JPH11269842A - Marine earth wall structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To construct a marine earth wall structure at a low cost. SOLUTION: A marine earth wall structure is constituted of a wall 3 mounted on a crushed stone mound 1 provided to the ocean floor 21 by facing one surface 3a to the sea side 24 and the other surface 3b to the land side 25 and back- filling material 4 coming into contact wit the surface 3b on the land side 25 of the wall 3 to back fill. In that case, the wall is constituted of a plurality of concrete blocks 2, at the same time, a reinforcing material 6 having strength capable of following the displacement of the back-filling material 4 and bearing tensile force, shear force and impact force occurring by the load and displacement of the back-filling material 4 is buried in the back-filling material back filled in the land side 25 of the Wall 3, and the reinforcing material 6 is interlocked with the back-filling material 4 to reduce earth pressure acting on the wall 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a submerged earth wall structure constructed on a coast or a harbor.

[0002]

2. Description of the Related Art As a conventional method for revetment of coasts and harbors, there are revetments using caesons, steel cells, double sheet piles or tie rod type sheet piles.

A revetment using a caisson is a revetment which resists the earth pressure of the ground behind by the weight of the caisson itself and a footing provided under the casing.

FIG. 4 is a sectional view of a submarine earth wall structure using a caisson. This submarine clay wall structure has a crushed stone mound 22 provided on a seabed 21 and a crushed stone mound 22 having one surface 23a facing the sea 24 and another surface 23b facing the land 25 side. The backing member 26 is buried in contact with the land 23 side of the case 23 on the land 25 side, and a landfill 27 covering the backing material 26. Reference numeral 28 in FIG. 4 denotes a ground improvement area for constructing the mound 22.

A revetment using a steel cell is a revetment designed to resist an external force due to the shear resistance of the filling material in the steel cell and the friction between the steel sheet piles constituting the steel cell. is there.

[0006] The revetment by double sheet piles is based on the earth pressure applied to the portion of the steel sheet pile embedded in the ground, the shear resistance of the middle-filled soil packed between the double sheet piles, and the bending rigidity of the steel sheet pile. It is designed to resist external force.

In the revetment using a tie rod type sheet pile, a steel sheet pile and a stay are connected with a tie rod or a tie wire, and the wall of the steel sheet pile is fixed to the ground and an attachment point of the tie rod to stabilize the wall. .

[0008] As a technique for constructing a mud wall structure on land which is a target when constructing an undersea mud wall structure, there is a reinforced mud wall construction method adopted when constructing a retaining wall or the like. . As shown in the cross-sectional view of FIG. 5, the structure using the reinforced earth wall method has a wall unit 32 embedded in a concrete foundation 31 and a plurality of belt-like reinforcing members 33 on a mountain-side surface 32a of the wall unit 32. The reinforcing material 33 fills the mountain side of the wall unit 32 with the landfill soil 34 while maintaining the state in which the reinforcing member 33 is orthogonal to the mountain surface 32a of the wall unit 32. In this method, by laying or inserting the reinforcing material 33 in the soil, the friction (adhesion) between the soil 34 and the reinforcing material 33 increases the stability and strength of the entire soil mass.

[0009]

However, the above-mentioned prior art has the following problems. (1) Since the volume and weight of a structure such as a caisson used for revetment is large, the man-hour required for the manufacture and the time required for the manufacture are prolonged. (2) The amount of mound and replacement sand is large, and the cost increases. (3) A large amount of work is required to improve the ground of the mound foundation. (4) In the reinforced earth wall method, the back ground and the reinforcing tensile material are adhered by the rolling of the unrolled backing soil, so there is no problem on land, but rolling is impossible in the sea. (5) In the reinforced earth wall construction method, the backing material cannot be put in the sea because the wall is not self-supporting.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and the structure used for revetment can be easily transported and the amount of soil and the like to be processed can be reduced. It is intended to provide a submarine mud wall structure.

[0011]

An undersea earthen wall structure according to the present invention is installed on a crushed stone mound provided on the sea floor, with one surface facing the sea and the other surface facing the land. A submerged earth wall structure comprising a wall body and a backing material backed in contact with the land side surface of the wall body, wherein the wall body comprises a plurality of concrete blocks, A strength capable of following the displacement of the backing material and withstanding the tensile force, shear force and impact force generated by the load and displacement of the backing material in the backing material backed on the land side of the wall body By embedding a reinforcing material having the following structure, and engaging the reinforcing material with the backing material, the earth pressure acting on the wall is reduced.

In this submarine soil wall structure, since the wall is made of a thin concrete block, the amount of crushed stone mound to be constructed at the lower part of the wall and the amount of construction for improving the ground of the mound foundation are improved. Need less.

When the wall is made of a concrete block, the independence of the wall is reduced, that is, when the wall falls over due to the earth pressure, the back of the concrete block moves from the land side to the land side. A plurality of reinforcing materials are embedded in the filling material to form a state in which the reinforcing material is meshed between the plurality of earth masses of the backing material. Thus, the shear strength of the backing material is increased, the earth pressure acting on the wall is reduced, and the wall is prevented from falling.

Therefore, it is possible to reduce the manufacturing cost of the submarine soil wall structure without reducing the strength of the submarine soil wall structure.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION
This will be described below with reference to the drawings.

FIG. 1 is a sectional view of a submarine earth wall structure according to an embodiment of the present invention. An undersea soil wall structure according to an embodiment of the present invention includes a crushed stone mound 1 constructed on a seabed 21, one surface 3a on the crushed stone mound 1 on the sea side 24, and the other surface 3b on the land side 25. A wall 3 composed of a plurality of concrete blocks 2 installed facing each other, a backing material 4 backed in contact with the land side surface 3b of the wall 3, and a backing material 4
And the landfill 5 covering the land and the land surface 3b of the wall 3 (connected in this example, but not necessarily connected), and from the surface 3b toward the land side, And a plurality of reinforcing members 6 embedded in the filling member 4.

In this submarine soil wall structure, the concrete block 2 is used for the wall 3 so as to make the wall 3 thin, so that the throughput of the crushed stone mound 1 built on the wall 3 is increased. In addition, the amount of ground improvement for constructing the mound 1 can be reduced.

When the wall 3 is thinned, the independence of the wall 3 is reduced, that is, when the wall 3 falls over due to the earth pressure, the wall 3 is connected to the land surface 3b and the backing material 4 By engaging a plurality of reinforcing members 6 embedded in the backing material 4 with the backing material 4, the shear strength of the backing material 4 is increased, and the earth pressure acting on the wall 3 is reduced.

Therefore, the use of the subsea soil wall structure can reduce the strength of the structure without reducing the strength of the structure.
The manufacturing cost of the undersea earthen wall structure can be reduced.

The submerged earth wall structure will be described in detail.
The thickness of the concrete block 2 is preferably 1 m or less in principle in consideration of workability. And
When the water depth is large and the thickness is large, a hollow block may be used.

The upper limit of the height and the width is 2 to 2 in the maximum dimension.
It is about 3 m. Since the sectional rigidity and stability of the wall body 3 are inferior to those of an integrated wall body, the applicable water depth is about 20 m at the maximum and generally about 10 m.

Since small blocks are used, handling and workability are good.

The concrete block 2 is basically a filling type for a small block and a hollow type for a large block.

The joining between the concrete blocks 2 basically utilizes the weight of the concrete block 2 and the water pressure. However, it is also possible to increase the sense of stability by making the joining portion uneven. Further, a joining groove may be provided in the lateral direction.

The lower end of the wall 3 may basically be the same as the upper concrete block 2. However, in order to enhance the stability, a skirt is provided only on the lower concrete block 2. It may be provided.

The properties and materials of the reinforcing member 5 are basically as follows: (1) A flexible structure or material capable of following the displacement of the backing material 3. (2) tensile force generated by the load and displacement of the backing material 3,
It has strength enough to withstand compressive and impact forces.

The details are as follows. (1) Structure Chain-shaped, ring-shaped, net-shaped,
Membranes, sheets, etc. (2) Material Steel, carbon fiber, etc. (3) Strength Determined based on the scale of the revetment (water depth, etc.), particle size, shape, specific gravity of backing material 3, and expected shear strength.

The backing material 3 is as follows. (1) Particle size Particles with a particle size of about μm, such as soil that is usually imaged,
It cannot be applied because friction and engagement with the reinforcing material 5 cannot be expected. As long as the particle size is at least mm, there is a difference in effect, but it is basically applicable. (2) Shape The rougher the surface, the higher the shear strength of the backing material 3,
The feature of the present invention is that even with the backing material 3 having a small shear strength, the shear strength of the backing material 3 is increased by the effect of the reinforcing material 5, so the surface shape is not particularly defined. (3) Materials Sand, crushed stone, rock, slag, concrete lump, etc.

In a normal seawall, there is a case where a lightweight backing material (foaming bead, air mortar, etc.) is used to reduce the earth pressure on the seawall, but in the present invention, No such consideration is required.

Unless there are special conditions such as environmental preservation, basically any material can be used as long as friction or engagement with the reinforcing material 5 can be expected.

Further, the improvement of the shear strength of the backing material 3 by the engagement of the reinforcing material 5 and the backing material 3 can be achieved when the structure of the reinforcing material is a chain shape, a ring shape or a net shape. This is performed as follows. (1) When the particle size of the backing material 3 is small (several mm to several cm) as compared with the diameter of the chain or ring, a longitudinal sectional view of the backing material in FIG. 2A and FIG. As shown in the cross sectional view of the backing material, the shear strength of the backing material 3 is increased by friction between the backing material 3 and the reinforcing material 5. (2) When the particle size of the backing material 3 is equal to or larger than the diameter of the chain or the ring (several tens of cm or more). As shown in the cross-sectional view of the backing material, the backing material 3 is restrained in the reinforcing material 5 having a net structure, and the backing materials 3 are engaged with each other and the reinforcing material 5 and the backing material 3 are engaged with each other. The shear strength of the backing material 3 increases.

It is assumed that the backing material 3 is self-supporting due to the effect of the reinforcing material 5 and has a structure in which earth pressure does not act on the wall body. Therefore, basically, the reinforcing material 5 and the seawall ( It is not necessary to connect the thin case 2). In particular, the cases that require connection include the case where the water depth is so deep that the earth pressure of the backing material 3 cannot be ignored, the case where the earth pressure of the landfill works, and the case where the earth pressure is expected as a safety factor.

[0033]

According to the present invention, the structure used for revetment can be easily transported, and the amount of soil and the like to be treated can be reduced, so that the manufacturing cost of the submarine earth wall structure can be reduced.

[Brief description of the drawings]

FIG. 1 is a sectional view of an undersea earthen wall structure according to an embodiment of the present invention.

FIGS. 2A and 2B are explanatory diagrams showing a meshing state of a reinforcing material and a backing material when the particle size of the backing material is small, wherein FIG. 2A is a longitudinal sectional view of the backing material, and FIG. It is a cross-sectional view of a material.

FIGS. 3A and 3B are explanatory diagrams showing a state of engagement between the reinforcing material and the backing material when the particle size of the backing material is large, where FIG. 3A is a longitudinal sectional view of the backing material, and FIG. It is a cross-sectional view of a material.

FIG. 4 is a sectional view of a submarine earth wall structure using a conventional casing.

FIG. 5 is a sectional view of a conventional reinforced earth wall structure.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Crushed stone mound 2 Concrete block 3 Wall 4 Backing material 5 Landfill 6 Reinforcement material

Claims (1)

[Claims] 1. A wall installed on a crushed stone mound provided on the sea floor with one surface facing the sea and the other surface facing the land, and a wall contacting the land surface of the wall. And a backing material that is backfilled with the backing material, wherein the wall body is composed of a plurality of concrete blocks, and the backing material that is backfilled on the land side of the wall body. Inside, embed a reinforcing material capable of following the displacement of the backing material and having the strength to withstand the tensile force, shear force and impact force generated by the load and displacement of the backing material, and A submerged earth wall structure characterized by reducing the earth pressure acting on the wall body by meshing with the earth wall.