufficient.

  Further, in the above embodiment, the construction system 10 for the base portion of the floating structure has the placing unit 20, the lifting unit 30, and the support unit 40, but the placing unit 20 is the base unit 5. Concrete is constructed so that concrete can be placed on the upper end 71a of the wall 71 of the cell 7, the lifting unit 30 is constructed so that the placing unit 20 and the support unit 40 can be lifted, and the support unit 40 comprises the placing unit 20 and As long as the lifting unit 30 is configured to be supported by the base unit 5, the members and the number of members constituting each may be other than those described above.

For example, in the above-described embodiment, the placement unit 20 is provided with six nozzle support beams 233, 233... For supporting the nozzle tank 232, but the nozzle support beam 233 provided in the placement unit 20 is provided. The number may be other than six. Further, in the above-described embodiment, the nozzle support beam 233 rotates around the axis of the placing column 210 and the nozzle tank 232 moves along the nozzle support beam 233, so that the nozzle 231 of the nozzle tank 232 is moved. Although it is configured to reach a predetermined position, the mechanism for moving the nozzle tank 232 may be other than the above.
In the above embodiment, the rotation support portion 240 is provided with six horizontal beams 241, 241..., And the six horizontal beams 241, 241. However, the number of the horizontal beams 241 provided on the rotation support portion 240 may be other than six, and the horizontal beams 241 adjacent to each other centering on the axis of the placing column portion 210. , 241 may be other than 60 °.
Further, the support column portion 410 of the support unit 40 may be provided so as to be extendable in the vertical direction. By setting it as such a structure, the placing unit 20 and the lifting unit 30 can be installed in desired height by expanding and contracting the support support | pillar part 410 and adjusting protrusion length.

DESCRIPTION OF SYMBOLS 1 Floating structure 2 Foundation part 3 Foundation attachment part 4 Upper structure 5, 5A Foundation unit 6 Connection part 7 Cell 10 Construction system of foundation part of floating structure 20 Placing unit 30 Lifting unit 40 Support unit 410 Support Supporting part (supporting part)
420 Upper beam (beam)
430 Lower beam (beam)
421,431 Pressing means 71 Wall portion 231 Nozzle

Claims (5)

A base part of a floating structure for constructing a base part of a floating structure having a base unit in which a plurality of bottomed cylindrical cells having a polygonal shape in plan view are horizontally arranged and can float on the sea The construction system of
A placing unit for placing concrete on top of the foundation unit that has been produced in advance and sent to the sea;
A lifting unit capable of lifting the placing unit;
A floating structure characterized in that it has a support unit that is detachably attached to the inside of the cell and supports either one of the placing unit and the lifting unit from below and can be lifted by the lifting unit. Construction system for the foundation of things. The placing unit has a nozzle capable of placing concrete on the upper part of the cylindrical wall portion of the cell,
The construction system for a base part of a floating structure according to claim 1, wherein the nozzle is movable along an upper part of the wall part of the cell. The support unit extends in the vertical direction and can support one of the placing unit and the lifting unit, and the support unit projects radially from the support unit in a plan view and extends in the horizontal direction. A plurality of existing beams, and
The plurality of beams are arranged inside the cell, and fixed to the inside of the cell by being pressed from the inside in a state where each tip portion is in contact with the cylindrical wall portion of the cell. A construction system for a foundation of a floating structure according to claim 1 or 2.   The construction system for a foundation portion of a floating structure according to any one of claims 1 to 3, wherein the support column is provided so as to be extendable in the vertical direction. A construction method for a foundation part of a floating structure using the construction system for the foundation part of the floating structure according to any one of claims 1 to 4,
A basic unit production process for producing the basic unit and sending it to the ocean;
A system installation step of installing the placing unit, the lifting unit and the support unit on the foundation unit;
After the system installation step, a placement step of placing concrete on the upper side of the foundation unit with the placement unit;
After the system installation step, the moving unit for moving the placing unit and the support unit to the inside of the other cell by lifting with the lifting unit,
A construction method for a foundation portion of a floating structure, wherein the placing step and the moving step are repeated and concrete on the upper side of the foundation unit is placed for each cell.

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