JPH03158514A - Foundation structure of flexible mound - Google Patents

Abstract

PURPOSE:To fix a bag body to a foundation provided on the seabed ground by forming the bag body in such a structure that an upper sheet is provided with a filling valve and a drainage valve for weight adjustment and a lower sheet for being anchored to the foundation are integrally conjugated. CONSTITUTION:In a foundation 1, an enclosure 3 is formed in the shape of a rectangle on the seabed ground G, a body 2 is made by pouring underwater concrete or the like, filling and hardening it in its inside, and members 5... for connection are formed on its upper surface edge. And a bag body 4 is formed integrally with an upper sheet 6, which is bent upward, and a lower sheet 7, which is brought into contact with the upper surface of the foundation 1, of a flexible material such as a rubber sheet or the like. Moreover, below the upper sheet 6, a filling valve 8 for being filled with sea water B and sand H and a drainage valve 9 for draining excessive sea water are provided. By this, the bag body 4 can be fixed on the sea bed ground by the weight of the foundation 1.

Description

[Detailed Description of the Invention] "Field of Industrial Application" This invention relates to the basic structure of a submerged submerged levee that controls the propagation of waves near the coast and the movement of sand on the seabed, etc. Flexible mound using a bag made of flexible material (
Regarding the basic structure of flexible structure submerged embankments).

``Prior Technology J'' Conventionally, submerged levees for controlling waves and sand near the coast have generally been constructed using caissons or by stacking Uranami blocks underwater.

By the way, in the case of the above-mentioned submerged embankment, caissons and large quantities of Uranami blocks must be transported to the site, and foundation work such as leveling of the seabed and mounds at the construction site is required, which lengthens the construction period and increases costs. There are some problems. In addition, if it becomes necessary to move or remove the structure after installation,
The work requires a lot of time and cost.

Furthermore, it is constructed with caissons and wave-dissipating blocks.
A so-called rigid submerged levee causes waves to break above the crest and continues the turbulence caused by the wave breaking over a wide crest, thereby reducing wave energy loss and dissipating the waves. Therefore, in order to obtain a sufficient wave-dissipating effect with such a submerged levee, the top of the levee must be raised close to the water surface, the levee must be very large, and it must be difficult for ships to navigate. There is a problem that it becomes a hindrance.

Therefore, the present applicant proposed a flexible mound (submerged embankment with flexible structure) as an effective means for solving the above-mentioned problems (Japanese Patent Application No. 63-239872, etc.).

Here, this flexible mound will be explained with reference to FIG. 25.

The flexible mound 40 is made of a sheet-like flexible material installed on the seabed ground G, and includes a bag body 41 that expands when fluid such as seawater is injected, and a bag body 41 that extends along the bottom edge of the bag body 41. The anchor tube 42 is provided with an anchor tube 42 filled with filler such as earth and sand, and the anchor tube 42 is buried in the seabed ground G.

The bag body 41 is made of a sheet-like flexible material such as a rubber sheet or a vinyl chloride sheet, and includes an upper sheet 43 that is flat and has a convex shape curved on the upper surface, and a lower part that is in contact with the seabed ground G. The sheet 44 is integrally joined at these end edges. At the bottom of the upper sheet 43 of this bag body 41, there is seawater B inside this bag body 41.
and a filling valve 45 for injecting and filling sand H, and a discharge valve 46 for discharging excess seawater H injected inside to the outside.
are provided for each. Further, a hollow anchor tube 4 is provided along the bottom edge of the bag body 41, that is, the periphery of the joint between the upper sheet 43 and the lower sheet 44.
2 is installed.

The anchor tube 42 is made of the same flexible material as the bag 41, and is filled with sand H' (filling material) that is the same as the earth and sand of the seabed ground B. By being buried in the seabed ground outside the bottom edge, it becomes the foundation of the flexible mound 40. This anchor tube 42 is provided with an injection valve 47 for injecting and filling the inside thereof with the sand H, and a discharge valve (shown in the drawing) for discharging excess fluid such as seawater.

Next, a method for constructing the flexible mound will be explained with reference to FIGS. 26 and 27.

First, the flexible mound 40, which was manufactured on land and transported to the planned area by a work boat, was sunk into the seabed.
Ground on the submarine ground G.

Next, as shown in FIG. 26, seawater B and sand H are injected into the bag 41 of the flexible mound 40 from the filling valve 45 until a predetermined amount is reached. Further, excess seawater B is discharged from the discharge valve 46.

Then, the seabed ground G around the anchor tube 42 is
As shown in FIG. 7, the excavated soil H° is injected into the anchor tube 42 from the injection valve 47 while excavating. moreover,
The flexible mound 4G is fixed on the seabed ground G by burying the anchor tube 42, the inside of which is filled with earth and sand H'', in the seabed ground G.

``Problem to be solved by the invention'' However, in the conventional foundation structure of a flexible mound, while excavating the seabed ground around the anchor tube,
Since this excavated soil is injected into this anchor tube and this anchor tube is buried in the seabed ground, there is a problem that the soil quality of the seabed ground where the flexible mound is installed is limited to sandy soil. Ta.

This invention was made in view of the above-mentioned circumstances, and aims to provide a basic structure for a flexible mound that is less dependent on the soil quality of the seabed and allows the flexible mound to be anchored on the seabed. It is something to do.

"Means for Solving the Problem" A bag body made of a flexible material and inflated by injecting fluid into the bag body, and a bag body disposed at the bottom of the bag body, and the bag body is fixed on the seabed ground. A foundation structure for a flexible mound comprising a foundation for
In the invention described in ), the foundation structure is such that the bag can be anchored on the seabed ground by the weight of the foundation. Further, in the invention as set forth in claim (2), the foundation has a foundation structure that allows the bag to be anchored on the seabed ground by driving and fixing piles into the seabed ground.

"Operation" In the invention described in claim (1), the foundation installed on the seabed ground can fix the flexible mound on the seabed ground by its weight.

In the invention described in claim (2), the flexible mound can be fixed on the seabed ground by driving a resistor into the seabed ground and fixing the foundation.

"Embodiment" An embodiment of the present invention will be described below with reference to the drawings.

1 to 3 show an embodiment of the invention as claimed in claim (1), and the reference numeral 1 in the drawings indicates the basis of the invention.

This foundation 1 consists of a main body 2 formed into a rectangular shape using prepact concrete or underwater concrete, and a main body 2
It consists of an enclosure 3 made of steel sheet piles for fixing.

The construction method for this foundation 1 is to first erect a large number of steel sheet piles on the seabed ground G to form a rectangular enclosure 3. next,
A main body 2 for installing a bag 4 is made by pouring and filling prepact concrete or underwater concrete into the enclosure 3 so as to cover the unevenness of the surface of the seabed ground 6 and solidifying it. A connecting member 5.5 consisting of a plurality of bolts and other members is attached to the upper surface of the main body 2.
... are provided along the edge of the upper surface by an anchor ring near the edge so that the bag body 4 can be attached. In this way, the base l consisting of the main body 2 and the enclosure 3
is formed.

Next, the structure of the bag body 4 fixed to the upper surface of the foundation 1 will be explained.

The bag body 4 is made of a sheet-like flexible material such as a rubber sheet or a vinyl chloride sheet, and includes an upper sheet 6 that is flat and has a convex shape curved at the upper surface, and a lower sheet 7 that is in contact with the upper surface of the foundation 1. , and have a structure in which these edges are joined together.

At the bottom of the upper sheet 6 of this bag body 4, there is a filling valve 8 for injecting and filling the inside of this bag body 2 with seawater B and sand H, and a filling valve 8 for discharging the excess seawater H injected inside to the outside. A discharge valve 9 is provided respectively.

Further, the lower sheet 7 of the bag body 4 is provided with a mounting piece lO along the peripheral edge joined to the upper sheet 6 to be fixed to the foundation 1. The mounting piece IO is provided with a plurality of connecting holes 11.11, . . . for connecting with the connecting members 5.5, . . . of the foundation 1.

A construction method for attaching the bag body 4 constructed in this manner to the foundation 1 will be explained with reference to FIGS. 4 to 7.

First, as shown in FIG. 4, an integrated bag body 4 is manufactured on land O by joining an upper sheet 6 and a lower sheet 7.

Next, the bag body 4 manufactured on land O is pulled out to sea, and the bag body 4 is towed by two work boats D to the sea area where it is planned to be installed. As shown in Figure 5, two work boats, D
This bag body 4 is supported by mooring ropes F, F installed between them. In this case, seawater B (or seawater and sand) is appropriately injected into the bag 4 as a ballast, and the gap inside the bag 4 is filled with air A to adjust the shape of the bag 4.
It is preferable to adjust the amount of injection so that the specific gravity of the water is slightly larger than that of seawater to facilitate towing by the work boat D.

Upon arrival at the planned installation sea area, seawater is injected into the interior of the bag 4 from the filling valve 8, and while air A is removed from the discharge valve 9, the specific gravity is increased and the bag 4 is sunk into the seabed. the said work boat;
D, as shown in Fig. 6, the bag 4 is installed by slowly stretching the mooring lines F and F to bring the bag 4 to the bottom on the foundation 1 set on the seabed ground G. The connecting holes 11.11, . . . of the piece 10 and the connecting members 5.5, . . . of the foundation 1.
...and connect them.

Then, as shown in FIG. 7, a work boat E equipped with a pump P is carried into the sea area where the flexible mound is installed, and the pump P pumps sand H and seawater into the bag body 4 from the filling valve 8. By injecting the mixture with B and discharging excess seawater B to the outside from the discharge valve 9, a predetermined amount of seawater B and sand H is injected and filled into the bag body 4, and thereby the bag body 4 is Inflates to the specified shape. Of course, this sand H may be earth and sand from the seabed ground G in the sea area where the flexible mound is installed, or earth and sand transported from another location.

In this way, the foundation structure of this flexible mound is made of solidified prepact concrete or underwater concrete that covers the unevenness of the seabed ground surface, and the weight of this foundation allows the flexible mound to be placed on the seabed ground. Since it is a gravity-type foundation structure that is anchored to the seabed, the flexible mound can be anchored on the seabed without being affected by the unevenness or soil quality of the seabed. Further, according to the present invention, the height of the foundation can be determined according to the water depth of the sea area where the flexible mound is installed, so the flexible mound bag can always be placed at a position where the wave-dissipating effect is high.

FIGS. 8 and 9 show a second example of the basic structure of the flexible mound of the present invention.

Here the foundation 12 is precast with the rubble mound 13:
I7)) It consists of a base (PC base) 14 made by REIT.

The construction method of this foundation 12 will be explained. First of all, the seabed ground in the area where the flexible mound is planned to be installed is 0.
Stones are piled up on the submarine ground G so as to cover the unevenness of the surface to form a square pyramid-shaped platform (rubbish mound 13). Next, place the PC base 14 on the top surface of this rubble mound 13.
Laminate. Here, this PC base 14 is formed into a rectangular plate shape using precast concrete.
The bottom surface of the PC base 14 is in close contact with the top surface of the rubble mound 13, and the top surface of the PC base 14 has a plurality of connecting members 15, 15, . . . along the edge of the top surface for attaching the bag 4. and is provided near the edge.

Further, in the third example of the basic structure of the flexible mound of the present invention illustrated in FIGS. 10 and 11, the foundation 16
It consists of a mortar grout 18 surrounded by a steel skirt 17 and the PC base 14.

The construction method of this foundation 16 will be explained - First, a steel skirt 17 is attached to the side surface of the PC base 14, and the tip of this steel skirt 17 is driven into the seabed ground G and fixed. Next, the foundation 16 is provided on the seabed G by filling the gap between the PC base 14 and the seabed G with mortar grout 18 to fill the gap.

Furthermore, in the third example of the foundation structure of the flexible mound of the present invention illustrated in FIGS. 12 and 13, the foundation 1
9 is the PC mounted on the frame 20 constructed by 8w4.
A base 14 is provided.

The construction method for this foundation will be explained. First of all,
Foundation piles made of H steel are driven into the seabed ground. Next, a bridge 20 is constructed by passing a beam made of H steel between these piles. Then, by placing the PC base 14 on this bridge 20, a foundation 19 is provided on the seabed ground G.

As described above, with the foundation structure of the present invention, the anchoring of the flexible mound on the seabed ground is less affected by the unevenness of the seabed ground surface and the soil condition, and the foundation structure is adjusted to suit the water depth of the sea area where the flexible mound is planned to be installed. Since the height of the flexible mound can be adjusted, it is possible to place the flexible mound where it has the highest wave-dissipating effect.

Next, the fourteenth embodiment of the invention described in claim (2) will be explained.
This will be explained with reference to FIGS. 16 to 16.

The foundation 21 consists of two rectangular precast concrete blocks 22 and 22 (PC blocks) and resistors 23 for fixing the PC blocks 22 and 22 on the seabed ground G.
．． It consists of 23,...

The construction method of this foundation 21 will be explained.

First, the surface of the seabed ground 0 on which the foundation 21 is to be installed is flattened, and two PC blocks 22 and 22 are placed on the flattened ground at a predetermined distance and parallel to each other. Place it on G. Here, this PC block 22.22 is provided with a plurality of piling holes 24.24, . A plurality of connecting members 26, 26, . . . for attaching the bag body 25 are provided near one edge along the .

Next, pile driving holes 24.24, ..., piles 23.23, ...
PC blocks 22.22 by penetrating these resistors 24.24, ... into the submarine ground G.
The foundation 21 is provided on the seabed ground G by fixing.

A method for attaching the bag body 25 to this foundation 21 will be explained.

First, the bag body 25 is manufactured on land. The bag body 24 attached to the connecting members 26, 26, . 25 is installed along the longitudinal direction of the bag body 25, and between the upper sheet 28 and the lower sheet 28.
It is a strip-shaped thing provided along the edge where it joins with 9.
Multiple connecting holes 30.30. ...is provided.

Next, the bag 25 is towed by two work boats D to the planned installation sea area, and the mooring lines F and F are slowly stretched, so that the bag 25 is attached to the PC block 2 installed on the submarine ground G.
2. Land on top of 22.

The bag body 25 is attached to the connection hole 30 of the pieces 27 and 27.
．． 30, . . . are connected to the connecting members 26, 26, .

Furthermore, as shown in FIG. 20, a work boat E equipped with a pump P is carried into the sea area where the flexible mound is installed, and the pump P pumps sand H and seawater into the bag body 25 from the filling valve 31. While injecting the mixture with B,
By discharging excess seawater H to the outside from the discharge valve 32,
A predetermined amount of seawater B and sand H are injected and filled into the bag 25, thereby inflating the bag 25 into a predetermined shape.

With the construction method described above, the foundation structure of the present invention can anchor the flexible mound on the seabed ground by driving and fixing piles into the seabed ground.

Furthermore, when a flexible mound is established on the seabed ground using the basic structure of the present invention, FIGS. 21 and 2
As shown in Figure 2, the PC block 2 is placed on the submarine ground G.
The PC block 22.22 is buried in the seabed ground G so that only the upper surface of the PC block 22.22 is exposed, thereby preventing the occurrence of scouring in the lower part of the bag body 25.

Furthermore, blocks made of steel caissons may be used instead of blocks made of precast concrete.

In the flexible mound foundation structure of the present invention shown in FIGS. 23 and 24, the foundation 33 has two rectangular w4
A block 34.34 consisting of a manufactured caisson and a resistor 3 for fixing the other block 34.34 on the seabed ffG.
5.35,...

The upper surface of this block 34.34 has a plurality of piling holes 36.36, which open from the upper surface to the lower surface and have a watertight structure.
・A plurality of connecting members 37 for attaching the bag body 24
．． 37, . . ., a plurality of openings 38, 38, .

The piles 35 are installed in the pile driving holes 36, 36, . . . of the foundation 33.
．． 35,... and these anti-35.35,...
The foundation 33 is installed on the seabed G by driving and fixing it into the seabed G.

As described above, the basic structure of the 7x7 pull mound of the present invention is such that the main body of the foundation is fixed by driving piles into the seabed ground. It is less dependent on soil conditions.

Note that the basic structure of the present invention is not limited to the above-mentioned embodiments; for example, by using blocks made of donut-shaped precast concrete or steel caisson, the occurrence of scour in the lower part of the bag can be prevented. is also possible. It is also possible to provide a bridge between two blocks.

"Effects of the Invention" As explained above, there is provided a bag body made of a flexible material that is inflated by injecting fluid into the bag body, and a bag body that is disposed at the bottom of the bag body and that is placed on the seabed ground. In the flexible mound foundation structure of the invention according to claim (1), the bag body is anchored on the seabed ground by the weight of the foundation. Furthermore, in the foundation structure of the flexible mound according to the invention set forth in claim (2), the foundation is fixed by driving piles into the seabed ground, so that the bag body can be moved to the seabed. By creating a structure that allows it to be anchored on the ground, it is possible to anchor the flexible mound without being affected by the soil condition of the submarine ground where the flexible mound is installed, and the wave-dissipating effect of the flexible mound can be improved. This has the effect of making it possible to use the information effectively.

[Brief explanation of the drawing]

Figures 1 to 3 are diagrams for explaining the invention as claimed in claim (1), in which Figure 1 is a perspective view, Figure 2 is a top view, and Figure 3 is a perspective view.
The figure is a sectional view taken along line I[[-1 of FIG. 2, FIGS. The figures show a modification of the present invention as set forth in claim (1), in which FIG. 8 is a top view, FIG. 9 is a sectional view taken along the line IX-IX in FIG. 8, and FIGS. 10 and 11. 10 is a top view, and FIG. 11 is a diagram showing a second modification of the invention as claimed in claim (1). FIG. 11 is a top view of FIG.
12 and 13 are cross-sectional views taken along the lines shown in claim (1).
12 is a top view, FIG. 13 is a sectional view taken along the xn-xm line in FIG. 12, and FIGS. 14 to 16 are views showing a third modification of the invention claimed in 2) Diagrams for explaining the described invention, FIG. 14 is a perspective view, FIG. 15 is a top view, FIG. 16 is a sectional view taken along the line Xll-Xll in FIG. 15, and FIGS. 17 to 20 21 and 22 are views showing a modification of the invention as claimed in claim (2), and FIG. 21 is a top view. Fig. 22 is xm-xm of Fig. 21
The sectional views taken along the line, FIGS. 23 and 24 are
23 is a top view, FIG. 24 is a sectional view taken along the line Xff-Xff, and FIG.
FIG. 5 is a side sectional view for explaining the basic structure of a conventional flexible mound, and FIGS. 26 and 27 are diagrams for explaining a conventional method of constructing a flexible mound. Figure 1 G: Seabed ground, 1.12.16.19.21133...Foundation,
2... Body, 4... Enclosure, 13... Rubble mound, 14... Precast concrete base,
17... Steel skirt, 18... Mortar grout, 20... Frame, 22... Precast concrete block, 23.35... Pile, 34...Block.

Claims (2)

[Claims] (1) A bag made of a flexible material and inflated by injecting fluid into the bag, and a foundation disposed at the bottom of the bag for fixing the bag on the seabed ground. A basic structure for a flexible mound, characterized in that the bag body is anchored on seabed ground by the weight of the foundation. (2) A bag made of a flexible material and inflated by injecting fluid into the bag, and a foundation disposed at the bottom of the bag for fixing the bag on the seabed. A basic structure for a flexible mound, characterized in that the bag body is anchored to the seabed ground by driving and fixing the foundation by driving piles onto the seabed ground.