JP6897943B1 - Protective structure for linear equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a protective structure capable of reliably and stably protecting linear equipment by forming a long and flat futon basket with a combination of a protective cell having a different function and a mooring cell. SOLUTION: A protective structure 1 of a linear facility of the present invention includes a futon basket 10 made of a long and flat hexahedron and a filling material 20, and the futon basket 10 has a plurality of partition nets inside. By partitioning in the longitudinal direction with 11d, three or more continuous cells C are formed, and the filling material 20 is composed of a coarse-grained material 21 and a fine-grained material 22 having a particle size smaller than that of the coarse-grained material 21. The mooring cell Cb is formed by the coarse-grained material 21 filled in the plurality of cells C on both sides in the longitudinal direction of the futon cage 10, and is protected by the fine-grained material 22 filled in the cell C sandwiched between the mooring cells Cb. It is characterized in that the cell Ca is formed. [Selection diagram] Fig. 1

Description

The present invention relates to a protective structure for linear equipment, and in particular, by forming a long and flat futon basket with a combination of protective cells and mooring cells having different functions, the linear equipment can be protected reliably and stably. , Regarding protective structures.

Submarine cables for wind power generation facilities and pipelines for transporting natural gas, oil, etc. are laid continuously along the seabed.
These linear equipments may move from their original installation location due to the influence of tidal currents, and the movement may damage the bottom and connecting parts. Further, when the earth and sand below the linear equipment is scoured by the tidal current, the linear equipment may sink into the scouring hole and be deformed, causing damage.
Especially in shallow waters relatively close to the coast, the effects of waves are so great that it is necessary to protect the linear equipment laid on the seabed.
In Patent Document 1, a filter unit made of a synthetic fiber net-like bag filled with crushed stone having a particle size of 50 to 300 mm is used, and a plurality of filter units are installed on the upper part of a submarine cable laid on the seabed. Techniques for protecting submarine cables by coating are disclosed.

Japanese Unexamined Patent Publication No. 2011-137366

The prior art has the following problems.
<1> Since the load of the filter unit acts in dots on the surface of the linear equipment through the crushed stone having a large particle size, the linear equipment may be deformed or damaged. Further, when the filter unit swings due to the tidal current, the crushed stone bites the linear equipment through the stitches, which may damage the linear equipment.
<2> Since it has a dumpling-like shape and low stability, it is likely to roll due to tidal currents, and may fall from the top of linear equipment and lose its protective function.
<3> Since the particle size of the crushed stone is large, the sand below is sucked out through the voids between the crushed stones, which may cause the linear equipment to sink and deform.
<4> Since the laying area per unit is small, a large number of filter units are required to cover the linear equipment of a predetermined length, and both the material cost and the construction cost increase. Further, since the covering surface has a substantially circular shape, there are many gaps between the units, and the protection function is not sufficient.
<5> When suspended from the seabed, it becomes spherical due to the load of crushed stone, so it is difficult to accurately cover linear equipment. Therefore, the construction accuracy is low and the construction efficiency is poor.

An object of the present invention is to provide a protective structure for linear equipment capable of solving the above problems.

The protective structure of the linear equipment of the present invention includes a futon basket made of a long and flat hexahedron and a filling material, and the inside of the futon basket is partitioned in the longitudinal direction by a plurality of partition nets. It constitutes three or more consecutive cells, and the filling material is composed of a coarse-grained material and a fine-grained material having a particle size smaller than that of the coarse-grained material, and is filled in a plurality of cells on both sides in the longitudinal direction of the futon basket. The mooring cell is composed of the coarse-grained material, and the protective cell is composed of the fine-grained material filled in the cell sandwiched between the mooring cells.

In the protective structure of the linear equipment of the present invention, an inner coating material having a mesh size smaller than that of the duvet cage may be attached to at least the inside of the side surface and the bottom surface of the protective cell.

In the protective structure of the linear equipment of the present invention, the inner coating material may be made of a lattice-shaped steel material.

In the protective structure of the linear equipment of the present invention, the inner coating material may be made of a grid-like resin geogrid.

The protective structure of the linear equipment of the present invention may include a plurality of restraint wires connecting two opposing surfaces inside the mooring cell and / or the protective cell.

In the protective structure of the linear equipment of the present invention, a plurality of restraining wires may be arranged in a mooring cell in a substantially cross shape in a plan view, and may be arranged only in the width direction of the futon cage in the protective cell.

In the protective structure of the linear equipment of the present invention, the particle size of the coarse-grained material is in the range of 100 mm to 300 mm, and the particle size of the fine-grained material may be 100 mm or less.

In the protective structure of the linear equipment of the present invention, the particle size of the coarse-grained material may be in the range of 100 mm to 300 mm, and the particle size of the fine-grained material may be in the range of 20 mm to 100 mm.

In the protective structure of the linear equipment of the present invention, the length L, the width W, and the height H in the futon basket may satisfy the relationship of [L ≧ 3W] and [W ≧ 3H].

The protective structure of the linear equipment of the present invention has at least one of the following effects due to the above-described configuration.
<1> The structure is such that the upper part of the linear equipment is held down and protected by the central protection cell, and the mooring cells at both ends are installed directly on the bottom of the water to moor, so the stability is high and the load applied to the linear equipment is high. It is less likely to be deformed or damaged (Fig. 4).
<2> Since it has a long and flat shape, it easily follows and deforms according to the outer shape of the linear equipment, and the linear equipment can be reliably moored to the bottom of the water.
<3> By suppressing the linear equipment with a protective cell filled with fine-grained material, the load can be distributed in a plane rather than a point. Therefore, it is difficult to deform or damage the linear equipment. In addition, there is no risk of damaging the linear equipment due to the biting of the filling material.
<4> Since it has a flat shape, it is not easily affected by tidal currents and is difficult to move. Therefore, the linear equipment can be stably protected for a long period of time, and damage to the linear equipment due to rocking can be prevented.
<5> The fine-grained material in the protective cell captures the sand around the linear equipment and prevents it from being sucked out, so that the linear equipment can be prevented from sinking.
<6> Since the laying area per unit is large, linear equipment can be covered over a long distance at low cost. In addition, since the planar shape is rectangular, it can be laid without gaps to reliably protect linear equipment.
<7> Since a long futon basket is installed crossing the linear equipment, construction is easy and construction efficiency is high.
<8> By using the void in the mooring cell as a habitat for seafood, the fish reef function can be exhibited.

Explanatory drawing of protection structure of linear equipment which concerns on this invention. Explanatory drawing of the futon basket. Explanatory drawing of arrangement of restraint wire rod. Explanatory drawing of usage state of protection structure. Explanatory drawing of Example 3. FIG.

Hereinafter, the protective structure of the linear equipment of the present invention will be described in detail with reference to the drawings.

[Protective structure]
<1> Overall configuration (Fig. 1).
The protective structure 1 of the present invention is a structure that covers and protects linear equipment A laid along the bottom of the water, such as a submarine cable or a pipeline. Here, "protecting" means covering the linear equipment A to protect it from collisions caused by drifting objects in the water and moving animals on the bottom of the water, and mooring the linear equipment A to the bottom of the water to prevent movement due to water flow. This includes preventing the lower part of the linear equipment A from being scoured by a stream of water.
The protective structure 1 includes at least a duvet cage 10 made of a long and flat hexahedron and a filling material 20 filled in the duvet cage 10.
The protective structure 1 constitutes three or more consecutive cells C inside the futon cage 10 by partitioning the inside of the futon cage 10 in the longitudinal direction.
The plurality of cells C are composed of a combination of mooring cells Cb on both sides of the futon cage 10 in the longitudinal direction and protective cells Ca sandwiched between the mooring cells Cb.
In this example, the size of the protective structure 1 is 6 m in length × 2 m in width × 0.6 m in height.

<2> Futon basket.
The futon basket 10 is a box body that houses the filling material 20 inside.
The futon basket 10 includes at least a basket body 11, and in this example, further includes an inner coating material 12 attached to the protective cell Ca inside the basket body 11.
The mesh size of the inner coating material 12 is smaller than the mesh size of the basket body 11.
In this example, the mesh size of the diamond-shaped wire mesh of the cage body 11 is 150 mm, and the mesh size of the geogrid of the inner coating material 12 is 30 mm on each side.
Here, the mesh size of the rhombic wire mesh means the length of one side of the space quadrilateral surrounded by the column lines, and the mesh size of the geogrid is not the mesh size but one side of the space quadrilateral surrounded by strands. Means the length of.

<2.1> The main body of the basket (Fig. 2).
The basket body 11 is a box made of wire mesh.
The basket body 11 is formed by assembling a plurality of side nets 11a, a bottom net 11b, and a lid net 11c in a long box shape. The inside of the basket body 11 is partitioned in the longitudinal direction by a partition net 11d, and a plurality of cells C are formed inside.
In this example, the side net 11a, the bottom net 11b, the lid net 11c, and the partition net 11d are wire mesh panels in which a diamond-shaped wire mesh is spread inside a rectangular frame line, respectively.
However, the side net 11a does not necessarily have to be an independent member. For example, two side nets 11a on both sides in the width direction of the cage body 11 may be foldably connected to the bottom net 11b to form a three-sided integrated structure. Good. Further, for example, the side nets 11a on the long side may be configured by connecting a plurality of side nets 11a instead of one.
In this example, a wire rod (IR coated plated steel wire) in which zinc aluminum alloy plated steel wire is coated with polyethylene ionomer resin is used as the material for each frame wire and diamond-shaped wire mesh.
However, the material such as the frame wire is not limited to this, and may be, for example, a zinc-aluminum alloy-plated iron wire, a zinc-plated iron wire, or the like.

<2.1.1> Dimensions of the basket body.
It is desirable that the dimensions of the basket body 11 satisfy the relationship that the length L, the width W, and the height H satisfy the relationship of [L ≧ 3W] and [W ≧ 3H].
In this example, the size of the basket body 11 is 6 m in length × 2 m in width × 0.6 m in height, so that it is [L = 3W] and [W = 3.3H].
By making the dimensions long and flat as described above, it is possible to exert effects such as flexibility, followability to the outer circumference of the linear equipment A, and a load distribution effect. In addition, since the laying area per unit is large, the material cost and construction cost per ^{m 2 are lower than those of the conventional technique.}

<2.2> Inner pasting material.
The inner coating material 12 is a face material for preventing the fine-grained material 22 from being washed away.
The inner coating material 12 is attached to at least the inside of the side net 11a, the bottom net 11b, and the partition net 11d in the protective cell Ca. In this example, the inner patch 12 is also attached to the lid surface net 11c.
In this example, a resin geogrid is used as the material of the inner coating material 12.
A geogrid is a civil engineering material formed by connecting components having tensile resistance in a grid pattern to form a sheet. The geogrid is a member having high strength, excellent creep characteristics, weather resistance, impact resistance, abrasion resistance, and the like.
In this example, as the geogrid, a product in which a core material made of fibers made of high-strength polyester resin (PET) is coated with polypropylene resin (PP) to form a grid pattern is adopted. Examples of such products include "TRIGRID (registered trademark)" manufactured by Okasan Ribic Co., Ltd.
As described above, the optimum material for the inner coating material 12 is geogrid, but the material is not limited to this, and may be, for example, a welded wire mesh having a mesh size smaller than the mesh size of the cage body 11.

<2.3> Connecting material.
The connecting member 13 is a member that connects the side net 11a, the bottom net 11b, the lid net 11c, and the partition net 11d of the cage body 11 to each other.
In this example, a connecting coil formed by winding a hard steel wire into a coil is used as the connecting material 13.
For example, by winding a connecting coil around the vertical wires of two adjacent side nets 11a, the two side nets 11a can be easily and surely connected.
The connecting material 13 is not limited to the coil material, and may be another known connecting means such as a wire number or a clip.

<2.4> Restraint wire.
The restraint wire 14 is a member that restrains the wire meshes on the two opposing surfaces of the cage body 11.
Specifically, the two facing side nets 11a or the facing side nets 11a and the partition net 11d are connected to each other by a plurality of restraint wires 14.
By mutually restraining the wire meshes on the two opposing surfaces of the cage body 11 with the restraint wire rod 14, it is possible to prevent the side nets 11a from being confined due to the filling of the filling material 20.
In this example, as the restraint wire material 14, an IR-coated plated steel wire having hook-shaped portions that hook into a mesh such as a side net 11a is adopted at both ends.
However, the restraint wire 14 is not limited to this, and may be, for example, a fiber rope, a wire rope, or the like. In short, it may be made of a material having predetermined strength and weather resistance, and may be configured to be reinforced by restraining between two opposing wire meshes.

<2.4.1> Arrangement of restraint wires (Fig. 3).
In this example, the arrangement of the restraint wire 14 is changed between the protective cell Ca and the mooring cell Cb (Note that, in FIG. 3, for convenience of explanation, the bottom net 11b, the lid net 11c, the inner coating material 12, and the inner coating material 12 are used. The filling material 20 is omitted).
Specifically, in the mooring cell Cb, the two restraint wires 14 connect the two side nets 11a in the width direction of the cage body 11 and the side nets 11a in the longitudinal direction and the partition net 11d. That is, the restraint wire 14 is arranged in a substantially cross shape in a plan view.
On the other hand, in the protective cell Ca, two side nets 11a in the width direction of the cage main body 11 are connected to each other by one restraining wire rod 14. That is, the restraint wire 14 is arranged only in the width direction and not in the longitudinal direction.
By not arranging the restraint wire 14 in the longitudinal direction in the protective cell Ca in this way, the protective cell Ca is likely to be curved in the longitudinal direction of the cage body 11, and it is easy to follow the outer shape of the linear equipment A. Become.

<3> Filling material.
The filling material 20 is a lumpy or granular member to be filled in the futon basket 10.
The filling material 20 is composed of a combination of a coarse-grained material 21 and a fine-grained material 22 having a smaller particle size than the coarse-grained material 21.
Here, "small particle size" means that the coarse-grained material 21 and the fine-grained material 22 have their respective particle size ranges, and at least the lower limit of the particle size range of the fine-grained material 22 is the particle size range of the coarse-grained material 21. It means that it is smaller than the lower limit.

<3.1> Coarse grain material.
The coarse-grained material 21 is a filling material 20 that is filled in the cell C of the basket body 11.
In this example, split chestnut stone having a particle size of 200 mm is used as the coarse grain material 21.
The particle size of the coarse-grained material 21 is not limited to this, and may be larger than that of the fine-grained material 22 and within the particle size range larger than the mesh size of the wire mesh of the cage body 11, but the particle size is in the range of 100 mm to 300 mm. It is more preferable to have it in.
The type of coarse-grained material 21 is not limited to split crushed stone, and may be single-grain crushed stone, rock crushed stone, recycled crushed stone such as concrete lump or brick lump.
The mooring cell Cb is formed by the coarse-grained material 21 filled in the cells C on both sides of the cage body 11 in the width direction.
Since the mooring cell Cb can secure a large void in the coarse-grained material 21 by the coarse-grained material 21 having a large particle size, the wave energy in water is sequentially dispersed and absorbed among the coarse-grained materials 21 to absorb the wave energy in the surrounding area. It can be reduced to a level that does not cause scouring.
Further, since the mooring cell Cb has a high porosity of the coarse-grained material 21, the voids of the coarse-grained material 21 can be used as a habitat for fish and shellfish to exhibit a fishing reef function.

<3.2> Fine grain material.
The fine-grained material 22 is a filling material 20 that fills the inner coating material 12.
In this example, crushed stone having a particle size of 50 mm is used as the fine-grained material 22.
The particle size of the fine-grained material 22 is not limited to this, and may be smaller than that of the coarse-grained material 21 and within the particle size range larger than the mesh size of the geogrid of the inner coating material 12, but the particle size is 20 mm to 100 mm. It is more preferable that it is in the range of.
This is irrational in terms of the cost and strength of the wire mesh to be captured when the grain size is smaller than 20 mm, and when the grain size is coarser than 100 mm, the meshing force between the fine grain materials 22 becomes stronger and manual packing work is required instead of heavy machinery. This is to become.
Further, the type of the fine-grained material 22 is not limited to crushed stone, and may be split chestnut stone, boulder, recycled crushed stone, or the like.
The protective cell Ca is composed of the fine-grained material 22 filled in the cell C sandwiched between the mooring cells Cb.
When the sand under the bottom net 11b is sucked from the seabed by the water flow, the protection cell Ca discharges only water and traps the sand in a small gap in the fine-grained material 22 to suck out the sand. Can be prevented.

<4> How to use the protective structure (Fig. 4).
Regarding the usage of the protective structure 1, an example in which a power transmission cable of a wind power generation facility is laid on the seabed will be described.
The protective structure 1 installed in the temporary storage place on land is lifted by the crane of the hoist ship, transported by sea, and suspended in the sea at the installation place.
Subsequently, the longitudinal direction of the protective structure 1 is directed in the direction orthogonal to the linear equipment A, and the protective cell Ca is suspended from the seabed so as to cover the upper part of the linear equipment A.
Then, the protective cell Ca filled with the fine-grained material 22 is deformed following the outer shape of the linear equipment A to hold the linear equipment A in a planar shape, and the mooring cells Cb on both sides are directly installed on the seabed. At this time, the coarse-grained material 21 in the mooring cell Cb bites into the sand on the seabed through the mesh of the bottom net 11b, so that the linear equipment A can be reliably moored.
Since the protective structure 1 has a long flat shape that is not easily affected by the tidal current and has a large contact area with the seabed, the linear equipment A can be stably protected for a long period of time.
Further, since the structure is moored on both sides across the linear equipment A, the load applied on the linear equipment A is small, and the linear equipment A is less likely to be deformed or damaged.

[Examples without using an inner patch]
In the first embodiment, in order to prevent the fine-grained material 22 from flowing out from the mesh of the cage main body 11, an inner pasting material 12 having a mesh size smaller than that of the mesh of the cage main body 11 is attached to the inside of the cage main body 11. However, the inner coating material 12 is not an essential component of the present invention.
For example, if the overall mesh size of the cage body 11 is smaller than the particle size of the fine-grained material 22, the fine-grained material 22 does not flow out from the mesh, so that it is not necessary to separately provide the inner coating material 12.
Alternatively, only the wire mesh surrounding the protective cell Ca may be a wire mesh having a mesh size smaller than the particle size of the fine grain material 22, and the other wire mesh may be a wire mesh having a mesh size larger than the particle size of the fine grain material 22.

[Examples with 4 or more cells]
In Example 1, the number of cells in the protective structure 1 was three, but the number is not limited to this. For example, it may be composed of 4 cells, 5 cells, 6 cells and the like.
In this case, the combination of the number of protective cells Ca and mooring cells Cb is not limited. For example, in the case of 5 cells, one cell in the center may be designated as protective cell Ca and a total of 4 cells on both sides may be designated as moored cells Cb (Fig.). 5 top), the central 3 cells may be the protective cell Ca, and a total of 2 cells on both sides may be the mooring cell Cb (Fig. 5, bottom).
Further, it is not necessary to make the dimensions of all the cells uniform, and for example, the length of the protective cell Ca and the length of the mooring cell Cb may be different.

1 Protective structure 10 Duvet cage 11 Basket body 11a Side net 11b Bottom net 11c Lid net 11d Partition net 12 Inner pasting material 13 Connecting material 14 Restraint wire 20 Filling material 21 Coarse grain material 22 Fine grain material C cell Ca protection cell Cb mooring cell A linear equipment

Claims (9)

A protective structure that covers and protects linear equipment installed on the bottom of the water.
It is equipped with a long and flat hexahedron futon basket and a filling material.
The futon basket constitutes three or more continuous cells by partitioning the inside in the longitudinal direction with a plurality of partition nets.
The filling material is composed of a coarse-grained material and a fine-grained material having a smaller particle size than the coarse-grained material.
A mooring cell is composed of coarse-grained materials filled in a plurality of cells on both sides in the longitudinal direction of the futon basket.
A protective cell is formed by a fine-grained material filled in a cell sandwiched between the mooring cells.
Protective structure. The protective structure according to claim 1, wherein an inner coating material having a mesh size smaller than that of the futon basket is attached to at least the side surface and the inside of the bottom surface of the protective cell. The protective structure according to claim 2, wherein the inner coating material is made of a lattice-shaped steel material. The protective structure according to claim 2, wherein the inner coating material is made of a grid-like resin geogrid. The protection structure according to any one of claims 1 to 4, further comprising a plurality of restraint wires connecting two opposing surfaces inside the mooring cell and / or the protection cell. The protective structure according to claim 5, wherein the plurality of restraint wires are arranged in a substantially cross shape in a plan view in the mooring cell, and arranged only in the width direction of the futon cage in the protective cell. .. The protective structure according to any one of claims 1 to 6, wherein the coarse-grained material has a particle size in the range of 100 mm to 300 mm, and the fine-grained material has a particle size of 100 mm or less. body. The protective structure according to claim 7, wherein the coarse-grained material has a particle size in the range of 100 mm to 300 mm, and the fine-grained material has a particle size in the range of 20 mm to 100 mm. The item according to any one of claims 1 to 8, wherein the length L, the width W, and the height H in the futon basket satisfy the relationship of [L ≧ 3 W] and [W ≧ 3 H]. The protective structure described.

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