KR102191879B1 - Segmental retaining wall and method of contructing segmental retaining wall - Google Patents

Abstract

The present invention provides a reinforced earth retaining wall, which includes: a draining block spaced apart from a cut surface by a predetermined distance and extended toward one side; a retaining wall part mounted on the draining block and supporting earth pressure of reinforced earth stacked between the cut surface and the draining block; and a draining part arranged between the retaining wall part and the reinforced earth and extended along a direction in which the reinforced earth is stacked. In the draining block, a drain penetrating in a direction across an extension direction is formed. At least a part of the draining block overlaps the draining part in the direction across the extension direction. The draining part and the drain communicate with each other. Therefore, the reinforced earth retaining wall can easily expand the draining amount.

Description

Construction method of reinforced soil retaining wall and reinforced soil retaining wall {SEGMENTAL RETAINING WALL AND METHOD OF CONTRUCTING SEGMENTAL RETAINING WALL}

The present invention relates to a reinforced soil retaining wall, and more specifically, to a reinforced soil retaining wall having a drainage structure and a construction method of the reinforced soil retaining wall.

Retaining wall is a wall that resists earth pressure and prevents the soil from collapsing. The retaining wall is a structure to prevent the collapse of the ground when the stable slope of the surface ground is steeper than that.

The retaining wall is manufactured to face the cut surface forming a specific slope. In particular, the reinforced soil retaining wall is manufactured in the axial wall method. In other words, concrete blocks are stacked to form a wall. A tension member is placed between the wall and the cut surface. Reinforcement soil is poured together with the tension member between the wall and the cut surface.

Tension members are placed between or connected to the concrete blocks. The tension member is fixed by the reinforced soil, and the concrete block is pulled in the direction opposite to the direction in which the concrete block is subjected to earth pressure.

The back of the wall is filled with rubble. In case of rain, the water flowing into the back of the reinforced soil retaining wall is groundwater and surface water flowing from high to low regions. Most of the water flowing into the rubble layer on the back of the reinforced soil retaining wall is surface water. If the rainfall time increases, groundwater flows in and the groundwater level at the back of the retaining wall rises rapidly.

In this case, the strength of the reinforced soil to fix the tension member is weakened, the shear strength of the reinforced soil is weakened, and hydraulic pressure is applied to the reinforced soil retaining wall, which may cause the reinforced soil retaining wall to be filled or destroyed. In the prior art, a perforated drainage pipe is used to solve this problem.

Prior Art Document 1 (Registration Patent No. 10-1757116) discloses a reinforced soil retaining wall in which a perforated drainage pipe is installed adjacent to a cut surface. The perforated drainage pipe is a drainage pipe with many through holes formed on the outer circumference of the pipe. Rainfall flows in through the through hole, and it is moved through the pipe and drained.

However, when a perforated drainage pipe is used, there is a limit to the amount of drainage that can be drained, and the inner diameter of the pipe must be increased to improve the amount of drainage. In this case, durability problems of the drain pipe may occur, and time and economic difficulties may arise in constructing the reinforced soil retaining wall.

That is, if the inner diameter of the perforated drainage pipe is small, there is a risk that the reinforced soil retaining wall will collapse and fall without withstanding the rainfall of more than 20 years. On the other hand, if the inner diameter of the perforated drain pipe is too large, the durability problem of the perforated drain pipe occurs.

The perforated drainage pipe is installed along the extension direction of the reinforced soil retaining wall on the rear surface of the reinforced soil retaining wall, or is installed below the cut surface as in Prior Art Document 1. Therefore, when damage occurs, technical and economic difficulties may occur in repairing it.

Therefore, there is a need for a reinforced soil retaining wall having a structure in which construction is possible in a short time, construction cost is reduced, and sufficient drainage is performed without problems in durability.

(Prior Technical Document 1) Registered Patent No. 10-1757116 (registered on July 05, 2017)

An object of the present invention is to provide a reinforced soil retaining wall having a structure capable of solving the above-described problems and a construction method thereof.

In addition, an object of the present invention is to provide a reinforced soil retaining wall having a drainage passage having a short distance between the inlet and the outlet of rainfall.

In addition, an object of the present invention is to provide a reinforced soil retaining wall having a drainage passage capable of easily expanding the total cross-sectional area of the drainage passage.

In addition, an object of the present invention is to provide a reinforced soil retaining wall having a structure in which the drainage portion and the drainage passage are in communication with each other to smoothly drain the incoming rainfall.

In addition, it is an object of the present invention to provide a reinforced soil retaining wall having a strong drainage channel by increasing the amount of drainage without expanding the diameter of the drainage channel.

In addition, it is an object of the present invention to provide a reinforced soil retaining wall having a drainage channel that does not affect the total amount of drainage even if a part is damaged by providing a plurality of drainage channels.

In addition, it is an object of the present invention to provide a reinforced soil retaining wall having a drainage passage that is easy to repair.

In order to achieve the above object, the present invention is spaced apart by a predetermined distance from the cut surface, a drainage block extending toward one side; A retaining wall part seated on the drain block and supporting the earth pressure of the reinforced soil stacked between the cut surface and the drain block; And a drainage portion disposed between the retaining wall portion and the reinforcing soil, and extending along a direction in which the reinforcement soil is stacked, wherein a drainage passage passing through the drainage block is formed in a direction crossing the extension direction, and at least of the drainage block A portion of the reinforced soil retaining wall overlaps the drainage portion in a direction crossing the extension direction, and communicates with the drainage portion and the drainage passage.

In addition, the drainage block, the upper end portion in which the drainage passage is formed; A lower part in contact with the ground; And a middle portion connecting the upper portion and the lower portion, and a width of the middle portion may be formed to be narrower than that of the upper portion and the lower portion, based on a direction crossing the extension direction of the drain block.

In addition, the drain passage may be formed in plural along the extending direction.

Further, based on a direction crossing the extension direction of the drain block, the width of the upper end portion may be formed to be wider than the width of the retaining wall portion.

Further, the drainage portion is formed of stacked rubbles, and a filtering portion is installed at one side of the drainage passage in contact with the rubbles, thereby preventing the rubbles from flowing into the drainage passage.

In addition, a drain pipe may be inserted into the drain passage of the drain block.

In addition, in order to achieve the above object, the present invention comprises the steps of: (a) consolidating the foundation surface by being spaced apart from the cut surface by a predetermined distance; (b) installing a drainage block along one direction on the base surface; (c) sequentially pouring and compacting drainage material and reinforcement soil between the drainage block and the cut surface up to the height of the drainage block; (d) installing at least one first retaining wall block on the drainage block; (e) sequentially pouring and compacting drainage material and reinforcement soil up to the height of the first retaining wall block; (f) installing at least one second retaining wall block on the first retaining wall block; (g) sequentially pouring and compacting drainage material and reinforcement soil up to the height of the second retaining wall block; (h) installing at least one other second retaining wall block on the second retaining wall block; (i) sequentially pouring and compacting drainage material and reinforcement soil up to the height of the other second retaining wall block; And (j) repeating steps (h) and (i) to stack a plurality of retaining wall blocks, wherein a drainage passage passing through the drainage block in a direction crossing the one direction is formed, the At least a portion of the drainage block may provide a method of constructing a reinforced soil retaining wall that overlaps with the drainage material in a direction crossing the one direction, and communicates the voids between the drainage material and the drainage passage.

Furthermore, the drainage block may include an upper end portion in which the drainage passage is formed; A lower part in contact with the ground; And a middle portion connecting the upper portion and the lower portion, and a width of the middle portion may be formed narrower than that of the upper portion and the lower portion based on a direction crossing the one direction of the drain block.

Further, the step (c) may include: (c1) pouring and compacting reinforced soil between the drainage block and the cut surface to the height of the middle portion; (c2) pouring and compacting drainage material on the rear surface of the upper end facing the cut surface; And (c3) pouring and compacting reinforcement soil between the drainage material and the cut surface.

In addition, the step (f), (f1) installing a tension member on the first retaining wall block and the reinforcing soil; And (f2) installing at least one second retaining wall block on the first retaining wall block with the tension member interposed therebetween, wherein step (h) includes: (h1) the second retaining wall block and the reinforcing soil Installing a tension member on top; And (h2) installing at least one other second retaining wall block on the second retaining wall block with the tension member therebetween.

According to the present invention, the following effects can be derived.

First, the present invention includes a drainage passage passing through the drainage block in a direction crossing the extension direction of the drainage block. That is, the length of the drainage channel is formed equal to the width of the drainage block in which the drainage channel is formed. In other words, since the distance between the inlet and outlet of the rainfall is short, the rainfall flowing into the drainage channel is immediately discharged.

In addition, the drainage passage of the present invention is formed in plural along the extending direction of the drainage block. That is, the total cross-sectional area of the ditch is expanded without increasing the length of the ditch. Through this, the amount of drainage can be easily expanded.

In addition, the drainage passage of the present invention is formed to overlap the drainage portion in a direction crossing the extension direction of the drainage block. That is, the gap between the rubble of the drainage part and the drainage passage communicate. Through this, rainfall flowing into the drainage part can be smoothly drained through the drainage channel.

In addition, the present invention increases the amount of drainage by increasing the number of drainage passages without expanding the diameter. Through this, it is possible to provide a drainage passage of strong durability.

In addition, the drainage passage of the present invention is provided in plural along the extending direction of the drainage block. In this way, even if a part of the drainage channel is damaged, it does not affect the total amount of drainage.

In addition, the drainage passage of the present invention is formed to be visually exposed from the front side. That is, if some of the plurality of drainage channels are damaged, the drain pipe in the damaged drainage channel can be removed. By inserting a new drain pipe instead of the damaged drain pipe, damage to the drain pipe can be easily repaired.

1A is a cross-sectional view showing a conventional reinforced soil retaining wall.
1B is a partial perspective view showing a conventional reinforced soil retaining wall.
1C is a cross-sectional view showing a problem of a conventional reinforced soil retaining wall.
2 is a cross-sectional view showing a reinforcing soil retaining wall according to the present invention.
3 is a perspective view showing a drain block according to the present invention.
Figure 4 is a partial perspective view showing a reinforced soil retaining wall according to the present invention.
5 is a partial perspective view showing the drainage passage of FIG. 4.
6 is a perspective view showing a region C of FIG. 4.
7 is a perspective view showing an embodiment of a retaining wall according to the present invention.
8 is a conceptual diagram showing a process of bonding a retaining wall portion and a tension member according to the present invention.
9 is a flow chart showing the construction method of the reinforced soil retaining wall according to the present invention.
FIG. 10 is a flow chart illustrating step S30 of FIG. 9.
FIG. 11 is a flowchart illustrating step S60 of FIG. 9.
FIG. 12 is a flow chart illustrating step S80 of FIG. 9.

Hereinafter, a reinforced soil retaining wall and a construction method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description, descriptions of some constituent elements may be omitted to clarify features of the present invention.

Prior to the description, the directions used in the present specification are defined.

1. Definition of direction

The "front" used hereinafter means a direction opposite to the direction in which the retaining wall portions 20 and 200 support earth pressure.

The "rear" used hereinafter means a direction in which the retaining wall portions 20 and 200 support the earth pressure. That is, it means the direction in which the retaining wall portions 20 and 200 face the cut surfaces 70 and 700.

"Left" used hereinafter means a left direction based on the "front", and "right" means a right direction based on the "front". That is, the foundation block 10 or the drainage block 100 extends from one of the left and right directions toward the other.

"Upper side" used hereinafter refers to the direction in which the retaining wall portions 20 and 200 are stacked. Or, "upper" means the direction in which the reinforcing soils 60 and 600 are stacked.

"Lower side" used hereinafter means a direction toward the base surface (80, 800). That is, it means the direction in which rainfall moves along the drain 30.

2. Conventional Reinforced soil Description of retaining wall

Hereinafter, a conventional reinforced soil retaining wall will be described with reference to FIG. 1A. 1A is a cross-sectional view showing a conventional reinforced soil retaining wall.

(1) foundation block (10) and To the retaining wall (20) Description

In order to install the reinforced soil retaining wall, the base surface 80 is formed on the front side of the cut surface 70. Then, the foundation block 10 is installed by being spaced a predetermined distance from the cut surface 70 to the front side.

The foundation block 10 is a structure for supporting the retaining wall 20 and is installed along the cut surface 70. That is, it extends from left to right or from left to right.

The foundation block 10 is manufactured by installing a formwork on the foundation surface and pouring concrete into the formwork. Alternatively, the foundation block 10 may be formed by digging the ground to form a predetermined space, and pouring rubble and compacting it.

A retaining wall portion 20 is installed on the upper side of the foundation block 10. That is, the retaining wall portion 20 extends upward from the upper surface of the foundation block 10.

The retaining wall portion 20 is composed of a plurality of retaining wall blocks 21. A plurality of retaining wall blocks 21 are arranged along the foundation block 10 and stacked from the lower side to the upper side.

A plurality of retaining wall blocks 21 arranged from one side of the left or the right side to the other form one layer. The retaining wall portion 20 is composed of a plurality of layers formed by the retaining wall block 21.

The retaining wall portion 20 supports the reinforcing soil 60 that presses the retaining wall portion 20 from the rear side.

(2) To the drain (30) Description

A drain 30 is installed on the rear side of the retaining wall 20. The drain portion 30 extends from one of the left and the right toward the other. In addition, the drain portion 30 extends from the lower side to the upper side.

The drain portion 30 is composed of rubble (31). Rubble 31 is stacked from the lower side to the upper side, and rainfall flows into the voids between the rubbles 31. In other words, the drain 30 serves to move the introduced rainfall downward.

The drain portion 30 is formed to have a height substantially equal to the height of the retaining wall portion 20 in the upper direction. That is, the drain portion 30 drains rainfall from the rear surface of the retaining wall portion 20 downward.

In addition, the drainage part 30 is pressurized by the earth pressure of the reinforcement soil 60 located at the rear side of the drainage part 30, and transmits the earth pressure to the retaining wall part 20. That is, the drain portion 30 presses the retaining wall portion 20 toward the front side.

(3) To the merit hall (40) Description

A perforated pipe 40 is installed at the lower side of the drain 30. The perforated tube 40 is an annular tube. A plurality of through holes are formed on the outer circumferential surface of the perforated pipe 40. The perforated pipe 40 extends from one of the left and the right side to the other side from the rear surface of the retaining wall portion 20.

Rainfall flows into the perforated pipe 40 through the through hole. The introduced rainfall is drained by moving along the extension direction of the perforated pipe 40.

(4) Tension member (50) and On reinforced soil (60) Description

Based on the upward direction, the tension member 50 is inserted between the retaining wall blocks 21 adjacent to each other. Alternatively, the tension member 50 is directly connected to the retaining wall block 21. The tension member 50 may be a grid-like material having a tensile force. For example, SM grid or Tensar grid can be used.

The tension member 50 extends from one of the left and the right to the other, and extends from the front to the rear.

The tension member 50 pulls the plurality of retaining wall blocks 21 forming one layer toward the rear. Alternatively, with respect to the upper side, the retaining wall block 21 is pulled to the rear side between two adjacent layers.

The tension member 50 is installed together with the reinforcing soil 60 in the process of constructing the reinforcing soil retaining wall. That is, it is fixed by the reinforcing soil 60 and pulls the retaining wall portion 20 to the rear side. The tension member 50 prevents the retaining wall 20 from collapsing.

The reinforced soil 60 is filled between the foundation block 10 and the cut surface 70 or between the retaining wall portion 20 and the cut surface 70.

The reinforcing soil 60 is filled between the foundation block 10 and the cut surface 70 after the foundation block 10 is installed. In addition, after the retaining wall block 21 is installed on the foundation block 10, the rubble 31 is filled on the rear surface of the retaining wall block 21, and the reinforcement soil 60 is formed between the rubble 31 and the cut surface 70. Filled and chopped.

In addition, after another retaining wall block 21 is installed on the retaining wall block 21, the rubble 31 is filled on the rear surface of the other retaining wall block 21, and reinforced soil 60 between the rubble 31 and the cut surface 70 ) Is filled and minced.

By repeating the above-described process, the retaining wall portion 20 is stacked in a plurality of layers facing upward.

The reinforcement soil 60 is filled between the red, retaining wall portion 20 and the cut surface 70.

(5) cut surface (70), On the base surface (80) Description

The cut surface 70 is an inclined surface facing the retaining wall portion 20. A reinforced soil retaining wall may be installed adjacent to the existing cut surface 70. In addition, the cut surface 70 may be formed by cutting the hill at a desired angle.

The base surface 80 is formed on the front side of the cut surface 70. It is formed by flattening the ground. The compacted base surface 80 supports the base block 10 and the retaining wall 20 upward.

(6) conventional Reinforced soil Retaining wall Description of the drainage process

Hereinafter, a process of draining a conventional reinforced soil retaining wall will be described with reference to FIG. 1B. 1B is a partial perspective view showing a part of a conventional reinforced soil retaining wall.

In FIG. 1B, a predetermined section of the reinforcing soil retaining wall is shown, a part of the reinforcement soil 60 has been omitted for explanation, and a part of the drain portion 30 is shown by a dotted line.

When rainfall falls, the rainfall is moved along the direction shown.

Mainly, the surface water is moved from the top to the bottom in the drain 30. In addition, surface water absorbed from the upper surface of the reinforced soil 60 and groundwater and surface water introduced along the cut surface 70 are introduced toward the drain 30. The surface water or groundwater flowing into the drain 30 is moved from the top to the bottom in the drain 30.

That is, the surface water and groundwater are moved to the perforated pipe 40 located below the drain 30 and flow into the perforated pipe 40 through a through hole formed on the outer circumferential surface of the perforated pipe 40.

The perforated pipe 40 is installed so as to incline from one of the left and the right to the other. In FIG. 1B, a perforated pipe 40 installed to be inclined downward from left to right is shown. That is, the surface water and ground water introduced into the perforated pipe 40 are moved to the right and drained into an external drainage channel (not shown).

(7) Conventional Reinforced soil The problem of retaining walls

Hereinafter, a problem of the conventional reinforced soil retaining wall will be described with reference to FIG. 1C. 1C is a cross-sectional view showing a problem of a conventional reinforced soil retaining wall.

The water flowing into the rear surface of the retaining wall 20 is groundwater and surface water flowing from a high region to a low region. Most of the water flowing into the drain 30 at the back of the reinforced soil retaining wall during rainfall is surface water. Also, if the rainfall time increases, it flows into the groundwater. In this case, the groundwater level on the rear surface of the retaining wall portion 20 rises rapidly, and the reinforced soil retaining wall may be destroyed by water pressure.

The conventional reinforced soil retaining wall drainage structure for preventing an increase in water pressure on the rear surface of the retaining wall 20 is a structure for discharging by installing a perforated pipe 40 on the back of the retaining wall 20 as described above. Since the drainage time is delayed due to the increase in the amount of drainage during rainfall, when the drainage capacity of the perforated pipe 40 is exceeded, the groundwater level rises rapidly, and the reinforced soil retaining wall is filled or destroyed by water pressure.

When the length of the reinforced soil retaining wall is installed at 50m, let's assume that the rainfall inflow into the reinforced soil retaining wall is applied by applying the rainfall intensity of 50 years.

The diameter of the drain pipe was calculated by the following calculation.

(7-1) Watershed conditions

Basin area (A) = 0.6 ha

Euro extension (L) = 30 m

Elevation difference (H) = 0.5 m

Design frequency (y) = 50 years

(7-2) Calculation of fluid arrival time (min)

Below, the inflow time t1 and the flow time t2 of the fluid are obtained.

The inflow time (t1) was applied by the kerby equation.

t1 = 1.44 (L * n / S ^{1/ 2} ) ^{0 .467} = 5.18 min

L: surface distance (m) = 100 m

S: Surface slope (H / L) = 0.5/30 = 0.01666667

n: Earth system number similar to the roughness coefficient = 0.02 (smooth impermeable surface)

Calculation for the flow time (t2).

t2 = L / (a * V) = 0.69 min

L: Sewage pipe extension (m) = 91.5 m

V: Average flow rate according to Manning's formula (m/sec) = 2.16 m/sec = 0.036 m/min

a: Correction factor for the moving speed of the flood = 1.03 (The cross section of the pipe is circular and the water depth is 80%)

Calculation of rainfall arrival time (t1).

Rainfall arrival time (t) = inflow time (t1) + flow time (t2) = 5.87 min

(7-3) Rainfall intensity (mm/hr)

The rainfall intensity was calculated based on the frequency of 50 years.

Rainfall intensity (I)= 569/(t+0.11) ^1/2

If 5.87min is substituted for the rainfall arrival time (t), the rainfall intensity (I) at a frequency of 50 years is 224.65 mm/hr.

(7-4) Outflow (㎥ /sec)

The basin area (A) is 0.6ha.

In other words, the relationship of A ≤ 4.0 ㎢ is established. Therefore, we apply the rational expression. The rational expression is as follows.

Runoff (Qd) = 0.278 * C * I * A

In the above rational formula, the constant C is the average runoff coefficient for each use.

Based on the road, the average runoff coefficient (C) for each use is 0.85.

Total runoff can be obtained by substituting rainfall intensity, average runoff coefficient for each use, and watershed area in the above rational equation.

The runoff (Qd) is 0.32(㎥/sec).

(7-5) Plan Section Assumption

There is only one pipeline of the merit hall, and there is one line. In addition, the diameter (D) of the perforated pipe is set to 600 mm.

The water flow through the merit pipe is as follows.

Flow rate (Qi) = cross-sectional area (A) * flow rate (V)

Cross-sectional area ^{(A) = π * D 2} /4 = 0.28 ㎡

The flow rate (V) is applied by Manning's formula.

Flow rate (V) = 1/n * R ^2/3 * I ^1/2 (m /sec)

Illuminance coefficient (n)= 0.013

Inner center (R) = A / P = 0.149 m

The length of the surface in contact with water (P) = π * D = 1.88 m

I = dynamic gradient

Dynamic water gradient (I) at the minimum flow rate of D600mm (0.8m/sec): 0.13570994%

Dynamic water gradient (I) at the maximum flow rate of D600mm (3.0m/sec): 1.90842107%

Planned pipe head difference = 1.6 m

Planner extension= 91.5 m

Application gradient = 1.6/91.5 = 1% (thus, it satisfies the allowable flow rate range)

R ^2/3 = 0.281

I ^1/2 = 0.1

V = 1/n * R ^2/3 * I ^1/2 = 2.16 m/sec

Flow rate (Qi) = A * V = 0.60 ㎥/sec

As it is a drain pipe, assuming that only 90% flows,

Planned sewage volume (Qi90) = Qi * 90% = 0.54 ㎥/sec

Sewage inflow (Qd) ＜ Planned outflow (Qi90)

That is, a pipe diameter of about 600mm is required for the perforated pipe to drain smoothly for the sewage inflow (Qd).

That is, in order to properly discharge the rainfall without increasing the water level at the rear of the reinforced soil retaining wall, a drain pipe having a diameter of 600 mm or more must be used. When the pipe diameter is enlarged, there is a limit to the practically increasing the perforated drainage pipe standard because durability and workability and economical problems of the drain pipe occur.

In order to solve the above-described problem, a reinforced soil retaining wall having a drainage passage of a new structure is required.

3. According to the invention Reinforced soil Description of retaining wall

Hereinafter, a reinforced soil retaining wall according to the present invention will be described with reference to FIG. 2. 2 is a cross-sectional view showing a reinforcing soil retaining wall according to the present invention.

(1) Drainage block 100 and To the retaining wall part (200) Description

In order to install the reinforced soil retaining wall, a base surface 800 is formed on the front side of the cut surface 700. Then, the drain block 100 is installed by being spaced apart from the cut surface 700 by a predetermined distance to the front side.

The drainage block 100 is a structure for supporting the retaining wall portion 200 and is installed along the cut surface 700. That is, it extends from left to right or from right to left.

The drainage block 100 includes an upper part 110, a middle part 130, and a lower part 150. The middle part 130 connects the upper part 110 and the lower part 150.

Based on the direction crossing the extension direction of the drain block 100, the width of the middle portion 130 is formed narrower than the upper portion 110 and the lower portion 150.

That is, in the direction toward the front side, the width of the middle portion 130 is formed narrower than the upper portion 110 and the lower portion 150.

In other words, the drainage block 100 has an I-shaped cross section or a lying H-shaped cross section.

A drainage passage 113 is formed at the upper end 110 of the drainage block 100. The drainage passage 113 passes through the upper end 110 from the rear side toward the front side.

The drainage passages 113 are formed in plural from one side of the left and the right side to the other side of the upper part 110.

That is, the drainage passages 113 are formed in plural along the extending direction of the drainage block 100.

The drainage block 100 may be inserted into a predetermined space formed by digging the ground. A retaining wall part 200 is installed on the upper side of the drain block 100. That is, the retaining wall portion 200 extends upward from the upper surface of the drain block 100.

The retaining wall part 200 is composed of a plurality of retaining wall blocks 210 and 220. A plurality of retaining wall blocks 210 and 220 are arranged along the drain block 100 and are stacked from the lower side to the upper side.

Each of the plurality of retaining wall blocks 210 and 220 arranged from one side of the left or the right side to the other forms one layer. The retaining wall part 200 is composed of a plurality of layers formed by the retaining wall blocks 210 and 220.

The retaining wall portion 200 supports the reinforcing soil 600 that presses the retaining wall portion 200 from the rear side.

The detailed structure of the retaining wall part 200 will be described in detail in FIG. 7.

(2) To the drainage part (300) Description

A drain 300 is installed on the rear side of the retaining wall 200. The drainage part 300 extends from one of the left and the right toward the other. In addition, the drain portion 300 extends from the lower side to the upper side.

The drainage part 300 is composed of rubble 310. Rubble 310 is stacked from the lower side to the upper side, and rainfall flows into the voids between the rubble 310. That is, the drain 300 serves to move the introduced rainfall downward.

The drainage part 300 is formed to have a height substantially equal to the height of the retaining wall part 200 in the upward direction. That is, the drainage part 300 drains rainfall downward from the rear surface of the retaining wall part 200.

Based on the direction from the rear side toward the front side, the drainage portion 300 overlaps with the upper end portion 110 of the drainage block 100.

That is, the drainage part 300 overlaps the drainage passage 113 of the upper end 110 in a direction crossing the direction in which the drainage block 100 extends.

In addition, the drainage passage 113 and the lower end of the drainage part 300 communicate with each other. Rainfall flowing into the lower end of the drainage portion 300 is discharged to the front side of the retaining wall portion 200 through the drainage portion 300.

In addition, the drainage part 300 is pressurized by the earth pressure of the reinforcement soil 600 located at the rear side, and transmits it to the retaining wall part 200. That is, the drain portion 300 presses the retaining wall portion 200 toward the front side.

(3) Tension member (500) and On reinforced soil (600) Description

The retaining wall blocks 210 and 220 include a first retaining wall block 210 adjacent to the drain block 100 and a second retaining wall block 220 installed on the first retaining wall block 210 and stacked upwardly.

A tension member 500 is inserted between the first retaining wall block 210 and the second retaining wall block 220 adjacent to each other based on the upward direction. Alternatively, the tension member 500 is directly connected to the first retaining wall block 210.

In addition, the tension member 50 is inserted between the second retaining wall blocks 220 adjacent to each other based on the upward direction. Alternatively, the tension member 500 is directly connected to the second retaining wall block 220. The tension member 500 may be a grid-type material having a tensile force. For example, SM grid or Tensar grid can be used.

The tension member 500 extends from one of the left and the right to the other, and extends from the front to the rear.

The tension member 500 pulls the plurality of first retaining wall blocks 210 and the second retaining wall blocks 220 forming one layer toward the rear. Alternatively, the first retaining wall block 210 and the second retaining wall block 220 are pulled rearward between two adjacent layers based on the upward direction.

The tension member 500 is installed together with the reinforcement soil 600 in the process of constructing the reinforced soil retaining wall. That is, it is fixed by the reinforcing soil 600 and pulls the retaining wall portion 200 to the rear side. The tension member 500 prevents the retaining wall part 200 from collapsing toward the front side.

The reinforced soil 600 is filled between the drainage block 100 and the cut surface 700 or between the retaining wall portion 200 and the cut surface 700.

The reinforced soil 600 is filled between the drain block 100 and the cut surface 700 after the drain block 100 is installed. In particular, for the overlapping structure of the drainage portion 300 and the drainage passage 113, the reinforcement soil 600 may be filled up to the height of the middle portion 130 between the drainage block 100 and the cut surface 700.

After that, the rubble 310 is filled on the rear surface of the upper end 110, and the reinforcement soil 600 is filled and compacted on the rear surface of the rubble 310.

In addition, after the first retaining wall block 210 is installed on the drainage block 100, rubble 310 is filled on the rear surface of the first retaining wall block 210, and reinforced soil between the rubble 310 and the cut surface 700 60 is filled and chopped.

A tension member 500 is installed on the first retaining wall block 210, and a second retaining wall block 220 is installed thereon.

The rear surface of the second retaining wall block 220 is filled with rubble 310, and reinforced soil 600 is filled and compacted between the rubble 310 and the cut surface 700.

The second retaining wall block 220 may be formed in a plurality of layers facing upward. That is, the second retaining wall block 220 may include a first layer 221, a second layer 223, and a third layer 225. However, it is not limited to the above, and the second retaining wall block 220 may be formed of a larger number of layers.

A tension member 500 is installed on the second retaining wall block 220, and another second retaining wall block 220 is installed thereon.

By repeating the above-described process, the retaining wall portion 200 is stacked in a plurality of layers toward the upper side.

That is, the reinforced soil 600 is filled between the retaining wall portion 200 and the cut surface 700.

The process in which the above-described tension member 500 is installed will be described in detail in FIG. 8.

(4) Cut surface (700), On the base surface (800) Description

The cut surface 700 is an inclined surface facing the retaining wall portion 200. A reinforced soil retaining wall may be installed adjacent to the existing cut surface 700. In addition, the cut surface 700 may be formed by cutting the hill at a desired angle.

The base surface 800 is formed on the front side of the cut surface 700. It is formed by flattening the ground. The compacted base surface 800 supports the drainage block 100 and the retaining wall 200 upward.

(5) Description of the external drainage channel (900)

The rainfall drained to the front side through the drainage channel 113 is discharged through the external drainage channel 900.

The external drainage passage 900 is formed on the front side of the reinforced soil retaining wall, and extends from one of the left and the right toward the other.

The external drainage passage 900 may be formed as a concrete drainage passage buried in the ground.

Rainfall that has fallen from the drainage passage 113 of the drainage block 100 is discharged by moving along the external drainage passage 900.

(6) Detailed description of the drainage block 100

Hereinafter, the drain block 100 according to the present invention will be described in detail with reference to FIG. 3. 3 is a perspective view showing a drain block 100 according to the present invention.

The drainage block 100 includes an upper part 110, a middle part 130, and a lower part 150. The middle part 130 connects the upper part 110 and the lower part 150.

Based on the direction crossing the extension direction of the drain block 100, the width of the middle portion 130 is formed narrower than the upper portion 110 and the lower portion 150.

That is, in the direction toward the front side, the width of the middle portion 130 is formed narrower than the upper portion 110 and the lower portion 150.

In other words, the drainage block 100 has an I-shaped cross section or a lying H-shaped cross section.

That is, the drain block 100 has a shape in which the middle portion is recessed toward the center.

Through this, the weight of the drainage block 100 can be reduced, and the production cost can be lowered. In the present invention, without manufacturing the foundation on the site, it is only necessary to pre-produce the drainage block 100 and install it at the installation site.

That is, the process is simplified and the construction time is shortened. In addition, by reducing the weight of the drain block 100 it is possible to smoothly transport the drain block 100 to the starting point.

The upper portion 110, the middle portion 130, and the lower portion 150 of the drain block 100 are formed so that their centers coincide with each other. That is, it is formed symmetrically with respect to the virtual line connecting each center.

The recessed portions of the middle portion 130 are formed symmetrically to each other, and soil is filled in the rear side and the front side of the middle portion 130. The soil filled in the rear side and the front side of the middle portion 130 supports the retaining wall portion 200 with the drain block 100 upward.

A drainage passage 113 is formed at the upper end 110 of the drainage block 100. The drainage passage 113 includes a drain hole 113a and a drain pipe 113b.

The drain hole 113a passes through the upper end 110 from the rear side toward the front side.

A drain pipe 113b is inserted into the drain hole 113a. The drain pipe 113b is formed in an annular shape, and the outer diameter of the drain pipe 113b may be formed substantially the same as the diameter of the drain hole 113a.

The drain pipe 113b may be a known pipe capable of moving a fluid. For example, cast iron pipes, white pipes, hard vinyl chloride pipes (PVC pipes), conduits, and the like may be used.

The inner diameter of the drain pipe 113b may be formed from 50mm to 100mm. However, it is not limited thereto and may be formed in various inner diameters. That is, the inner diameter of the drain pipe 113b may be determined in consideration of the upper height and the front width of the drain block 100.

Based on the direction from the rear side toward the front side, the width of the upper end portion 110 may be determined to be 500 mm or more. The width of the retaining wall block used in the market is mostly 350mm. Accordingly, it is possible to stably support the retaining wall block of the drainage block 100.

However, the width of the upper part 110 is not limited to the above-described standard and may be variously set. That is, based on a direction crossing the extension direction of the drain block 100, the width of the upper end portion 110 may be formed to be wider than the width of the retaining wall portion 200.

The drainage passages 113 are formed in plural from one side of the left and the right side to the other side of the upper part 110. That is, the drainage passages 113 are formed in plural along the extending direction of the drainage block 100.

Based on the direction from the rear to the front, the drainage block 100 has a drainage passage 113 passing through the drainage block 100. The length of the drainage passage 113 is equal to the length of the width of the drainage block 100. That is, the length of the flow path for discharging rainfall from the rear side to the front side of the retaining wall portion 200 is formed short.

Through this, the drainage time required for rainfall to flow into the pipe and discharge it out of the pipe is shortened. In other words, it is possible to immediately discharge the incoming rainfall without delay in the drainage time.

In addition, in the conventional perforated pipe, rainfall is introduced through a through hole formed on the outer peripheral surface of the pipe. However, there is a limit to increasing the size of the through hole because it is necessary to prevent the inflow of rubble or soil through the through hole. In order to increase the size and number of through holes, the diameter of the perforated pipe must be increased. However, an increase in the diameter of the perforated pipe may not only cause a problem of durability of the perforated pipe, but also reduce the time and economy required for construction.

In the drainage passage 113 according to the present invention, a plurality of drainage passages 113 are formed along the extension direction of the drainage block 100, so that an area for discharging rainfall can be easily increased. That is, it is possible to easily improve the area in which rainfall is discharged while shortening the length in which rainfall is moved. In addition, since it is not necessary to increase the inner diameter of the drain pipe 113b, it has relatively strong durability.

In addition, the perforated pipe is a type in which one pipe is buried in the rear side of the retaining wall. In addition, it extends along the entire length of the reinforced soil retaining wall based on a direction from one of the left and the right toward the other.

In other words, the drainage length in which rainfall must be moved for drainage is too long. In addition, if a breakage occurs in the middle, leakage may occur and drainage efficiency may decrease, and if soil flows in the middle and becomes clogged, the drainage may be stopped. In other words, damage to a part of the perforated pipe affects the entire perforated pipe. In addition, in the case of damage to a part of the perforated pipe, the entire perforated pipe must be replaced, making it difficult to repair in practice.

On the other hand, the drainage passage 113 according to the present invention has a short drainage length, and a plurality of drainage passages 113 are formed along the extending direction of the drainage block 100. That is, even if some of the plurality of drainage passages 113 are damaged, the entire drainage is not significantly affected. In addition, the drain pipe 113b is visually exposed from the front side of the retaining wall part 200. Through this, even if damage occurs, it can be easily repaired by separating and removing the damaged drain pipe 113b from the drain hole 113a and inserting a new drain pipe 113b into the drain hole 113a.

(7) according to the present invention Reinforced soil Retaining wall Description of the drainage process

In the following, a drainage process of the reinforced soil retaining wall according to the present invention will be described with reference to FIGS. 4, 5 and 6.

Figure 4 is a partial perspective view showing a reinforced soil retaining wall according to the present invention. 5 is a partial perspective view showing the drainage passage of FIG. 4. 6 is a perspective view showing a region C of FIG. 4.

In FIG. 4, a predetermined section of the reinforced soil retaining wall is shown, a part of the reinforced soil 600 has been omitted for explanation, and a part of the drainage part 300 is shown by a dotted line.

When rainfall falls, the rainfall moves along the direction of the arrow shown.

Mainly, the surface water is moved from the upper side to the lower side within the drainage part 300. In addition, surface water absorbed from the upper surface of the reinforced soil 600 and groundwater and surface water introduced along the cut surface 700 are introduced toward the drain 300. Surface water or groundwater flowing into the drainage unit 300 is moved from the top to the bottom within the drainage unit 300.

The drainage passage 113 of the drainage block 100 and the lower side of the drainage part 300 communicate with each other. Accordingly, the surface water and ground water introduced to the lower side of the drainage unit 300 are introduced to the rear side of the drainage passage 113 of the drainage block 100. Surface water and groundwater introduced into the drainage channel 113 are discharged to the front side of the drainage channel 113.

In FIG. 5, a part of the drainage block 100 is omitted for description. A drain pipe 113b is shown in a portion of the drain block 100 in which a part is omitted.

As shown, a plurality of drain pipes 113b are formed along the extending direction of the drain block 100. Through this, the surface water and groundwater introduced to the lower side of the drainage portion 300 through the drainage portion 300 may be immediately discharged through the nearest drainage pipe 113b.

In FIG. 6, area C of FIG. 4 is shown, and for explanation, a state in which the drain pipe 113b is inserted into the cross section of the drain hole 113a is shown.

In the process of introducing the surface water and ground water into the drain pipe 113b into which the surface water and ground water are introduced, the rubble 310 or the soil may be introduced together. In this case, the drain pipe 113b is clogged and there is a problem that drainage is not performed. Accordingly, a filter 113c for blocking the inflow of rubble 310 or soil may be installed at the rear side of the drain pipe 113b. In an embodiment of the present invention, the filtering unit 113c may be formed of a grid-like member.

The filtering unit 113c is installed at the rear side of all the drain pipes 113b to filter rubble from flowing into the drain pipe 113b.

(8) With retaining wall part (200) To the tension member 500 Specific explanation

Hereinafter, a process in which the retaining wall portion 200 and the tension member 500 are installed will be described with reference to FIGS. 7 and 8.

7 is a perspective view showing an embodiment of a retaining wall according to the present invention. 8 is a conceptual diagram showing a process of bonding a retaining wall portion and a tension member according to the present invention.

Referring to FIG. 7, a process in which the retaining wall part 200 is installed is shown. 7 shows a state in which the second retaining wall blocks 220 are stacked.

As the second retaining wall block 220, a known block such as a concrete block may be used.

A plurality of second retaining wall blocks 220 are sequentially arranged from one of the left and the right toward the other to form one block layer.

A plurality of second retaining wall blocks 220 are sequentially arranged on the one block layer from one of the left and the right toward the other to form another block layer.

The retaining wall portion 200 having a plurality of layers is formed through the above-described method.

Based on a direction from the lower side to the upper side, the adjacent second retaining wall blocks 220 may be formed to partially overlap each other. That is, it can be arranged in zigzag.

In FIG. 8, a process in which the tension member 500 is inserted between the first retaining wall block 210 and the second retaining wall block 220 is illustrated.

Based on the direction from the lower side to the upper side, the tension member 500 may be inserted between the second retaining wall blocks 220 as well.

The first retaining wall block 210 has coupling grooves 210a and 210b penetrating from the lower side to the upper side at each corner. Further, the second retaining wall block 220 is formed with coupling grooves 220a and 220b penetrating from the lower side to the upper side at each corner.

A grid-type tension member 500 is disposed between the first retaining wall block 210 and the second retaining wall block 220.

The first retaining wall block 210 and the second retaining wall block 220 are coupled to each other by a coupling pin 250 penetrating the inner space of the tension member 500.

The upper side of the coupling pin 250 is inserted into the left or right coupling grooves 210a, 210b of the first retaining wall block 210, and the lower side of the coupling pin 250 is coupled to the left or right side of the second retaining wall block 220 It is inserted into the grooves 220a and 220b.

That is, in a state in which the first retaining wall block 210 and the second retaining wall block 220 are coupled by the coupling pin 250, the front side of the tension member 500 is caught by the coupling pin 250.

The grid 500 is fixed by the reinforcement soil 600 buried at the rear side of the first retaining wall block 210 and the second retaining wall block 220 to pull the retaining wall part 200 to the rear side together with the coupling pin 250 .

Through this, the retaining wall portion 200 supports the earth pressure of the reinforced soil 600.

4. According to the invention Reinforced soil Retaining wall Description of the construction method

In the following, a method of constructing a reinforced soil retaining wall according to the present invention will be described with reference to FIGS. 9, 10, 11 and 12.

9 is a flow chart showing the construction method of the reinforced soil retaining wall according to the present invention. FIG. 10 is a flow chart illustrating step S30 of FIG. 9. FIG. 11 is a flowchart illustrating step S60 of FIG. 9. FIG. 12 is a flow chart illustrating step S80 of FIG. 9.

(1) Description of the step (S10) of compacting the base surface 800 by being spaced apart from the cutting surface 700 by a predetermined distance

The cut surface 700 is an inclined surface facing the retaining wall portion 200. A reinforced soil retaining wall may be installed adjacent to the existing cut surface 700. In addition, the cut surface 700 may be formed by cutting the hill at a desired angle.

Prior to installing the reinforced soil retaining wall, the reinforced soil retaining wall is supported on the front side of the cut surface 700, and a foundation surface 800 on which the reinforced soil 600 is filled is formed.

The base surface 800 is formed by flattening the ground.

(2) On the base surface (800) Description of the step (S20) of installing the drainage block along one direction

A drain block 100 is installed on the foundation surface 800 to install the reinforced soil retaining wall. A drain block 100 is installed spaced apart from the cut surface 700 by a predetermined distance to the front side.

Since the drain block 100 has been described in detail above, it will be omitted.

Drainage block 100 is produced in advance in the factory and transported to the construction site. That is, the previously produced drainage block 100 is installed along a specific direction without the need to produce the foundation part of concrete at the construction site.

The drainage block 100 is a structure for supporting the retaining wall portion 200 and is installed along the cut surface 700. That is, a plurality of drainage blocks 100 are installed from left to right or from left to right.

(3) The drainage material 310 and the drainage material 310 between the drainage block 100 and the cutting surface 700 to the height of the drainage block 100 Reinforced soil (600) Description of the step of filling and compacting sequentially (S30)

The reinforced soil 600 is filled between the drainage block 100 and the cut surface 700 or between the retaining wall portion 200 and the cut surface 700.

The reinforced soil 600 is filled between the drain block 100 and the cut surface 700 after the drain block 100 is installed.

Through this, the drainage portion 300 is formed on the rear surface of the drainage block 100, and the reinforcement soil 600 is filled to the rear of the drainage portion 300.

In particular, for the overlapping structure of the drainage portion 300 and the drainage passage 113, the reinforcement soil 600 may be filled up to the height of the middle portion 130 between the drainage block 100 and the cut surface 700 (S301).

After that, the drainage material 310 is filled and compacted on the rear surface of the upper end portion 110 facing the cut surface 700 (S303).

After that, the reinforcement soil 600 is filled and compacted between the drainage material 310 and the cut surface 700 (S305).

(4) Description of the step (S40) of installing at least one first retaining wall block 210 on the drainage block 100

In addition, a first retaining wall block 210 is installed on the drain block 100.

The drainage block 100 is spaced apart from the cutting surface 700 by a predetermined distance and is installed from one of the left and the right toward the other.

A first retaining wall block 210 is installed on the drain block 100.

Although not shown, a plurality of coupling grooves may be formed on the upper side of the drain block 100, and a plurality of coupling grooves 210a and 210b are formed on the lower side of the first retaining wall block 210.

A coupling pin 250 is disposed between the drainage block 100 and the first retaining wall block 210. One side of the coupling pin 250 is inserted into the coupling groove of the drain block 100, and the other side of the coupling pin 250 is inserted into the coupling grooves 210a and 210b of the first retaining wall block 210. That is, the drainage block 100 and the first retaining wall block 210 are coupled by a coupling pin 250.

(5) Drainage material 310 and up to the height of the first retaining wall block 210 Description of the step (S50) of sequentially filling the reinforced soil 600

The drainage material 310 is filled on the rear surface of the first retaining wall block 210, and the reinforcement soil 600 is filled and compacted between the drainage material 310 and the cut surface 700. The drainage material 310 forms a part of the drainage part 300.

In addition, based on the direction from the front side toward the rear side, the width of a part of the drainage portion 300 formed by the drainage material 310 is the drainage portion 300 formed by the drainage material 310 at the rear surface of the drainage block 100 ) Can be formed equal to the width of a part of.

That is, after filling the drainage material 310 to form a part of the drainage portion 300, the reinforcement soil 600 is filled to the rear side of the drainage portion 300.

(6) installing at least one second retaining wall block on the first retaining wall block ( Description of S60)

A tension member 500 is installed on the first retaining wall block 210 (S601).

First, the lower side of the coupling pin 250 is inserted into the coupling grooves 210a and 210b formed on the upper side of the first retaining wall block 210. Thereafter, the tension member 500 is penetrated by the coupling pin 250 and is disposed on the drainage portion 300 and the reinforcing soil 600 located at the rear side of the first retaining wall block 210 and the first retaining wall block 210. Placed.

The coupling grooves 220a and 220b formed on the lower side of the second retaining wall block 220 are fitted on the upper side of the coupling pin 250. Through this, at least one second retaining wall block 220 is installed on the first retaining wall block 210 with the tension member 500 therebetween (S603).

(7) Up to the height of the second retaining wall block 220 Drainage material 310 and Reinforced soil (600) Description of the step of filling and compacting sequentially (S70)

The rear surface of the second retaining wall block 220 is filled with rubble 310, and reinforced soil 600 is filled and compacted between the rubble 310 and the cut surface 700. The drainage material 310 forms a part of the drainage part 300.

In addition, based on the direction from the front side to the rear side, the width of a part of the drainage portion 300 formed by the drainage material 310 is a drainage portion formed by the drainage material 310 at the rear surface of the first retaining wall block 210 It may be formed to have the same width as a part of 300.

That is, after filling the drainage material 310 to form a part of the drainage portion 300, the reinforcement soil 600 is filled to the rear side of the drainage portion 300.

The second retaining wall block 220 may be formed in a plurality of layers facing upward. That is, the second retaining wall block 220 may include a first layer 221, a second layer 223, and a third layer 225. However, it is not limited to the above, and the second retaining wall block 220 may be formed of a larger number of layers.

(8) Description of the step (S80) of installing another second retaining wall block 220 on the second retaining wall block 220

A tension member 500 is installed on the second retaining wall block 220 (S801).

First, the lower side of the coupling pin 250 is inserted into the coupling grooves 220a and 220b formed on the upper side of the second retaining wall block 220. Thereafter, the tension member 500 is penetrated by the coupling pin 250 and is disposed on the drainage portion 300 and the reinforcing soil 600 located at the rear side of the second retaining wall block 220 and the first retaining wall block 220. Placed.

The coupling grooves 220a and 220b formed on the lower side of the other second retaining wall block 220 are fitted on the upper side of the coupling pin 250. Through this, at least one other second retaining wall block 220 is installed on the second retaining wall block 220 with the tension member 500 therebetween (S803).

(9) Up to the height of the other second retaining wall block 220 Drainage material 310 and Reinforced soil (600) Description of the step of filling and compacting sequentially (S90)

The rear surface of the second retaining wall block 220 is filled with rubble 310, and reinforced soil 600 is filled and compacted between the rubble 310 and the cut surface 700. The drainage material 310 forms a part of the drainage part 300.

In addition, based on the direction from the front side to the rear side, the width of a part of the drainage portion 300 formed by the drainage material 310 is a drainage portion formed by the drainage material 310 at the rear surface of the second retaining wall block 220 It may be formed to have the same width as a part of 300.

That is, after filling the drainage material 310 to form a part of the drainage portion 300, the reinforcement soil 600 is filled to the rear side of the drainage portion 300.

The other second retaining wall block 220 may be formed in a plurality of layers facing upward. That is, another second retaining wall block 220 may be composed of a first layer 221, a second layer 223, and a third layer 225. However, it is not limited to the above, and the other second retaining wall block 220 may be formed of a larger number of layers.

(10) Repeat steps S80 and S90 to form a plurality of retaining wall blocks. Stacked Description of step (S100)

Based on the direction from the lower side to the upper side, the retaining wall portion 200 may be stacked in a plurality of layers by repeating the steps S80 and S90.

Although the above has been described with reference to preferred embodiments of the present invention, those of ordinary skill in the art will variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can.

10: foundation block
20: retaining wall
21: retaining wall block
30: drain
31: rubble
40: Merit Hall
50: tension member
60: reinforced soil
70: cut surface
80: base surface
100: drain block
110: upper part
113: ditch
113a: drain hole
113b: drain pipe
130: middle
130a: recess side
130b: recess side
150: lower part
200: retaining wall
210: first retaining wall block
210a: coupling groove
210b: coupling groove
220: second retaining wall block
221: second retaining wall block
221a: coupling groove
221b: coupling groove
223: second retaining wall block
225: second retaining wall block
250: coupling pin

Claims (10)

Drainage blocks spaced apart from the cut surface by a predetermined distance and extending toward one side;
A retaining wall part seated on the drain block and supporting the earth pressure of the reinforced soil stacked between the cut surface and the drain block; And
A drain portion disposed between the retaining wall portion and the reinforcing soil and extending along a direction in which the reinforcing soil is stacked,
The drainage block is formed with a drainage passage passing through in a direction crossing the extension direction,
At least a portion of the drainage block overlaps the drainage portion in a direction crossing the extension direction,
The drainage part and the drainage passage communicate,
The drainage block,
An upper end portion in which the drainage passage is formed;
A lower part in contact with the ground; And
And a middle portion connecting the upper end and the lower end,
Based on a direction crossing the extension direction of the drainage block, the width of the middle portion is formed narrower than that of the upper end and the lower end,
A filtering unit for blocking the inflow of rubble or soil is disposed on one side of the drainage channel,
In the drainage passage of the drainage block, a drainage pipe formed to be separated from the drainage passage so as to be repairable in case of damage is inserted,
Reinforced soil retaining wall. The method of claim 1,
The retaining wall portion,
A first retaining wall block disposed adjacent to the drainage block; And
Comprising a second retaining wall block installed on the first retaining wall block and stacked in a vertical direction upward,
Reinforced soil retaining wall. The method of claim 1,
The drainage passage is formed in plurality along the extending direction,
Reinforced soil retaining wall. The method of claim 1,
Based on the direction crossing the extension direction of the drainage block, the width of the upper end is formed to be wider than the width of the retaining wall,
Reinforced soil retaining wall. The method of claim 1,
The drainage part is formed of stacked rubbles,
The drainage part,
Extending to the upper end of the drainage block so as to discharge rainfall that is drained downward from the rear surface of the retaining wall through the drainage part through the drainage passage,
Reinforced soil retaining wall. delete (a) separating the base surface by a predetermined distance from the cut surface;
(b) installing a drainage block along one direction on the base surface;
(c) sequentially filling and compacting drainage material and reinforcement soil between the drainage block and the cut surface up to the height of the drainage block;
(d) installing at least one first retaining wall block on the drainage block;
(e) sequentially filling and compacting drainage material and reinforcement soil up to the height of the first retaining wall block;
(f) installing at least one second retaining wall block on the first retaining wall block;
(g) sequentially filling and compacting drainage material and reinforcement soil up to the height of the second retaining wall block;
(h) installing at least one other second retaining wall block on the second retaining wall block;
(i) sequentially filling and compacting drainage material and reinforcement soil to the height of the other second retaining wall block;
(j) repeating steps (h) and (i) to stack a plurality of retaining wall blocks,
The drainage block is formed with a drainage passage passing through in a direction crossing the one direction,
At least a portion of the drainage block overlaps the drainage material in a direction crossing the one direction,
The drainage passage communicates with the voids between the drainage material,
The drainage block,
An upper end portion in which the drainage passage is formed;
A lower part in contact with the ground; And
And a middle portion connecting the upper end and the lower end,
Based on a direction crossing the extension direction of the drainage block, the width of the middle portion is formed narrower than that of the upper end and the lower end,
A filtering unit for blocking the inflow of rubble or soil is disposed on one side of the drainage channel,
In the drainage passage of the drainage block, a drainage pipe formed to be detachable from the drainage passage so as to be repairable in case of damage is inserted,
Construction method of reinforced soil retaining wall. delete The method of claim 7,
The step (c),
(c1) filling and compacting reinforced soil between the drainage block and the cut surface to the height of the middle portion;
(c2) filling and compacting a drainage material on the rear surface of the upper end facing the cut surface; And
(c3) comprising the step of filling and compacting reinforced soil between the drainage material and the cut surface,
Construction method of reinforced soil retaining wall. The method of claim 9,
The step (f),
(f1) installing a tension member on the first retaining wall block and the reinforcing soil; And
(f2) comprising the step of installing at least one second retaining wall block on the first retaining wall block with the tension member therebetween,
The step (h),
(h1) installing a tension member on the second retaining wall block and the reinforcing soil; And
(h2) comprising the step of installing at least one other second retaining wall block on the second retaining wall block with the tension member therebetween,
Construction method of reinforced soil retaining wall.

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