JP6763221B2 - Reinforcement structure of embankment - Google Patents

Description

The present invention relates to a reinforcing structure for embankments such as coasts and rivers, coasts such as roads and railway embankments, and embankments extending long along rivers, roads, railways and the like.

As an example of the reinforcing structure of the embankment, the one described in Patent Document 1 is known. In this reinforcement structure of the embankment, steel sheet piles or steel pipe sheet piles are arranged in the vicinity of the buttock on the left and right sides of the embankment or the vicinity of the center of the slope, and the vicinity of the head is connected and reinforced with a connecting material such as a tie rod.

Further, as an example of a method for reinforcing a retaining wall constructed by using a plurality of steel sheet piles, the one described in Patent Document 2 is known. The method of reinforcing the earth retaining wall is to form a main body of the earth retaining wall, a buttress projecting from the back side of the main body of the earth retaining wall, and a bearing wall projecting from the buttress substantially parallel to the main body of the earth retaining wall. It is a method of reinforcing the earth retaining wall including the earth pressure retaining material, and the earth pressure counter material is laid so as to connect a plurality of steel sheet piles constituting the earth retaining wall main body to each other. In this way, the steel sheet piles constituting the earth retaining wall main body are integrated with each other via the earth pressure counter material, and the rotation of the steel sheet piles generated when the earth pressure of the ground is applied can be suppressed.

Japanese Unexamined Patent Publication No. 2003-13451 JP-A-2010-126991

However, in the reinforcement structure of the embankment described in Patent Document 1, since it is necessary to carry out the construction by penetrating the inside of the embankment with a connecting material such as a tie rod, a large amount of construction is carried out when the embankment width (fill width) is large. There is concern that it will be costly. In addition, if there is a track at the top of the embankment in the railway embankment, there is concern about the impact on the track, which makes construction difficult during track operation, and the construction time is limited and the construction period becomes longer, resulting in higher construction costs. There is also concern that it will increase.

On the other hand, the method of reinforcing the retaining wall described in Patent Document 2 resists the earth pressure acting on the retaining wall body by the bearing wall via the buttress, so that the bearing wall must be constructed. is necessary. In addition, the buttress is positioned as a connecting material that connects the retaining wall body to the bearing wall, and the buttress does not suppress the deformation of the retaining wall body.

Therefore, the present inventor does not use a connecting material such as a tie rod for a steel wall made of a steel sheet pile or the like embedded in the buttock portion of the embankment (referring to the buttock portion or its vicinity) in the reinforcement structure of the embankment. As a result of diligent research on reinforcement, we have obtained the following findings.
That is, in the event of an earthquake, a steel wall made of steel sheet piles or the like buried in the buttock portion has a fixed point at the lower end and behaves so that the upper end opens outward following the deformation of the embankment (fill). When the upper end of the steel wall opens outward, the embankment (embankment) sinks and deforms accordingly. Therefore, suppressing this "opening" as much as possible directly leads to the suppression of damage to the embankment (embankment).

In order to suppress such "opening", it was found that the performance (flexural rigidity) is dramatically improved by installing a steel wall in the direction perpendicular to the steel wall in the direction perpendicular to the steel wall. (See Tables 1 to 3).

表１に示すハット形鋼矢板は直角方向鋼製壁を構成するものである。
なお、ハット形鋼矢板１０Ｈ〜５０Ｈは、Ｈの係数が大きくなるほど、ハット形鋼矢板の有効高さおよび厚さが大きくなっている。
また、ｘ周りとは、ハット形鋼矢板の断面において、重心がある高さ位置にて、ハット形鋼矢板の幅方向に延びるｘ軸周りのことであり、ｙ周りとは、ハット形鋼矢板の断面重心にてｘ軸と直角方向、つまり、ハット形鋼矢板の高さ方向に延びるｙ軸周りのことである。

The hat-shaped steel sheet pile shown in Table 1 constitutes a right-angled steel wall.
In the hat-shaped steel sheet piles 10H to 50H, the larger the coefficient of H, the larger the effective height and thickness of the hat-shaped steel sheet pile.
Further, the x circumference is the x-axis circumference extending in the width direction of the hat-shaped steel sheet pile at a height position where the center of gravity is located in the cross section of the hat-shaped steel sheet pile, and the y circumference is the hat-shaped steel sheet pile. It is around the y-axis extending in the direction perpendicular to the x-axis in the cross-sectional center of gravity of

In Tables 2 and 3, "per depth of 9 m" means a section having a length of 9 m in the continuous direction of the embankment. Therefore, for example, one sheet (two sheets) per depth of 9 m means that one sheet (two sheets) is installed in a section having a length of 9 m in the continuous direction of the embankment, and steel sheet piles constituting the steel wall in the perpendicular direction are installed. ..
In addition, the numerical values in Table 3 are the steel reinforced by the steel sheet piles constituting the steel wall in the perpendicular direction to the case where the moment of inertia of area of the steel wall provided at the embankment is set to "1". The moment of inertia of area of the wall is shown for each type and number of steel sheet piles.

Assuming that the amount of embankment subsidence and the moment of inertia of area (averaged in the depth direction) of the steel sheet pile are in a linear relationship, the amount of embankment subsidence can be halved for the number of steel sheet piles installed in the direction perpendicular to the extension of the embankment. ,
Hat-shaped steel sheet pile 10H: 1 sheet at 9m depth intervals,
Hat-shaped steel sheet pile 25H: 2 sheets at 9m depth intervals,
Hat-shaped steel sheet pile 45H: 3 sheets at 9m depth intervals,
Hat-shaped steel sheet pile 50H: 3 sheets at 9m depth intervals,
It turns out that it is necessary.
From the above, by installing a steel wall in the direction perpendicular to the steel wall in the direction perpendicular to the steel wall, the performance (flexural rigidity) will increase dramatically, and the embankment will be deformed (sink) during an earthquake. ) Can be suppressed.

The present invention has been made based on the above-mentioned findings, and a steel wall made of steel sheet piles or the like embedded in the buttock portion of the embankment is reinforced without using a connecting material such as a tie rod to embankment during an earthquake. It is an object of the present invention to provide a reinforcing structure of embankment that can suppress the deformation of the embankment.

In order to achieve the above object, in the reinforcement structure of the embankment of the present invention, a steel wall is provided at the buttock portion of the continuous embankment along the continuous direction of the embankment.
It is characterized in that the right-angled steel walls extending in the direction perpendicular to the steel wall and in the direction away from the embankment are discretely arranged in the continuous direction of the embankment.

Here, the buttock portion means a buttock or a vicinity thereof, and the steel wall may be provided on the slope side of the buttock or outside the buttock.

In the present invention, the right-angled steel walls extending in the direction perpendicular to the steel wall provided at the end of the embankment and in the direction away from the embankment are discretely arranged in the continuous direction of the embankment. Therefore, not only the bending rigidity of the steel wall but also the bending resistance of the steel wall in the perpendicular direction can be expected. Therefore, the steel wall buried in the buttock of the embankment can be reinforced without using a connecting material such as a tie rod, and the deformation of the embankment during an earthquake can be suppressed.

In the configuration of the present invention, the steel wall and the right-angled steel wall may be connected by their heads.

According to such a configuration, the continuous steel wall along the embankment and the right-angled steel wall arranged in the perpendicular direction are integrated, so that the resistance to bending deformation is remarkably increased and the embankment Deformation can be further suppressed.

Further, in the configuration of the present invention, the steel wall and the right-angled steel wall may be connected by a joint.

According to such a configuration, the shear resistance of the joint of the steel wall and the right-angled steel wall is also exhibited, the resistance force against bending deformation is further increased, and the deformation of the embankment can be effectively suppressed.

Further, in the configuration of the present invention, the top end of the steel wall may be located on a slope located below a height position of 1/2 of the height of the embankment.

According to such a configuration, when there is a track at the top of the railway embankment or the like, the influence of construction can be suppressed. In addition, there is an advantage that the construction cost can be reduced because the construction can be carried out even during the track business and the construction time can be sufficiently secured.

Further, in the above-mentioned configuration of the present invention, the top end of the right-angled steel wall may be located below the ground surface.

According to such a configuration, the steel wall in the perpendicular direction does not protrude from the ground surface in and near the embankment, which leads to consideration for the surrounding environment. Further, it is not necessary to widen the embankment slope to cover the steel wall in the perpendicular direction, and the reinforcing structure can be easily constructed even if the embankment slope is relatively close to the surrounding structure or the site boundary.

Further, in the configuration of the present invention, the right-angled steel wall may be installed in the ground so as to straddle the liquefied ground and the non-liquefied ground.

According to such a configuration, for a steel wall provided along the continuous direction of the embankment, the maximum stress generation position at the time of an earthquake is the layer boundary between the liquefied layer and the non-liquefied layer, such as a model experiment. Since it is known from the above, stress can be reduced by reinforcing the position with a steel wall in the perpendicular direction.

According to the present invention, not only the bending rigidity of the steel wall provided at the bottom of the embankment but also the bending resistance of the steel wall in the perpendicular direction can be expected. Therefore, the steel wall buried in the buttock of the embankment can be reinforced without using a connecting material such as a tie rod, and the deformation of the embankment during an earthquake can be suppressed.

It is a perspective view which shows typically the reinforcement structure of the embankment which concerns on 1st Embodiment of this invention. It is a front sectional view schematically showing the reinforcement structure of the embankment which concerns on the 2nd Embodiment of this invention. It is a front sectional view which shows typically the reinforcement structure of the embankment which concerns on 3rd Embodiment of this invention. It is a plan sectional view which shows the main part of the reinforcement structure of the embankment which concerns on 3rd Embodiment of this invention. It is a front sectional view schematically showing the reinforcement structure of the embankment which concerns on 4th Embodiment of this invention. It is a front sectional view which shows typically the reinforcement structure of the embankment which concerns on 5th Embodiment of this invention. It is a front sectional view schematically showing the reinforcement structure of the embankment which concerns on the 6th Embodiment of this invention. It is for demonstrating the model experiment which concerns on this invention, and is the right sectional view which shows the schematic structure of the model embankment. It is a graph which shows the depth distribution of the bending strain of the steel sheet pile of the method tail in the vibration experiment. It shows the main part of the reinforcement structure of the embankment which concerns on embodiment of this invention, and is the plan sectional view which shows the state which connected the steel continuous wall as a right-angled steel wall with the steel wall.

Hereinafter, embodiments of the embankment reinforcement structure according to the present invention will be described with reference to the drawings.
In each of the following first to sixth embodiments, the right-angled steel wall 3 extends in the direction perpendicular to the steel wall 2 provided on one of the embankment 1's ridges 1c. However, in reality, it is preferable that the right-angled steel wall 3 is provided on both of the embankments 1 at the tail portions 1c. Further, the right-angled steel wall 3 may be provided on one of the buttock portions 1c of the embankment 1.

(First Embodiment)
FIG. 1 is a perspective view schematically showing a reinforcing structure of the embankment according to the first embodiment.
In the present embodiment, the steel wall 2 is provided along the continuous direction of the embankment 1 on the buttock portion 1c of the continuous embankment 1. The steel wall 2 is formed by connecting a plurality of steel sheet piles or steel pipe sheet piles. The top end 2c of the steel wall 2 is located on the ground surface in the vicinity of the buttock portion 1c of the embankment 1.

Further, the right-angled steel walls 3 extending in the direction perpendicular to the steel wall 2 and in the direction away from the embankment 1 are discretely arranged in the continuous direction of the embankment 1. In FIG. 1, two right-angled steel walls 3 are arranged apart from each other in the continuous direction of the embankment 1, but three or more right-angled steel walls 3 are arranged at predetermined intervals in the continuous direction of the embankment 1. It may be arranged discretely. The intervals between the right-angled steel walls 3 and 3 adjacent to each other in the continuous direction of the embankment 1 may be the same, or may be appropriately changed depending on the position of the embankment 1 in the continuous direction.
Further, the tip edges of the right-angled steel walls 3 and 3 along the vertical direction are in contact with the back surface of the steel wall 2, but they may be connected by a joint or the like, or the right-angled steel walls 3 and 3 may be connected. There may be a predetermined gap between the tip edge of 3 and the back surface of the steel wall 2.

According to the present embodiment, the steel wall 3 in the orthogonal direction extending in the direction perpendicular to the steel wall 2 provided in the ridge portion 1c of the embankment 1 and in the direction away from the embankment 1 is continuous with the embankment 1. Since they are arranged discretely in the direction, not only the bending rigidity of the steel wall 2 but also the bending resistance of the steel wall 3 in the perpendicular direction can be expected. Therefore, the steel wall 2 embedded in the buttock portion 1c of the embankment 1 can be reinforced without using a connecting material such as a tie rod, and the deformation of the embankment at the time of an earthquake can be suppressed.

(Second Embodiment)
FIG. 2 is a cross-sectional view schematically showing a reinforcing structure of the embankment according to the second embodiment.
The difference between the embankment reinforcement structure according to the first embodiment and the embankment reinforcement structure according to the first embodiment is that the steel wall 2 and the perpendicular steel wall 3 are joined by their heads. Since there are some points, this point will be described below, and the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted or simplified.

In the present embodiment, the right-angled steel wall 3 is formed by three steel sheet piles 3a, and the three steel sheet piles 3a are in contact with each other.
Further, the heads of the three steel sheet piles 3a and the heads of the steel wall 2 are joined by the joint portion 5. The joint portion 5 connects all the heads of the three steel sheet piles 3a and connects the heads to the heads of the steel wall 2, but the steel sheet piles constituting the steel wall 3 in the perpendicular direction When the number of sheets of 3a is large, the heads of a predetermined number of steel sheet piles 3a close to the steel wall 2 and the heads of the steel walls 2 may be joined.
As the joint portion 5, cap concrete or shaped steel may be used. In the case of cap concrete, cast-in cap concrete may be used, or precast cap concrete may be used. In the case of shaped steel, H-shaped steel is preferably used, but other shaped steels may be used. The joint portion 5 formed of shaped steel is joined to the head of the steel sheet pile 3a and the head of the steel wall 2 by welding or the like.

According to the present embodiment, the same effect as that of the first embodiment can be obtained, and the head of the steel wall 2 continuous along the embankment 1 and the right-angled steel arranged in the perpendicular direction. Since the head of the wall 3 is integrated with the joint portion 5, the resistance to bending deformation is remarkably increased, and the deformation of the embankment 1 can be further suppressed.

(Third Embodiment)
FIG. 3 is a cross-sectional view schematically showing a reinforcing structure of the embankment according to the third embodiment.
The embankment reinforcement structure according to the first embodiment is different from the embankment reinforcement structure according to the first embodiment in that the steel wall 2 and the perpendicular steel wall 3 are connected by a joint. Therefore, this point will be described below, and the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted or simplified.

In the present embodiment, as in the second embodiment, the perpendicular direction steel wall 3 is formed by three steel sheet piles 3a, and among these three steel sheet piles 3a, the steel wall 2 The steel sheet pile 3a on the closest side is connected to the steel wall 2 by the joints 3b and 2b.
Specifically, as shown in FIG. 3A, a joint projecting toward the steel sheet pile 3a side is provided on the web of the steel sheet pile 2a that constitutes the steel wall 2 and to which the steel wall 3 in the perpendicular direction is to be connected. 2b is fixed by welding or the like, and the joint 3b provided at one end of the steel sheet pile 3a is engaged with the joint 2b. The steel wall 2 and the steel wall 3 in the perpendicular direction are connected by the engagement of the joints 2b and 3b. Further, the adjacent steel sheet piles 3a may be joined by the same joint as the joint 3b.

In the present embodiment, the joints 2b and 3b are formed over the entire length of the steel sheet piles 2a and 3a in the depth direction, but are not necessarily formed over the entire length in the depth direction.
When the steel wall 2 is composed of a plurality of steel pipe sheet piles, the steel sheet pile 3a joint 3b is inserted into the C-shaped joint of the steel pipe sheet pile, and the C-shaped joint is filled with mortar. The steel wall 2 and the steel wall 3 in the perpendicular direction may be combined with each other.

According to the present embodiment, the same effect as that of the first embodiment can be obtained, and the shear resistance of the joints 2b and 3b of the steel wall 2 and the right-angled steel wall 3 is also exhibited, resulting in bending deformation. The resistance to the embankment 1 is further increased, and the deformation of the embankment 1 can be effectively suppressed.

(Fourth Embodiment)
FIG. 4 is a cross-sectional view schematically showing a reinforcing structure of the embankment according to the fourth embodiment.
The difference between the embankment reinforcement structure according to the first embodiment and the embankment reinforcement structure according to the first embodiment is that the top end 3c of the right-angled steel wall 3 is 1/2 of the height H of the embankment 1. Since it is a point located on the slope 1b located below the height H / 2 position of the above, this point will be described below, and the same components as those in the first embodiment are designated by the same reference numerals. The explanation is omitted or simplified.

In the present embodiment, the steel wall 2 provided along the continuous direction of the embankment 1 intersects the slope 1b at a position closer to the top end side than the embankment 1's buttock in the vicinity of the embankment 1's buttock. The top end 2c of the steel wall 2 is located on the slope 1b located below the height H / 2 position, which is 1/2 the height H of the embankment 1. There is. Further, the portion of the embankment 1 outside the steel wall 2 has been removed.
Then, the right-angled steel walls 3 extending in the direction perpendicular to the steel wall 2 and in the direction away from the embankment 1 are arranged discretely in the continuous direction of the embankment 1 (the direction orthogonal to the paper surface in FIG. 4). Has been done.
The right-angled steel wall 3 is formed of three steel sheet piles 3a as in the second and third embodiments, and the top end 3c of the right-angled steel wall 3 made of these steel sheet piles 3a is formed. It is aligned with the top end 2c of the steel wall 2. Therefore, since the steel wall 3 in the perpendicular direction protrudes from the ground surface, the protruding portion may be cut at the same position as the ground surface, or the embankment 1 may be widened and filled.

According to the present embodiment, the same effect as that of the first embodiment can be obtained, and the influence of construction can be suppressed when there is a track at the top of the railway embankment or the like. In addition, there is an advantage that the construction cost can be reduced because the construction can be carried out even during the track business and the construction time can be sufficiently secured.

(Fifth Embodiment)
FIG. 5 is a cross-sectional view schematically showing a reinforcing structure of the embankment according to the fifth embodiment.
The difference between the embankment reinforcement structure according to the fourth embodiment and the embankment reinforcement structure according to the fourth embodiment is that the top end 3c of the right-angled steel wall 3 is located below the ground surface. Therefore, this point will be described below, and the same components as those in the fourth embodiment are designated by the same reference numerals, and the description thereof will be omitted or simplified.

In the present embodiment, as in the fourth embodiment, the steel wall 2 provided along the continuous direction of the embankment 1 intersects the slope 1b of the embankment 1 in the vicinity of the buttock of the embankment 1. It is buried vertically in this way, and the top end 2c of the steel wall 2 is located on the slope 1b located below the height H / 2 position, which is 1/2 the height H of the embankment 1. ..
On the other hand, the top end 3c of the right-angled steel wall 3 extending in the direction perpendicular to the steel wall 2 and in the direction away from the embankment 1 is located below the ground surface. Therefore, since the right-angled steel wall 3 does not protrude from the ground surface, it is not necessary to cut the protruding portion or widen the embankment 1 unlike the fourth embodiment.

According to the present embodiment, the same effect as that of the fourth embodiment can be obtained, and the steel wall 3 in the perpendicular direction does not protrude from the ground surface of the embankment 1 and its vicinity, so that the surrounding environment It leads to consideration for. Further, it is not necessary to widen the slope 1b of the embankment 1 to cover the steel wall 3 in the perpendicular direction, and the reinforcing structure can be easily constructed even if the slope 1b of the embankment 1 is relatively close to the surrounding structure or the site boundary.

(Sixth Embodiment)
FIG. 6 is a cross-sectional view schematically showing a reinforcing structure of the embankment according to the sixth embodiment.
The difference between the embankment reinforcement structure according to the fifth embodiment and the embankment reinforcement structure according to the fifth embodiment is that the perpendicular steel wall 3 is liquefied ground (liquefaction layer) 10 in the ground. Since it is installed so as to straddle the non-liquefied ground (non-liquefied layer) 11, this point will be described below, and the same components as those in the fifth embodiment are designated by the same reference numerals. The explanation is omitted or simplified.

In the present embodiment, as in the fifth embodiment, the steel wall 2 provided along the continuous direction of the embankment 1 intersects the slope 1b of the embankment 1 in the vicinity of the buttock of the embankment 1. It is buried vertically in this way, and the top end 2c of the steel wall 2 is located on the slope 1b located below the height H / 2 position, which is 1/2 the height H of the embankment 1. .. Further, the lower end portion of the steel wall 2 is installed in the ground so as to straddle the liquefied ground (liquefied layer) 10 and the non-liquefied ground 11 (non-liquefied layer). Further, the top end 2c of the steel wall 2 may be located near the buttock portion 1c of the embankment 1.

On the other hand, the top end 3c of the right-angled steel wall 3 extending in the direction perpendicular to the steel wall 2 and in the direction away from the embankment 1 is located below the ground surface and is made of right-angled steel. The lower end of the wall 3 is installed in the ground so as to straddle the liquefied ground (liquefied layer) 10 and the non-liquefied ground (non-liquefied layer) 11.
Further, of the three steel sheet piles 3a constituting the right-angled steel wall 3, the steel sheet pile 3a on the side closest to the steel wall 2 has a longer vertical length than the remaining two steel sheet piles 3a. There is. Further, since the lower ends of the steel sheet piles 3a are aligned with the remaining two steel sheet piles 3a, the steel sheet piles 3a project upward from the remaining two steel sheet piles 3a.

According to this embodiment, with respect to the steel wall 2 provided along the continuous direction of the embankment 1, the maximum stress generation position at the time of an earthquake is liquefied ground (liquefied layer) 10 and non-liquefied ground (non-liquid). Since it is known from model experiments and the like that it is the layer boundary of the liquefaction layer) 11, stress can be reduced by reinforcing the position with the steel wall 3 in the perpendicular direction.

Next, the model experiment will be described with reference to FIGS. 7 and 8.
A vibration experiment was conducted on a model embankment in which a steel sheet pile was installed at the bottom of the embankment.
As shown in FIG. 7, the size of the embankment (embankment) is as follows.
Top width: 300 (mm), embankment height: 250 (mm), slope gradient 1: 1.8,
Hojiri sheet pile length: 400 (mm), sheet pile thickness: 2.3 mm
Since this model embankment is assumed to be 1/20 to 1/25 of the full-scale scale, the top width: 7.5 m, the embankment height: 6.25 m, and the sheet pile type 10H, on the full-scale scale. Sheet pile length: about 10 m.
As the vibration waveform, the waveform adjusted for the time scale of the observation wave of the Kobe Marine Meteorological Observatory during the 1995 Hyogo-ken Nanbu Earthquake was used.
The ground physical properties are as follows.
Embankment layer (γ _t ): 16.0 (kN / m ³ )
Liquefied layer (γ _t ): 18.5 (kN / m ³ )
_{(D r): 32.4 (%} )
Compaction layer (γ _t ): 19.7 (kN / m ³ )

FIG. 8 shows the depth distribution of the bending strain of the method tail sheet pile by this vibration experiment. As shown in this figure, it was found that both the maximum value and the residual value during excitation occurred at the boundary between the liquefaction layer and the compaction layer.
The amount of subsidence at the top of the embankment was 67 mm. This is about 5 m when converted to the actual size. Although it is a large value in terms of actual size, it is due to the selection of experimental conditions assuming a large-scale collapse of the embankment.
On the other hand, in the sixth embodiment, the amount of subsidence of the embankment is estimated to be as follows.
Assuming that the steel sheet pile constituting the right-angled steel wall is a hat-shaped steel sheet pile 10H, this hat-shaped steel sheet pile 10H is used.
If one sheet is installed at 9m in the continuous direction of the embankment, the settlement amount will be 2.6m.
If two sheets are installed in the continuous direction of the embankment at 9 m, the amount of subsidence is 1.8 m.
When three sheets are installed in the continuous direction of the embankment at 9 m, the subsidence amount is 1.3 m, and it can be seen that the subsidence amount is considerably smaller than the subsidence amount of 5 m when the perpendicular steel wall is not installed.

In the first to sixth embodiments, the right-angled steel wall 3 is formed of a plurality of steel sheet piles or steel pipe sheet piles, but instead, it may be formed of a continuous steel wall. Examples of the steel continuous wall include, but are not limited to, the steel continuous wall 30 shown in FIG. 9, and other steel continuous walls may be used. Further, the steel wall 2 may also be formed by a continuous steel wall.

The steel continuous wall 30 is formed by joining steel sheet piles 31 having a substantially H-shaped cross section, and joints 32 are provided on both edges of both flanges of the steel sheet piles 31. It is formed.
The steel sheet pile 31 is formed to be elongated in the direction orthogonal to the paper surface in FIG. 9, and the steel sheet pile 31 is buried in the ground with the elongated direction facing the vertical direction, and the joints 32 and 32 are engaged with each other. Then, the steel continuous wall 30 that becomes the orthogonal direction steel wall 3 is constructed.
Then, among the plurality of steel sheet piles 31 constituting the steel continuous wall 30, the joints 32, 32 of the steel sheet pile 31 closest to the steel wall 2 are formed on the steel wall 2, and the joints 2b, 2b are formed. The steel wall 2 and the steel wall 3 in the orthogonal direction are joined by engaging with.

1 Embankment 1b Slope 1c Slope 2 Steel wall 2c Top 2b Fittings 3,30 Right-angle steel wall 3b Fittings 3c Top 5 Joint 10 Liquefied ground 11 Non-liquefied ground

Claims (4)

A steel wall is provided along the continuous direction of the embankment at the buttock of the continuous embankment.
Right-angled steel walls extending in a direction perpendicular to the steel wall and in a direction away from the embankment are discretely arranged in the continuous direction of the embankment .
The top end of the steel wall is located on a slope located below the height position of 1/2 of the height of the embankment, and the portion of the embankment outside the steel wall is removed in the perpendicular direction. A reinforcing structure for embankment, characterized in that a portion of a steel wall protruding from the ground surface is cut at the same position as the ground surface . The reinforcement structure for embankment according to claim 1, wherein the steel wall and the right-angled steel wall are joined by their heads. The reinforcement structure for embankment according to claim 1 or 2, wherein the steel wall and the right-angled steel wall are joined by a joint. The embankment reinforcement structure according to any one of claims 1 to 3 , wherein the right-angled steel wall is installed in the ground so as to straddle the liquefied ground and the non-liquefied ground. ..

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