KR20190088654A - Retaining wall construction method using soil cement and rigid geogrid - Google Patents

Abstract

The present invention provides a construction method for a retaining wall, using soil cement and rigid geogrid, capable of reducing storage space of a construction material of a retaining wall and consuming relatively low construction costs of the construction material of the retaining wall. According to the present invention, the construction method for a retaining wall, using the soil cement and the rigid geogrid, includes: a first step of preparing multiple pieces of rigid geogrid (10); a second step of arranging the multiple pieces of the rigid geogrid (10) and forming multiple placing spaces (11); a third step of inserting a leg of a steel plate (30) into an inclinometer (20) after inserting the inclinometer (20) into the placing space (11); a fourth step of installing a blocking film (40) formed of a nonwoven fabric material in the placing space (11) installed in front of the multiple pieces of the rigid geogrid (10); a fifth step of placing reinforcing soil (50) including soil, gravel, and soil cement in the placing space (11); a sixth step of removing the steel plate (30) inserted into the inclinometer (20); and a seventh step of forming a unit retaining wall by forming an aggregate layer (60) in the rear of the multiple pieces of the rigid geogrid (10).

Description

{Retaining wall construction method using soil cement and rigid geogrid}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of constructing a retaining wall for preventing soil from collapsing.

Generally, when constructing a retaining wall, soil has a characteristic that it can not exert its own predetermined strength, unlike concrete or steel rock, etc., so that various reinforcing materials having a large tensile force are used in the soil, After that, the retaining wall structure is constructed by using the reinforcing soil.

As a technique relating to such a retaining wall structure, Korean Patent Registration No. 1085250 discloses a semi-detachable retaining wall block, which is mounted on the front surface of the front wall and has a decorative stone having an average thickness of 30 mm, A bolt mounting hole formed at a left side and a right upper end of the rear surface of the decorative stone at a depth of 15 to 20 mm and a bolt mounting hole formed in a rear portion of the decorative stone, Shaped mounting piece is mounted on the rear portion of the decorative stone by fastening a nut to the bolt through a threaded portion of the bolt, and the upper end of the semi-removable retaining wall block is formed Shaped mounting portion, and a decorative piece is inserted by inserting a hook piece of the seven-shaped mounting piece into the flat-shaped mounting portion, A decorative stone mounting structure of a semi-detachable retaining wall block is disclosed in which a natural aesthetic sense of a natural stone is generated without a mounting hole or a protruding bolt.

However, in the related art, when the retaining wall block is transported to the retaining wall construction area, the weight of the retaining wall block is heavy and a large storage space is required, thus requiring a high transportation cost.

Also, the prior art has a problem that a large space is required for storing the retaining wall block.

Korean Registered Patent No. 1085250 (November 14, 2011)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a retaining wall construction method using sill cement and a rigid geogrid which can reduce the storage cost of the retaining wall construction material and the transportation cost of the retaining wall construction material is relatively low. .

The retaining wall construction method using the soil cement and the rigid geogrid according to the present invention comprises a first step of preparing a plurality of rigid geogrid 10; A second step of arranging the rigid geogrids 10 in a mesh structure to form a plurality of pouring spaces 11; A third step of inserting the legs of the iron plate 30 into the horizontal vertical system 20 after inserting the horizontal vertical system 20 into the recessed space 11; A fourth step of installing a shielding film (40) made of a nonwoven fabric in a placement space (11) located in front of the rigid geogrid (10); A fifth step of injecting a reinforcing soil (50) including soil, gravel, and soil cement into the pouring space (11); A sixth step of removing the steel plate 30 inserted into the horizontal straightness system 20; And forming an aggregate layer (60) behind the rigid geogrid (10) to form a unit retaining wall.

The second step includes a step 2-1 of bending the rigid geogrid 10 in a staggered manner, a step 2-2 of arranging the rigid geogrid 10 in a mesh structure, a step 2-2 of arranging the rigid geogrid 10, And joining the joint grid 15 by staggering the joining grid 15 to the joint site.

The fifth step includes a fifth step of injecting the reinforcing soil 50 into the pouring space 11, a fifth step of applying vibration to the reinforcing soil 50 with a vibrator, ) Is pressurized with a pressure roll.

An eighth step of forming a multi-layer retaining wall by laminating the unit retaining walls in multiple layers; And installing a drain pipe (70) in front of the multi-layer retaining wall.

The eighth step includes a step 8-1 of laminating the unit retaining walls in multiple layers, an eighth step of fixing the ends of the rigid geogrid 10 formed in the unit retaining walls to the terminal 80, And screwing the terminal (80) to the through bolt (90).

A tenth step of penetrating the base steel bar 100 in front of the multi-layer retaining wall; An eleventh step of coupling a supporting reinforcing bar 110 of a grid structure to the base reinforcing bar 100; And a gypsum board 120 having a specific pattern formed on the front side of the supporting bar 110.

In addition, the horizontal straightness system 20 is made of fiber reinforced plastics (FRP).

Accordingly, the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention is advantageous in that the transportation cost of the retaining wall construction material is relatively small and the storage space of the retaining wall construction material is shortened.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing first to second steps of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention; FIG.
2 is a schematic view showing the third to fourth steps of the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention.
3 is a schematic view showing a fifth step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.
4 is a schematic view showing steps 6 to 7 of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.
5 is a schematic diagram illustrating a joint grid according to the present invention;
6 is a schematic view showing steps 8 to 9 of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.
7 is a schematic diagram showing a terminal according to the invention;
8 is a schematic view showing a tenth step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.
9 is a schematic view showing an eleventh step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.
10 is a schematic view showing a twelfth step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the technical concept of the present invention, are incorporated in and constitute a part of the specification, and are not intended to limit the scope of the present invention.

The present invention relates to a retaining wall construction method using soil cement and rigid geogrid.

FIG. 1 is a schematic view showing a first step to a second step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention, FIG. 2 is a schematic view showing a third step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention FIG. 3 is a schematic view showing a fifth step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention, FIG. 4 is a schematic view showing a fifth step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention, 7 < / RTI >

As shown in Fig. 1, the first step is to prepare the basic construction material of the present invention, and a plurality of rigid geogrids 10 are prepared.

Generally, the rigid geogrid 10 is manufactured by passing a geomempa passed through an extruder through a roller to form a grid-like hole. In the present invention, the rigid geogrid 10 is formed by cutting a plurality of unit sheets, And then bonding the contact portions of a plurality of bars with an adhesive. As a result, the rigid geogrid 10 of the present invention does not require a separate extruder or roller.

In the second step, the rigid geogrids 10 are arranged in a mesh structure to form a plurality of pouring spaces 11. At this time, the portions where the rigid geogrids 10 are in contact with each other may be fixed by separate members.

2, in the third step, the horizontal straight line 20 is inserted into the pouring space 11, the legs of the steel plate 30 are inserted into the horizontal straight line 20, The horizontal straightness system 20 is moved and fixed to the ground so that the horizontal straightness system 20 is vertically erected on the ground.

At this time, the horizontal straightness system 20 may be made of fiber reinforced plastics (FRP) material so that a horizontal system and an orthogonal system function as a general description, and a detailed description thereof is omitted, but it is prevented from being broken by peripheral pressure.

Further, the iron plate 30 includes a frame-shaped main body and a plurality of legs perpendicularly connected to the main body.

In the fourth step, a barrier film 40 made of a nonwoven fabric is installed in the installation space 11 located in front of the rigid geogrids 10. At this time, the blocking film 40 serves to block the reinforcing soil 50 inserted into the pouring space 11.

As shown in FIG. 3, in the fifth step, the reinforcing soil 50 is introduced into the pouring space 11. At this time, the steel plate 30 supports the rigid geogrid 10 so that the rigid geogrid 10 does not fall down while the reinforcing soil 50 is inserted into the pouring space 11.

As shown in FIG. 4, in the sixth step, the steel plate 30 inserted into the horizontal straightness system 20 is removed. At this time, since the horizontal and vertical degrees are displayed on the horizontal straightness system 20, the inclination of the reinforcing soil 50 can be confirmed.

In the seventh step, an aggregate layer 60 is formed behind the rigid geogrids 10 to form a unit retaining wall.

Accordingly, the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention uses the rigid geogrid 10 having a light weight as the basic wall of the retaining wall construction material, so that the transportation cost of the retaining wall construction material is relatively low, The storage space of the material can be shortened.

5 is a schematic view showing a joint grid according to the present invention.

As shown in FIG. 5, the second step includes a step 2-1 of bending the rigid geogrid 10 in a staggered manner, a step 2-2 of arranging the rigid geogrid 10 in a mesh structure, And a second and third step of stitching and joining the joint grid 15 to the jointed part of the rigid geogrid 10.

More specifically, step 2-1 may bend the rigid grids using a squeeze roll.

In addition, in the step 2-3, at least two or more jointing grids 15 are staggeredly passed through the jointed portions of the rigid geogrid 10 so that the jointed portions of the rigid geogrid 10 are more firmly coupled .

Accordingly, the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention does not use a separate adhesive for joining the rigid geogrid 10, so that not only a small amount of adhesive is required but also the rigidity of the rigid geogrid 10 It is very easy to combine and separate them.

The fifth step includes a fifth step of injecting the reinforcing soil 50 into the pouring space 11, a fifth step of applying vibration to the reinforcing soil 50 with a vibrator, ) Is pressurized with a pressure roll.

More specifically, in the step 5-2, the soil, the gravel, and the cement constituted of the reinforcing soil 50 are well mixed by vibrating the reinforcing soil 50 with the vibrator, so that the reinforcing soil 50 becomes more rigid do.

In the step 5-3, the reinforcing soil 50 is pressurized by the pressure roll to prevent the soil constituting the reinforcing soil 50 from being discharged to the outside through the upper end.

6 is a schematic view showing steps 8 to 9 of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.

6, the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention includes an eighth step of forming a multi-layer retaining wall by laminating the unit retaining walls in multiple layers, And a ninth step of installing the image data.

In more detail, in the eighth step, the unit retaining walls may be vertically stacked or the unit retaining walls may be alternately stacked to form a multi-layer retaining wall.

In addition, in the ninth step, the rigidity of the reinforcing soil 50 is lowered when the water is accumulated in the reinforcing soil 50 in a rainy period, and it prevents the reinforcing soil 50 from being stiff.

7 is a schematic view showing a terminal according to the present invention.

7, the eighth step includes a step 8-1 of laminating the unit retaining walls in a multi-layered structure, and a step 8-1 of fixing the end portions of the rigid geogrid 10 formed in the unit retaining walls 8-2 and screwing the terminal 80 to the through-bolt 90. Fig.

More specifically, the step 8-2 includes the steps of forming the rigid geogrid 10 at the ends of the rigid geogrid 10 formed at the unit retaining wall (lateral direction end portion or vertical direction end portion) Direction end) of the terminal 80 is fixed.

FIG. 8 is a schematic view showing a tenth step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention, FIG. 9 is a schematic view showing an eleventh step of a retaining wall construction method using a soil cement and a rigid geogrid according to the present invention, Is a schematic view showing the twelfth step of the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention.

As shown in FIG. 8, in a tenth step, the base reinforcing bar 100 passes through the multi-layer retaining wall. At this time, the base reinforcing bar 100 passes through the concave portion of the multi-layer retaining wall, and the front end curves downward.

As shown in FIG. 9, in the eleventh step, the reinforcing bars 110 of the grid structure are coupled to the base reinforcing bars 100. At this time, the reinforcing bar 110 is welded to the front end of the base reinforcing bar 100, and the reinforcing bars formed long in the left and right direction are placed on the top of the base reinforcing bar 100, do.

As shown in FIG. 10, in step 12, a pattern plate 120 having a specific pattern formed on the front side of the supporting reinforcing bar 110 is coupled.

Accordingly, a variety of specific patterns are formed in front of the multi-layer retaining wall, thereby providing an aesthetic effect.

Meanwhile, the present invention includes a retaining wall manufactured by a retaining wall construction method using a soil cement and a rigid geogrid.

In addition, the reinforcing soil (50) includes a vegetation mat or soil cultivation soil to constitute an environmentally friendly vegetation retaining wall.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: Rigid Geogrid
11: Installation space
15: Connecting grid
20: horizontal straight line
30: iron plate
40:
50: reinforcement soil
60: aggregate layer
70: Water pipe
80: Terminal
90: Through bolt
100: base steel
110: Supported reinforcing bar
120: Gilded plates

Claims (8)

A first step of preparing a plurality of rigid geogrids 10;
A second step of arranging the rigid geogrids 10 in a mesh structure to form a plurality of pouring spaces 11;
A third step of inserting the legs of the iron plate 30 into the horizontal vertical system 20 after inserting the horizontal vertical system 20 into the recessed space 11;
A fourth step of installing a shielding film (40) made of a nonwoven fabric in a placement space (11) located in front of the rigid geogrid (10);
A fifth step of injecting a reinforcing soil (50) including soil, gravel, and soil cement into the pouring space (11);
A sixth step of removing the steel plate 30 inserted into the horizontal straightness system 20; And
And forming a unit retaining wall by forming an aggregate layer (60) behind the rigid geogrids (10).
2. The method of claim 1,
A step 2-1 of bending the rigid geogrids 10 in a zigzag manner,
A step 2-2 of arranging the rigid geogrids 10 in a mesh structure,
And a second step of stitching and joining the joining grid (15) to the jointed part of the rigid geogrids (10) by stitching them together.
The method of claim 1, wherein the fifth step
A step 5-1 of injecting the reinforcing soil 50 into the pouring space 11,
A step 5-2 of applying vibration to the reinforcing soil 50 with a vibrator,
And pressurizing the reinforcing soil (50) with a pressure roll. (5) A method of constructing a retaining wall using a soil cement and a rigid geogrid.
The method according to claim 1,
An eighth step of laminating the unit retaining walls in multiple layers to form a multi-layer retaining wall; And
And installing a drain pipe (70) in front of the multi-layer retaining wall.
5. The method of claim 4, wherein the eighth step
An eighth step of laminating the unit retaining walls in multiple layers,
An eighth step of fixing the ends of the rigid geogrid 10 formed on the unit retaining walls to the respective terminals 80,
(8-3) of screwing the terminal (80) to the through bolt (90), and a method of constructing the retaining wall using the cement and the rigid geogrid.
The apparatus according to claim 1, wherein the horizontal straightness system (20)
Retaining wall construction method using sill cement and rigid geogrid made of fiber reinforced plastics (FRP).
5. The method of claim 4,
A tenth step of penetrating the base steel bar 100 in front of the multi-layer retaining wall;
An eleventh step of coupling a supporting reinforcing bar 110 of a grid structure to the base reinforcing bar 100; And
And joining the gypsum board (120) having a specific pattern on the front side of the supporting reinforcing bar (110).
A retaining wall formed by a retaining wall construction method using a soil cement and a rigid geogrid according to any one of claims 1 to 7.

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