KR102112508B1 - Retaining wall construction method using soil cement and rigid geogrid - Google Patents

Abstract

The present invention is 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 pour spaces 11; A third step of inserting a horizontal vertical system 20 into the pour space 11 and then inserting a leg of the iron plate 30 into the horizontal vertical system 20; A fourth step of installing a blocking film 40 made of a non-woven material in a pour space 11 located in front of the rigid geogrids 10; A fifth step of introducing reinforcing soil 50 including soil, gravel and soil cement into the pouring space 11; A sixth step of removing the iron plate 30 inserted in the horizontal and vertical system 20; And a seventh step of forming a unit retaining wall by forming an aggregate layer 60 on the back of the rigid geogrids 10. The present invention relates to a retaining wall construction method using soil cement and a rigid geogrid.

Description

Retaining wall construction method using soil cement and rigid geogrid}

The present invention relates to a construction method of a retaining wall erected for the purpose of preventing the soil from collapsing.

In general, when building a retaining wall, unlike the concrete or steel rock, the soil does not exhibit its own predetermined strength, so various reinforcements with high tensile strength are used inside the soil to increase its adhesion to produce reinforced reinforced soil. After that, the retaining wall structure will be constructed using these reinforcing soils.

As a technology related to such a retaining wall structure, Korean Registered Patent No. 1085250, a semi-removable retaining wall block is mounted on the front of the front part, and has an average of 30 mm thick decorative stone and a seven-shaped mounting piece on the rear of the decorative stone. A bolt mounting hole formed to a depth of 15-20 mm formed on the left and right upper ends of the rear portion of the decorative stone, by applying and inserting an adhesive on the head of the bolt to the bolt mounting hole formed on the rear portion of the decorative stone Mounting the bolt, through the screw portion of the bolt through the long hole formed in the vertical portion of the seven-shaped mounting piece, the seven-shaped mounting piece is mounted on the rear portion of the decorative stone by fastening the nut, and formed on the upper end of the semi-removable retaining wall block Being ━shaped mounting part, the ━shaped mounting part is equipped with a decorative stone by inserting a locking piece of a 7-shaped mounting piece, so the decorative part of the decorative stone has a natural, natural, unique aesthetic sense of natural stone without bolt mounting holes or protruding bolts. Disclosed is a decorative stone mounting structure of a semi-removable retaining wall block characterized in that this occurs.

However, in the related art, when the retaining wall block is transported to the retaining wall construction area, the retaining wall block has a heavy weight and requires a large storage space, which causes a high transportation cost.

In addition, the prior art has a problem that requires a large space for storage of the retaining wall block.

Korean Registered Patent No. 1085250 (2011.11.14)

The present invention has been devised to solve the above-mentioned problems, and the object of the present invention is to use a retaining wall construction method using soil cement and rigid geogrid that can reduce the storage space of the retaining wall construction material and require a relatively low transportation cost of the retaining wall construction material. It is intended to provide.

The retaining wall construction method using soil cement and rigid geogrid according to the present invention includes 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 pour spaces 11; A third step of inserting a horizontal vertical system 20 into the pour space 11 and then inserting a leg of the iron plate 30 into the horizontal vertical system 20; A fourth step of installing a blocking film 40 made of a non-woven material in a pour space 11 located in front of the rigid geogrids 10; A fifth step of introducing reinforcing soil 50 including soil, gravel and soil cement into the pouring space 11; A sixth step of removing the iron plate 30 inserted in the horizontal and vertical system 20; And a seventh step of forming a unit retaining wall by forming an aggregate layer 60 behind the rigid geogrids 10.

In addition, the second step includes the 2-1 step of bending the rigid geogrid 10 zigzag, the 2-2 step of arranging the rigid geogrid 10 in a mesh structure, and the rigid geogrid 10 And a second or third step of joining the joint grids 15 through zigzag through the joints.

In addition, the fifth step is a 5-1 step of introducing a reinforcement soil 50 into the pour space 11, a 5-2 step of applying vibration to the reinforcement soil 50 with a vibrator, and the reinforcement soil 50 Step 5-3 of pressing with a pressure roll.

In addition, the eighth step of forming a multilayer retaining wall by stacking the unit retaining wall in a multi-layer; And a ninth step of installing a drain pipe 70 in front of the multilayer retaining wall.

In addition, in the eighth step, the eighth step of stacking the unit retaining walls in multiple layers and the eighth step of fixing the ends of the rigid geogrid 10 configured in the unit retaining walls, respectively, by the terminal 80, And a step 8-3 of screwing the terminal 80 with the through bolt 90.

In addition, a tenth step of penetrating the base reinforcement 100 in front of the multilayer retaining wall; An eleventh step of coupling the support reinforcing bar 110 of a lattice structure to the base reinforcing bar 100; And a twelfth step of combining a pattern plate 120 having a specific pattern formed in front of the support reinforcing bar 110.

In addition, the horizontal vertical system 20 is made of FRP (Fiber reinforced plastics) material.

Accordingly, the retaining wall construction method using the soil cement and the rigid geogrid according to the present invention has an advantage that the transport cost of the retaining wall construction material is relatively low and the storage space of the retaining wall construction material can be shortened.

1 is a schematic view showing the first to second steps of the retaining wall construction method using soil cement and rigid geogrid according to the present invention.
Figure 2 is a schematic diagram showing the third to fourth steps of the retaining wall construction method using soil cement and rigid geogrid according to the present invention.
Figure 3 is a schematic view showing the fifth step of the retaining wall construction method using a soil cement and rigid geogrid according to the present invention.
Figure 4 is a schematic view showing the sixth to seventh step of the retaining wall construction method using a soil cement and a rigid geogrid according to the present invention.
Figure 5 is a schematic diagram showing a joint grid according to the present invention.
Figure 6 is a schematic view showing the 8th to 9th steps of the retaining wall construction method using the soil cement and rigid geogrid according to the present invention.
7 is a schematic diagram showing a terminal according to the present invention.
8 is a schematic view showing a tenth step of the retaining wall construction method using soil cement and rigid geogrid according to the present invention.
9 is a schematic view showing the eleventh step of the retaining wall construction method using soil cement and rigid geogrid according to the present invention.
10 is a schematic view showing a twelfth step of a retaining wall construction method using soil cement and rigid geogrid according to the present invention.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

The accompanying drawings are only examples shown in order to explain the technical spirit of the present invention in more detail, so the technical spirit of the present invention is not limited to the form of the accompanying drawings.

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

1 is a schematic view showing the first to second steps of the retaining wall construction method using soil cement and rigid geogrid according to the present invention, and FIG. 2 is the third to the third steps of the retaining wall construction method using soil cement and rigid geogrid according to the present invention. Schematic diagram showing the fourth step, Figure 3 is a schematic diagram showing the fifth step of the retaining wall construction method using the soil cement and rigid geogrid according to the invention, Figure 4 is the sixth stage of the retaining wall construction method using the soil cement and rigid geogrid according to the invention It is a schematic diagram showing the seventh step.

As shown in FIG. 1, the first step is to prepare the basic construction material of the present invention, and prepare a number of rigid geogrids 10.

Generally, the rigid geogrid 10 is manufactured by passing a geomembrane that has passed through an extruder through a roller to form a grid-shaped hole, but in the present invention, the rigid geogrid 10 grids a plurality of unit sheets formed by cutting a fabric. After arranging in a structure, it is formed by bonding a plurality of bar contact areas with an adhesive. Accordingly, 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 pour spaces 11. At this time, the portions where the rigid geogrids 10 are in contact with each other may be fixed by separate members.

As shown in FIG. 2, in the third step, after inserting the horizontal vertical system 20 into the pour space 11, after inserting the leg of the iron plate 30 into the horizontal vertical system 20, The horizontal and vertical system 20 is fixed to the ground by moving the horizontal and vertical system 20 so that it is perpendicular to the ground.

At this time, the horizontal and vertical system 20 is a horizontal and vertical functions as a normal technique, detailed description is omitted, but may be made of fiber reinforced plastics (FRP) material to prevent damage by surrounding pressure.

In addition, the iron plate 30 includes a frame-structured body and a plurality of legs vertically connected to the body.

In the fourth step, a barrier film 40 made of a non-woven material is installed in the pour space 11 positioned in front of the rigid geogrids 10. At this time, the blocking film 40 serves to block the reinforcing soil 50 that is introduced into the pouring space 11.

As shown in FIG. 3, in the fifth step, reinforcing soil 50 is introduced into the pour space 11. At this time, the iron plate 30 serves to support the rigid geogrids 10 from falling while the reinforcing soil 50 is introduced into the pouring space 11.

As shown in FIG. 4, in the sixth step, the iron plate 30 inserted in the horizontal and vertical system 20 is removed. At this time, since the horizontal and vertical degrees are displayed on the horizontal vertical system 20, the slope 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 rigid geogrid according to the present invention uses a light weight rigid geogrid 10 as the basic wall of the retaining wall construction material, so the transport cost of the retaining wall construction material is relatively low and the retaining wall construction is required. There is an advantage that can shorten the storage space of the material.

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

As shown in FIG. 5, the second step includes steps 2-1 of bending the rigid geogrids 10 in a staggered manner, and steps 2-2 of arranging the rigid geogrids 10 in a mesh structure, And a step 2-3 in which the joint grid 15 is zigzag through the joints of the rigid geogrids 10 to join.

In more detail, in step 2-1, the rigid grids can be bent using a pressing roll.

In addition, in the second and third steps, at least two or more joint grids 15 are zigzag through the joints of the rigid geogrids 10 so that the joints of the rigid geogrids 10 are more firmly coupled. It is preferred to be combined.

Accordingly, the retaining wall construction method using soil cement and rigid geogrid according to the present invention does not use a separate adhesive for bonding between the rigid geogrids 10, and not only requires less adhesive, but also the rigid geogrids 10 It has the advantage of being very easy to combine and separate.

In addition, the fifth step is a 5-1 step of introducing a reinforcement soil 50 into the pour space 11, a 5-2 step of applying vibration to the reinforcement soil 50 with a vibrator, and the reinforcement soil 50 Step 5-3 of pressing with a pressure roll.

In more detail, in the 5-2 step, vibration of the reinforcing soil 50 is vibrated by a vibrator, so that the soil, gravel, and cement composed of the reinforcing soil 50 are well mixed, so that the reinforcing soil 50 is more robust. do.

In addition, the fifth and third steps press the reinforcing soil 50 with a pressure roll to prevent the soil formed in 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 soil cement and rigid geogrid according to the present invention.

As shown in FIG. 6, the retaining wall construction method using soil cement and rigid geogrid according to the present invention comprises an eighth step of stacking the unit retaining walls in multiple layers and a drain pipe 70 in front of the multilayer retaining wall. The installation may further include a ninth step.

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 multilayer retaining wall.

In addition, in the ninth step, when water accumulates in the reinforcing soil 50 in rain, the rigidity of the reinforcing soil 50 decreases, and serves to prevent this.

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

As illustrated in FIG. 7, the eighth step includes steps 8-1 of stacking the unit retaining walls in multiple layers, and a terminal 80 fixing the ends of the rigid geogrid 10 configured in the unit retaining walls, respectively. Steps 8-2 and the steps 8-3 of screwing the terminal 80 with a through bolt 90 are included.

In more detail, the step 8-2 includes the ends of the rigid geogrid 10 configured in the unit retaining wall (left and right ends or up and down ends) and the ends of the rigid geogrid 10 configured in other unit retaining walls (left and right ends or up and down). The terminal 80).

Figure 8 is a schematic diagram showing the tenth step of the retaining wall construction method using the soil cement and rigid geogrid according to the present invention, Figure 9 is a schematic view showing the eleventh step of the retaining wall construction method using the soil cement and rigid geogrid according to the present invention, Figure 10 Is a schematic diagram showing the twelfth step of the retaining wall construction method using soil cement and rigid geogrid according to the present invention.

As shown in FIG. 8, in the tenth step, the base reinforcing bar 100 is penetrated in front of the multilayer retaining wall. At this time, the base reinforcing bar 100 penetrates the concave portion in the multilayer retaining wall, and the shear is bent downward.

As shown in FIG. 9, in the eleventh step, the support reinforcing bar 110 having a lattice structure is coupled to the base reinforcing bar 100. At this time, the support reinforcing bar 110 is welded by reinforcing bars formed long in the vertical direction to the front end of the base reinforcing bar 100, and reinforcing bars formed long in the left and right directions are placed on the top of the base reinforcing bar 100 to weld them. do.

As illustrated in FIG. 10, in the twelfth step, a pattern plate 120 having a specific pattern formed in front of the support reinforcing bar 110 is combined.

Accordingly, by constructing various specific patterns in front of the multilayer retaining wall, it is possible to give an aesthetic effect.

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

In addition, the reinforcing soil 50 may include a vegetation mat or a soil culture soil to construct an eco-friendly vegetation retaining wall.

The present invention is not limited to the above-described embodiment, the scope of application is, of course, various modifications are possible without departing from the gist of the invention as claimed in the claims.

10: Rigid Geogrid
11: Pour space
15: joint grid
20: horizontal vertical system
30: iron plate
40: blocking film
50: reinforced soil
60: aggregate layer
70: drain pipe
80: terminal
90: through bolt
100: base rebar
110: support rebar
120: pattern

Claims (8)

A first step of arranging a plurality of unit sheets formed by cutting the fabric in a lattice structure, and preparing a plurality of rigid geogrids 10 formed by bonding the contact portions of the plurality of bars with an adhesive;
A second step of arranging the rigid geogrids 10 in a mesh structure, passing a joint grid 15 zigzag through the joints of the rigid geogrids 10 to form a plurality of pour spaces 11;
After inserting the horizontal vertical system 20 made of FRP (Fiber reinforced plastics) material in the pour space 11, a plurality of vertically connected to the main body of the frame structure and the main body inside the horizontal vertical system 20 A third step of inserting the plurality of legs of the iron plate 30 including legs;
A fourth step of installing a blocking film 40 made of a non-woven material in a pour space 11 located in front of the rigid geogrids 10;
After pouring the reinforcing soil (50) containing soil, gravel, soil cement into the pour space (11), the step of applying vibration to the reinforcing soil (50) with a vibrator and pressing the reinforcing soil (50) with a pressure roll Step 5;
A sixth step of removing the iron plate 30 inserted in the horizontal and vertical system 20; And
The seventh step of forming a unit retaining wall by forming an aggregate layer 60 on the back of the rigid geogrid (10); Retaining wall construction method using soil cement and rigid geogrid.
delete delete According to claim 1,
An eighth step of stacking the unit retaining walls in multiple layers to form a multilayer retaining wall; And
Retaining wall construction method using soil cement and rigid geogrid further comprising; a ninth step of installing a drain pipe 70 in front of the multilayer retaining wall.
The method of claim 4, wherein the eighth step
Step 8-1 of laminating the unit retaining walls in multiple layers,
Steps 8-2, in which the terminals 80 respectively fix the ends of the rigid geogrids 10 configured in the retaining walls,
Retaining wall construction method using soil cement and a rigid geogrid including the 8-3 step of screwing the terminal 80 with a through bolt 90.
delete The method of claim 4,
A tenth step of penetrating the base reinforcement 100 in front of the multilayer retaining wall;
An eleventh step of coupling the support reinforcing bar 110 of a lattice structure to the base reinforcing bar 100; And
Retaining wall construction method using soil cement and rigid geogrid further comprising; a 12th step of combining a pattern plate 120 with a specific pattern formed in front of the support reinforcing bar 110.
A retaining wall formed by a retaining wall construction method using soil cement and rigid geogrid according to any one of claims 1, 4, 5, and 7.

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