JP2020180458A - Ground liquefaction suppression structure - Google Patents

Abstract

To provide a ground liquefaction suppression structure capable of facilitating recovery after an earthquake while draining excess pore water and suppressing sandblasting.SOLUTION: A ground liquefaction suppression structure includes: a columnar drain 18 formed in ground 10; a plant layer 24 arranged over a surface layer 12 of the ground 10 covering the columnar drain 18; and holding means 30 that holds the plant layer 24 on the columnar drain 18.SELECTED DRAWING: Figure 2

Description

The present invention relates to a structure for suppressing liquefaction of the ground.

Conventionally, as an example of a method of suppressing liquefaction of the ground, a method of forming a columnar drain in the ground and draining excess pore water in the ground through the columnar drain to the ground during an earthquake is known. For example, Patent Document 1 discloses a liquefaction countermeasure structure having a drain provided in the ground and a water-impermeable or impervious coating layer provided on the ground surface and covering the drain.

Japanese Unexamined Patent Publication No. 2016-000940

In the liquefaction countermeasure structure shown in Patent Document 1, since the covering layer is provided on the ground surface portion, it is possible to suppress the sandblasting caused by the liquefaction of the ground. However, since the coating layer is impermeable or impervious, it is difficult to drain excess pore water in the ground from the ground surface, and it is difficult to dissipate excess pore water during liquefaction at an early stage. is there.

For this reason, it is necessary to form a drainage box (wastewater treatment means) for draining the excess pore water conducted to the drain to the ground surface portion in the covering layer, and it is not easy to construct the covering layer. Furthermore, when the covering layer was damaged by the liquefaction of the ground, it was necessary to repave the ground surface again, and it was not easy to recover after the earthquake.

In view of the above facts, it is an object of the present invention to provide a ground liquefaction suppression structure capable of achieving both drainage of excess pore water and suppression of blasting sand and facilitating recovery after an earthquake. ..

The ground liquefaction suppression structure according to claim 1 includes a columnar drain provided in the ground, a plant layer provided on the surface layer of the ground and covering the columnar drain, and the plant layer on the columnar drain. It has a holding means for holding in.

According to the above configuration, a columnar drain is arranged in the ground, and a plant layer covering the columnar drain is provided on the surface layer of the ground. As a result, liquefaction of the ground can be suppressed by draining excess pore water onto the ground through a columnar drain during an earthquake. In addition, the roots of the plants in the plant layer, which have a filter effect of suppressing the permeation of sand while allowing water to permeate, can suppress the sand blasting from the top of the columnar drain while quickly dissipating the excess pore water pressure. ..

Here, the plant layer is held on the columnar drain by the holding means. Therefore, it is possible to suppress the floating of the plant layer at the time of liquefaction of the ground, and it is possible to suppress the lateral flow of the liquefied ground by pressing the ground by the roots of the plants constituting the plant layer. In addition, since the plants constituting the plant layer have a self-renewal ability, it becomes easy to maintain the plant layer, and it becomes easy to partially repair the plant layer and to gradually restore the plant layer after liquefaction occurs.

The ground liquefaction suppressing structure according to claim 2 is the ground liquefaction suppressing structure according to claim 1, and the holding means is a steel pipe driven around the columnar drain and the steel pipe. It has a pressing member provided on the upper part and locked to the plant layer.

According to the above configuration, the steel pipe is driven around the columnar drain, and the pressing member provided on the upper part of the steel pipe is locked to the plant layer, so that the plant layer is pressed by the pressing member and held on the columnar drain. it can. Further, when the ground is liquefied, the pulling out of the steel pipe is suppressed by the frictional force between the columnar drain and the ground around the columnar drain, so that the floating of the plant layer can be suppressed.

The ground liquefaction suppressing structure according to claim 3 is the ground liquefaction suppressing structure according to claim 1, and the holding means is a plurality of the holding means driven into the surface layer of the ground around the columnar drain. Anchor, and a connecting member that connects the plurality of the anchors to each other and is locked to the plant layer.

According to the above configuration, a plurality of anchors are driven into the surface layer of the ground around the columnar drain, and the connecting member connecting the anchors is locked to the plant layer, so that the plant layer is pressed by the connecting member and placed on the columnar drain. Can be held. Further, when the ground is liquefied, the pulling out of a plurality of anchors is suppressed by the total frictional force between the columnar drain and the surrounding ground, so that the floating of the plant layer can be suppressed.

According to the ground liquefaction suppression structure according to the present invention, it is possible to achieve both drainage of excess pore water and suppression of sandblasting, and it is possible to facilitate recovery after an earthquake.

(A) is an overall perspective view showing the liquefaction suppressing structure of the ground according to the first embodiment, and (B) is a perspective view showing the holding means of the liquefaction suppressing structure of the ground. It is a vertical sectional view which shows the liquefaction suppression structure of the ground which concerns on 1st Embodiment. It is a partial cross-sectional perspective view which shows the liquefaction suppression structure of the ground which concerns on 2nd Embodiment. It is a partial cross-sectional perspective view which shows the liquefaction suppression structure of the ground which concerns on 3rd Embodiment. It is a partial cross-sectional perspective view which shows the liquefaction suppression structure of the ground which concerns on 4th Embodiment. (A) and (B) are partial cross-sectional perspective views showing the liquefaction suppression structure of the ground according to the modified example.

Hereinafter, the first to fourth embodiments of the present invention and the ground liquefaction suppressing structure according to the modified example will be described with reference to FIGS. 1 to 6. In the figure, arrows X and Y indicate two horizontal directions, and arrow Z indicates a vertical direction.

<First Embodiment>
First, the ground liquefaction suppression structure according to the first embodiment of the present invention will be described with reference to FIGS. 1 and 2.

(Construction)
As shown in FIGS. 1A and 2, the ground 10 to which the liquefaction suppressing structure of the ground of the present embodiment is applied is, for example, a surface layer 12, a liquefaction layer 14 existing in the lower layer of the surface layer 12, and a liquid. It has a non-liquefied layer 16 existing under the chemical layer 14.

Here, the liquefaction layer 14 is made of, for example, hydrous sandy soil, and the interstitial water saturated between the soil particles flows due to the vibration during an earthquake, and the interparticle bond of the soil particles is broken to make a liquid. It is a layer that is likely to be shaped. On the other hand, the non-liquefied layer 16 is a layer made of, for example, cohesive soil or bedrock, and is unlikely to become liquid due to vibration during an earthquake.

The ground liquefaction suppression structure of the present embodiment has a plurality of columnar drains 18 provided in the ground 10. As shown in FIG. 2, the columnar drain 18 is composed of, for example, a cylindrical drain hole 20 constructed in the ground 10 and a drain material 22 filled in the drain hole 20. As the drain material 22 filled in the drain hole 20, known materials such as crushed stone, gravel, sand, and pressed paper can be used.

The columnar drain 18 may be configured by filling the drain material 22 into a resin or metal pipe (not shown) having a plurality of holes formed on the outer peripheral surface. Further, a filter layer (gravel layer) (not shown) for suppressing clogging of the columnar drain 18 may be provided at the top end portion 18A of the columnar drain 18.

The columnar drain 18 (drain hole 20) extends vertically into the ground 10, the top end 18A opens on the surface layer 12 of the ground 10, and the bottom end penetrates the liquefaction layer 14. It has reached the non-liquefied layer 16.

Further, as shown in FIG. 1 (A), the columnar drains 18 are arranged in the ground 10 in two horizontal directions (arrow X direction and arrow Y direction in FIG. 1 (A)) at predetermined intervals in a plan view. They are arranged in a grid pattern. The diameter of the columnar drain 18 is, for example, about 40 mm to 600 mm, and the distance between the columnar drains 18 is, for example, about 1.0 m to 40.0 m.

Further, the ground liquefaction suppression structure of the present embodiment has a plant layer 24 provided on the surface layer 12 of the ground 10. The plant layer 24 extends in a plane, that is, in two horizontal directions (arrow X direction and arrow Y direction in FIG. 1A), and covers a plurality of columnar drains 18. As a result, as shown in FIG. 2, the plant layer 24 is laid between the adjacent columnar drains 18.

The plant layer 24 has a sand layer 26 formed on the surface layer 12 of the ground 10 and a plant 28 composed of, for example, a ground cover plant planted on the sand layer 26. The ground cover plant is a general term for plants that cover the surface layer 12 of the ground 10, and refers to woody plants and herbs that have a short plant height and strong properties. Further, the plant layer 24 may have a layer made of a non-woven fabric or the like as a root entanglement material provided between the sand layer 26 and the plant 28, in addition to the sand layer 26 and the plant 28.

In the plant layer 24, the plants 28 are densely planted so as to cover the entire sand layer 26, and the roots 28A of the plant 28 extend in a mesh pattern with the sand layer 26 as the soil. The root 28A of the plant 28 extending in a mesh pattern has a filter effect of suppressing the permeation of sand while allowing permeation of water.

It is preferable that the plant 28 constituting the plant layer 24 has a root 28A capable of maintaining a sufficient pressure resistance (strength) throughout the year. Examples of ground cover plants having root 28A capable of maintaining sufficient pressure resistance throughout the year include turfgrass, shrubs, vines, bamboo grass, herbs, ferns and the like.

Further, the ground liquefaction suppressing structure of the present embodiment has a holding means 30 for holding the plant layer 24 on the columnar drain 18. In the present embodiment, as shown in FIG. 1B, the holding means 30 is composed of a steel pipe 32 and a pressing member 34 provided on the upper portion of the steel pipe 32.

The steel pipe 32 has, for example, a cylindrical shape, and its inner diameter is one size larger than the diameter of the columnar drain 18. Further, a plurality of holes 32A are formed on the outer peripheral surface of the steel pipe 32 so that water can flow in and out of the steel pipe 32 from the outside of the steel pipe 32.

Further, the height of the steel pipe 32 is appropriately determined by the magnitude of the required frictional force between the ground 10 and the outer peripheral surface of the steel pipe 32. Here, the frictional force (extreme frictional force) R (kN) between the ground 10 and the outer peripheral surface of the steel pipe 32 is the ultimate frictional stress degree τ (kN / m ² ) × the area A (m) of the outer peripheral surface of the steel pipe 32. ^Obtained by ² ). The ultimate frictional stress degree τ (kN / m ² ) is a numerical value determined by the geology (sandy soil, cohesive soil) of the ground 10.

On the other hand, the holding member 34 is composed of a plurality of wire rods fixed to the upper end surface of the steel pipe 32 by welding or the like. In the present embodiment, for example, the holding member 34 is formed by intersecting the three wire rods at the center of each other. 34 has an asterisk shape in a plan view.

The pressing member 34 may have any shape as long as it allows water to flow in and out from the upper part of the steel pipe 32 and can be locked to the plant layer 24. For example, a cross in a plan view. It may have a shape or a mesh shape.

The holding means 30 holds the plant layer 24 on the top end 18A of the columnar drain 18 by pressing the plant 28 constituting the plant layer 24 from above. Specifically, as shown in FIGS. 1A and 2, a steel pipe 32 is driven around the columnar drain 18 in the surface layer 12 of the ground 10 from above the plant layer 24, and a presser provided on the upper part of the steel pipe 32 is provided. The member 34 is locked to the plant 28 of the plant layer 24. As a result, the plant 28 of the plant layer 24 can be pressed from above by the pressing member 34 of the holding means 30.

(Action during rainfall)
In the ground liquefaction suppression structure of the present embodiment, the root 28A of the plant 28 constituting the plant layer 24 provided on the surface layer 12 of the ground 10 has a filter effect of suppressing the permeation of sand while allowing water to permeate. doing.

Therefore, at the time of rainfall, the rainwater that has fallen on the surface layer 12 of the ground 10 is temporarily stored in the plant layer 24 and the columnar drain 18, and permeates into the ground 10 over time through the plant layer 24 and the columnar drain 18. Will be done. As a result, rainwater flowing into the sewer can be peak-cut.

(Action during an earthquake)
On the other hand, at the time of an earthquake, the pore water pressure rises in the liquefied layer 14 of the ground 10 to generate excess pore water. Here, since the columnar drain 18 is provided in the ground 10, excess pore water around the columnar drain 18 flows into the columnar drain 18 and flows into the columnar drain 18 as shown by an arrow P in FIG. Rise.

Here, since the root 28A of the plant 28 constituting the plant layer 24 provided on the columnar drain 18 has a property of allowing water to permeate, the excess pore water raised in the columnar drain 18 is the plant layer 24. Is drained onto the surface layer 12 of the ground 10. As a result, the increase in pore water pressure in the ground 10 is suppressed.

Further, when the excess pore water rises in the columnar drain 18, the soil particles in the ground 10 become sandblasts together with the excess pore water and rise in the columnar drain 18. However, since the root 28A of the plant 28 constituting the plant layer 24 provided on the columnar drain 18 has a property of suppressing the permeation of sand, the soil particles rising in the columnar drain 18 are the plant layer 24. The sand jet from the top end 18A of the columnar drain 18 is suppressed.

As described above, the increase in pore water pressure in the ground 10 is suppressed around the columnar drain 18. As a result, as shown in FIG. 2, a liquefaction suppressing region 36 in which the liquefaction of the liquefaction layer 14 of the ground 10 is suppressed is formed around the columnar drain 18. The range in which the liquefaction suppression region 36 is formed in the ground 10 is determined by the diameter of the columnar drain 18 and the geology of the ground 10.

On the other hand, since the area around the liquefaction suppression region 36 is separated from the columnar drain 18, excess pore water generated in the liquefaction layer 14 does not easily flow into the columnar drain 18, and the pore water pressure in the ground 10 rises to become liquid. Liquefaction is likely to occur. Therefore, as shown by the arrow Q in FIG. 2, a force is applied to the surface layer 12 of the ground 10 in the vertical direction, that is, in the direction in which the surface layer 12 rises, due to the excess pore water and the sandblast.

Here, in the present embodiment, the plant layer 24 is hung between the adjacent columnar drains 18. Further, the steel pipe 32 of the holding means 30 is driven around the columnar drain 18, and the holding member 34 of the holding means 30 is locked to the plant layer 24.

Therefore, when a vertical upward force Q is applied to the plant layer 24, as shown by an arrow S in FIG. 2, the frictional force between the columnar drain 18 and the ground 10 around the columnar drain 18 causes the steel pipe 32 of the holding means 30 to have a force Q. A force that resists the force Q is applied. As a result, the pulling out of the holding means 30 is suppressed, and the lifting of the plant layer 24 is suppressed by the holding means 30 on the columnar drain 18.

Further, by pressing the surface layer 12 of the ground 10 by the root 28A of the plant 28 of the plant layer 24 whose both ends are held on the columnar drain 18 (liquefaction suppression region 36), unevenness such as uplift of the ground 10 is reduced. To. That is, a non-landing reduction region 38 in which the non-landing of the ground 10 is reduced is formed around the liquefaction suppression region 36. The range in which the non-land reduction region 38 is formed in the ground 10 is determined by the pressure resistance (strength) of the root 28A of the plant 28 constituting the plant layer 24.

(effect)
As described above, according to the present embodiment, a plurality of columnar drains 18 are arranged in two horizontal directions at intervals in the ground 10, and plants are placed on the columnar drains 18 on the surface layer 12 of the ground 10. A layer 24 is provided. Therefore, the liquefaction of the liquefaction layer 14 of the ground 10 can be suppressed by draining the excess pore water onto the surface layer 12 of the ground 10 through the columnar drain 18 at the time of an earthquake.

In addition, the root 28A of the plant 28 of the plant layer 24, which has a filter effect of suppressing the permeation of sand while allowing water to permeate, dissipates excess pore water pressure at an early stage while ejecting sand from the top end 18A of the columnar drain 18. It can be suppressed.

In this way, by providing the plant layer 24 on the surface layer 12 of the ground 10, the rainwater storage function (peak cut) during rainfall is compared with the conventional configuration in which the covering layer is provided by paving the surface layer 12. Function) and the function of suppressing blasting during an earthquake can be combined.

Further, since the plant 28 constituting the plant layer 24 has a self-renewal ability, even if a part of the plant is damaged, it is naturally repaired. Therefore, as compared with the conventional configuration in which the coating layer is provided by paving the surface layer 12, the plant layer 24 can be easily maintained, and the plant layer 24 can be partially repaired or stepwise after the occurrence of liquefaction due to an earthquake. Recovery is also easy.

Further, according to the present embodiment, since the plant layer 24 is planar, the plant layer 24 is provided as compared with a configuration in which the plant layer 24 is provided on the columnar drain 18 in a dotted or linear manner. The pressure resistance (strength) of the root 28A of the constituent plant 28 can be increased. Therefore, by pressing the ground 10 by the root 28A of the plant 28 constituting the plant layer 24, it is possible to suppress the non-landing of the ground 10 at the time of liquefaction between the columnar drains 18, and the installation interval of the columnar drains 18 can be increased. It can be made wider (reduce the number of installations).

Further, according to the present embodiment, the plant layer 24 is held on the columnar drain 18 by the holding means 30. As a result, the floating of the plant layer 24 at the time of liquefaction can be suppressed, and the lateral flow of the liquefied ground can be suppressed by pressing the ground 10 by the root 28A of the plant 28.

In particular, according to the present embodiment, the steel pipe 32 driven into the ground 10 around the columnar drain, that is, the liquefaction suppressing region 36, and the pressing member 34 provided above the steel pipe 32 and locked to the plant layer 24. , Consists of the holding means 30.

Therefore, when the ground 10 is liquefied, the pulling out of the steel pipe 32 is suppressed by the frictional force S between the liquefaction suppressing region 36 and the ground 10, so that the floating of the plant layer 24 can be suppressed. The holding means 30 of the present embodiment is particularly suitable when the ground 10 is relatively hard and a sufficient frictional force S can be secured on the ground 10 around the columnar drain 18.

<Second Embodiment>
Next, the liquefaction suppression structure of the ground according to the second embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

In the first embodiment, the columnar drain 18 is composed of the drain hole 20 and the drain material 22, and the steel pipe 32 of the holding means 30 is driven around the columnar drain 18 on the surface layer 12 of the ground 10. On the other hand, in the present embodiment, as shown in FIG. 3, the columnar drain 48 is composed of the steel pipe 42 and the drain material 22 filled in the steel pipe 42, and the steel pipe 42 constituting the columnar drain 48 is formed. , Consists of a holding means 50 for holding the plant layer 24.

The steel pipe 42 extends vertically into the ground 10, the lower end reaches the non-liquefaction layer 16, and the upper end penetrates the sand layer 26 of the plant layer 24 provided on the surface layer 12 of the ground 10. And extends to the bottom of the plant 28.

Similar to the first embodiment, a pressing member 34 composed of a plurality of wire rods is provided at the upper end of the steel pipe 42, and the pressing member 34 is locked to the plant 28 of the plant layer 24. Further, a plurality of holes 42A are formed on the outer peripheral surface of the steel pipe 42 so that water can flow in and out of the steel pipe 42 from the outside of the steel pipe 42.

According to the present embodiment, as in the first embodiment, the plant layer 24 is held on the columnar drain 48 by pressing the plant 28 from above by the pressing member 34 of the holding means 50. As a result, the floating of the plant layer 24 at the time of liquefaction can be suppressed, and the lateral flow of the liquefied ground can be suppressed by pressing the ground 10 by the root 28A (see FIG. 2) of the plant 28.

In particular, according to the present embodiment, since the lower end of the steel pipe 42 of the holding means 50 reaches the non-liquefaction layer 16, the frictional force S between the ground 10 and the steel pipe 42 can be increased. As a result, the pulling out of the steel pipe 42 can be further suppressed, and the lifting of the plant layer 24 can be further suppressed by the holding means 50.

Further, since the columnar drain 48 is composed of the steel pipe 42, the strength of the columnar drain 48 can be increased as compared with the columnar drain 18 of the first embodiment, and the risk of the columnar drain 48 breaking during an earthquake is reduced. can do.

Further, since the steel pipe 42 constituting the columnar drain 48 is also used as the holding means 50, the number of members can be reduced as compared with the configuration in which the holding means 50 is provided separately from the steel pipe 42 forming the columnar drain 48. it can. The holding means 50 of the present embodiment is particularly suitable when the ground 10 is soft and a sufficient frictional force S cannot be secured on the ground 10 around the columnar drain 48.

<Third Embodiment>
Next, the liquefaction suppression structure of the ground according to the third embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

In the first embodiment, the holding means 30 is composed of the steel pipe 32 and the pressing member 34 provided on the upper portion of the steel pipe 32, whereas in the present embodiment, the ground 10 is as shown in FIG. The holding means 60 is composed of the structure 58 provided above.

The structure 58 is, for example, a bench installed on the plant 28 of the plant layer 24, and has a weight sufficient to hold down the plant layer 24, that is, a weight capable of resisting a vertical upward force Q (see FIG. 2). have.

By constructing the structure 58 with a material that allows water to permeate, for example, gravel, excess pore water can be drained from the top end 18A of the columnar drain 18 through the structure 58. Is preferable. Further, for example, the structure 58 may be bound to the top end portion 18A of the columnar drain 18 by a binding member (not shown).

According to the present embodiment, the plant layer 24 can be held on the top end 18A of the columnar drain 18 by pressing the plant 28 of the plant layer 24 from above by the holding means 60. As a result, the floating of the plant layer 24 at the time of liquefaction can be suppressed, and the lateral flow of the liquefied ground can be suppressed by pressing the ground 10 by the root 28A (see FIG. 2) of the plant 28.

In particular, according to the present embodiment, since the holding means 60 is composed of the structure 58 installed on the ground 10, the holding means 60 can be used as a bench or the like. Further, since the floating of the plant layer 24 can be suppressed only by installing the structure 58 on the ground 10, it is compared with the configuration in which the steel pipes 32 and 42 are driven into the ground 10 as in the first and second embodiments. Therefore, the construction becomes easy.

<Fourth Embodiment>
Next, the liquefaction suppression structure of the ground according to the fourth embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

In the first embodiment, the holding means 30 is composed of the steel pipe 32 and the pressing member 34 provided on the upper part of the steel pipe 32. On the other hand, in the present embodiment, as shown in FIG. 5, a plurality of anchors 66 driven into the surface layer 12 of the ground 10 around the columnar drain 18 and a connecting member 68 for connecting the anchors 66 to each other hold the anchors 66. Means 70 are configured.

The plurality of anchors 66 are arranged in two horizontal directions (arrow X direction and arrow Y direction in FIG. 5) at predetermined intervals in the liquefaction suppression region 36 (see FIG. 2) formed around the columnar drain 18. They are arranged in a grid pattern in a plan view.

Further, the lower end of the anchor 66 is driven into the surface layer 12 of the ground 10, and the upper end is exposed on the sand layer 26 of the plant layer 24. On the other hand, the connecting member 68 is, for example, a wire, and connects the upper ends of the anchors 66 exposed on the sand layer 26 to each other.

According to the present embodiment, a plurality of anchors 66 are driven into the ground 10, and a connecting member 68 for connecting the anchors 66 to each other is locked to the plant layer 24, whereby the plant layer 24 is pressed by the holding means 70 and the columnar drain 18 is used. Can be held on.

Further, when the ground is liquefied, the pulling out of the plurality of anchors 66 is suppressed by the sum of the frictional forces T with the ground 10 around the columnar drain 18, so that the floating of the plant layer 24 can be suppressed. .. As a result, the lateral flow of the liquefied ground can be suppressed by pressing the ground 10 by the root 28A (see FIG. 2) of the plant 28 of the plant layer 24.

In particular, according to the present embodiment, since a plurality of anchors 66 are used as the holding means 70, the surface layer 12 of the ground 10 is reached as compared with the case where the steel pipes 32 and 42 are used as in the first and second embodiments. The anchor 66 can be easily driven in, and the workability can be improved. Further, since a plurality of anchors 66 are driven into the liquefaction suppressing region 36 (see FIG. 2) of the ground 10, it is possible to prevent the holding means 70 (anchor 66) from floating together with the plant layer 24.

<Other Embodiments>
Although the first to fourth embodiments of the present invention have been described above, the present invention is not limited to such embodiments, and various other embodiments are possible within the scope of the present invention. In addition, the configurations of each embodiment can be combined as appropriate.

For example, in the first embodiment, the holding means 30 is composed of the steel pipe 32 and the pressing member 34 provided on the upper part of the steel pipe 32. However, as shown in FIG. 6A, the wire 76 whose lower end is fixed to the bottom end (non-liquefaction layer 16) of the columnar drain 18 and the pressing member 78 joined to the upper end of the wire 76 , The holding means 80 may be configured.

According to the configuration shown in FIG. 6A, the wire 76 of the holding means 80 is inserted into the columnar drain 18, and the lower end thereof is fixed to the bottom end portion of the columnar drain 18 by, for example, a root hardening liquid 82 or the like. .. As a result, the pressing member 78 can be locked to the plant layer 24 without using a steel pipe or the like, and the holding means 80 can suppress the floating of the plant layer 24.

Further, for example, by combining the configurations of the second embodiment and the fourth embodiment, as shown in FIG. 6B, a plurality of anchors 66, a connecting member 68 for connecting the anchors 66 to each other, and a columnar drain 48 can be provided. The holding means 90 may be formed by the steel pipe 42 to be formed.

According to the configuration shown in FIG. 6B, the connecting member 68 for connecting the anchors 66 to each other is joined to the upper end surface of the steel pipe 42. Therefore, the pulling out of the holding means 90 is suppressed by the sum of the frictional force T between the surrounding ground 10 and the plurality of anchors 66 and the frictional force S between the surrounding ground 10 and the steel pipe 42.

As a result, for example, even if the surface layer 12 of the ground 10 is soft and the frictional force T of the anchor 66 alone cannot sufficiently resist the upward force Q (see FIG. 2) in the vertical direction, the plant layer 24 is provided by the holding means 90. It is possible to suppress the floating of the.

Further, for example, in the first embodiment, a plurality of columnar drains 18 arranged in two horizontal directions are covered with a planar plant layer 24. However, the plant layer 24 may be configured to cover at least the top end portion 18A of the columnar drain 18, and may be provided in a dot shape or a linear shape on the surface layer 12 of the ground 10. Further, although the plurality of columnar drains 18 are arranged in a grid pattern in two horizontal directions in a plan view, the columnar drains 18 may be arranged in a staggered pattern in a two horizontal directions in a plan view.

10 Ground 12 Surface layer 18, 48 Columnar drain 24 Plant layer 30, 50, 60, 70, 80, 90 Holding means 32, 42 Steel pipe 34, 78 Holding member 66 Anchor 68 Connecting member

Claims (3)

Columnar drains provided in the ground and
A plant layer provided on the surface layer of the ground and covering the columnar drain,
A holding means for holding the plant layer on the columnar drain,
Liquefaction suppression structure of the ground. The holding means is
A steel pipe driven around the columnar drain and
A pressing member provided on the upper part of the steel pipe and locked to the plant layer,
The liquefaction suppressing structure of the ground according to claim 1. The holding means is
A plurality of anchors driven into the surface layer of the ground around the columnar drain,
A connecting member that connects a plurality of the anchors and is locked to the plant layer,
The liquefaction suppressing structure of the ground according to claim 1.