KR102003843B1 - Method for constructing a retaining wall using lightweight flowable fills - Google Patents

Abstract

The present invention relates to a method of constructing a reinforced earth retaining wall using a fluid filler, comprising the steps of: constructing a foundation on a ground to which a retaining wall is to be applied; Forming a unit wall on both sides of the base portion by joining the wall unit plates to one another in both sides of the base portion; Connecting the two unit walls to a plurality of unit horizontal connecting units so that the two unit walls are not opened; Filling and solidifying the filling space formed by the two unit walls with a fluid filler; A unit wall is formed by uniting the wall unit plates with the unit walls of the unit retaining wall including the unit walls, the unit horizontal connecting units and the solidified filler to form the unit wall on each unit wall of the unit retaining wall step; A connecting step of connecting the two unit walls to a plurality of unit horizontal connecting units so that the two unit walls are not opened; Filling the filling space formed by the two unit walls with a fluid filling material and consolidating the filling space; And repeating the unit wall forming step, the connecting step, and the filling step to a predetermined height. According to the present invention, it is minimized that an excessive load acts or settlement occurs during rainfall, and the construction period is shortened.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for constructing a reinforced earth retaining wall using a fluid filler,

The present invention relates to a method of constructing a reinforced earth retaining wall using a fluid filler.

In order to stabilize the slope, a retaining wall is constructed, and a retaining wall is constructed for flattening the slope in the embankment and cutout of roads and railways, river embankments, slopes of coastal roads and residential areas.

Generally, the retaining wall is constructed by a field installation method. Field installation methods include ground excavation, foundation concrete installation, reinforcing structure assembly and formwork installation corresponding to the retaining wall structure, concrete pouring in the formwork, and backfill construction. In this method, the reinforcing structure of the concrete is placed on the ground based on the preliminary design. Also, it takes much time to cure the concrete that has been placed in the form of self-supporting and back-filling. The construction period will be longer.

As a result, the construction cost is high and a long-term vehicle restriction is required, so that the inconvenience of citizens is large and the risk of safety accidents increases.

Korean Patent Registration No. 10-0764135 (hereinafter referred to as prior art) discloses a method of constructing blocks in a multi-tiered structure along a lateral direction and a longitudinal direction, filling the backside of the constructed blocks with a backing material Discloses a technique in which a reinforcing member is connected to a roughened block and the reinforcing member is embedded in a backing member to support the blocks. However, the prior art is advantageous in that the construction is simple and the construction period is short. However, since the blocks are formed in multiple stages, when the load is excessively applied to the upper surface of the backfill material or when the ground is weakened due to heavy rain or the like, There is a concern. In particular, when the reinforcing material is defective, there is a greater possibility of settlement and collapse.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for constructing a reinforced earth retaining wall using a fluid filled material that minimizes occurrence of an excessive load or sinkage upon rainfall.

Another object of the present invention is to provide a method of constructing a reinforced earth retaining wall using a fluid filled material that shortens a construction period.

In order to achieve the object of the present invention, there is provided a method of constructing a foundation, Forming a unit wall on both sides of the base portion by joining the wall unit plates to one another in both sides of the base portion; Connecting the two unit walls to a plurality of unit horizontal connecting units so that the two unit walls are not opened; Filling and solidifying the filling space formed by the two unit walls with a fluid filler; A unit wall is formed by uniting the wall unit plates with the unit walls of the unit retaining wall including the unit walls, the unit horizontal connecting units and the solidified filler to form the unit wall on each unit wall of the unit retaining wall step; A connecting step of connecting the two unit walls to a plurality of unit horizontal connecting units so that the two unit walls are not opened; Filling the filling space formed by the two unit walls with a fluid filling material and consolidating the filling space; And repeating the unit wall forming step, the connecting step, and the filling step to a set height, wherein the reinforcing soil retaining wall construction method using the fluid filled material is provided.

It is preferable that a sealing member is provided between two adjacent wall unit plates in the unit wall.

The sealing member is preferably a plate (packing) made of rubber.

It is preferable that the wall unit plate is formed by integrally forming two square plates having a uniform thickness and partially overlapping each other, forming a square shape of the overlapping portions, and forming a through hole in the overlapping square portion.

Wherein the wall unit unit comprises a rectangular plate portion having a uniform thickness, a rectangular stepped groove portion formed at a rear surface of the upper end portion of the rectangular plate portion with a uniform width and thickness, and a groove formed at a uniform thickness on the entire lower surface of the rectangular plate portion And a through hole formed in the center of the rectangular plate portion.

The unit horizontal connecting unit may include bolts respectively coupled to the wall unit plates facing each other, a connecting wire connecting the bolts, and a nut fastened to the bolt from the outside of the wall unit plate.

Wherein the unit horizontal connecting unit is provided with male threaded portions at both ends thereof, and the one male threaded portion penetrates through one wall unit plate across the two wall unit plates facing each other, and the other male threaded portion penetrates through the other walled unit plate An outer nut fastened to the male screw portion of the horizontal bar to be in contact with the outer surface of the wall unit unit plate and an outer nut fastened to the male screw portion of the horizontal bar to be brought into contact with the inner surface of the wall unit plate, .

And the lid is fastened to the male screw part of the horizontal bar projected outwardly to which the outer nut is fastened.

Preferably, the fluid filler comprises in situ soil, water, cement, and hydrogen peroxide . It is preferable that the amount of the useful soil in the field is 62 to 67% by weight, the water content is 20 to 30% by weight, the cement content is 3 to 10% by weight and the hydrogen peroxide is 5% by weight.

The fluid filler preferably has a curing time of 4 to 7 minutes.

The present invention is characterized in that the fluid filling material is backfilled in the filling space formed between the unit walls and the fluid filling material is solidified to integrate with the unit walls to form a retaining wall so that the settlement of the backfill is minimized and the supporting force for supporting the load is increased . It is also possible to prevent the generation of oysters on the backfill material during rainfall, thereby preventing collapse of the retaining wall due to rainfall.

Also, since the fluid filler is backfilled in the filling space between the unit walls and the fluid filler is solidified to form the retaining wall, the curing time of the fluid filler is fast, shortening the construction period.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow chart showing an embodiment of a method of constructing a reinforced earth retaining wall using a fluid filler according to the present invention;
FIG. 2 is a side view showing a base portion in an embodiment of a reinforced earth retaining wall construction method using a fluid filler according to the present invention. FIG.
3 is a side view showing a state in which a unit wall is installed in an embodiment of a reinforced earth retaining wall construction method using a fluid filler according to the present invention;
FIG. 4 is a front view showing a unit wall and a wall unit plate constituting the unit wall in the embodiment of the method of constructing the reinforced earth retaining wall using the fluid filling material according to the present invention. FIG.
FIG. 5 is a side view showing a sealing member in an embodiment of a reinforced earth retaining wall construction method using a fluid filler according to the present invention,
FIG. 6 is a front view showing a unit wall and a wall unit plate constituting the unit wall according to an embodiment of the method of constructing a reinforced earth retaining wall using the fluid filling material according to the present invention. FIG.
FIG. 7 is a side view showing a state in which a unit horizontal connecting unit is installed in an embodiment of a reinforced earth retaining wall construction method using a fluid filler according to the present invention;
FIG. 8 is a cross-sectional view of a lid fastened to a unit horizontal connecting unit in an embodiment of a method for constructing a reinforced earth retaining wall using a fluid filler according to the present invention,
9 is a side view showing another embodiment of the unit horizontal connecting unit in the embodiment of the reinforced earth retaining wall construction method using the fluid filler according to the present invention,
10 is a side view showing a state in which a fluid filler is filled in a method of constructing a reinforced earth retaining wall using a fluid filler according to the present invention,
11 is a side view of a reinforced earth retaining wall constructed according to an embodiment of a reinforced earth retaining wall construction method using a fluid filler according to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a method for constructing a reinforced earth retaining wall using a fluid filler according to the present invention will be described with reference to the accompanying drawings.

1 is a flowchart showing an embodiment of a method of constructing a reinforced earth retaining wall using a fluid filler according to the present invention.

As shown in FIG. 1, an embodiment of a method of constructing a reinforced earth retaining wall using a fluid filler according to the present invention includes steps of constructing a foundation on a ground on which a reinforced earth retaining wall is to be installed (refer to FIG. 2) ). The base portion B has a structure in which the reinforcing rods 2 are placed on the rubble 1 and the concrete 3 is laid on the bottom of the foundation. . At this time, it is preferable that the base blocks 4 are arranged on both sides in the width direction of the base portion B on both sides of the reinforced steel structure and the concrete 3 is laid integrally. It is also possible to form the foundation blocks 4 by installing the concrete blocks 3 before the concrete blocks 3 are laid and then molding the concrete blocks 3 to form the foundation blocks 4. The line connecting grooves 5 are formed on both sides of the base portion B by the base blocks 4 in a straight line.

The unitary walls W are formed on both sides of the base portion B by horizontally joining the wall unit plates 10 in one stage on both sides of the base portion B after the base portion B is applied (S2). The wall unit plates 10 are joined to the line coupling grooves 5 formed by the base block 4 of the base portion B. As shown in FIG. 4, the wall unit plate 10 includes two square plates 11 having a uniform thickness, which are integrally formed by overlapping one another. The upper part (the navigator part) 14, in which the two square plates 11 are not overlapped, and the lower part 13, which is the lower part of the square part 12, And the widths of the portions (silver portions) 15 are equal to each other. The lower non-overlapping portion 15 of the wall unit plate 10 is inserted into the line coupling groove 5 of the base portion B and engaged. The two adjacent wall unit plates 10 constituting the unit wall W are joined while overlapping the non-overlapping portions. 5, the sealing member S is coupled between the line coupling groove 5 of the base portion B and the lower non-overlapping portion 15 of the wall unit plate 10, It is preferable that the sealing member S is coupled to the coupling portion of the two sheets of the wall unit plates 10. The sealing member S is preferably a rubber plate (or packing).

6, the wall unit plate 10 'has a rectangular plate portion 16 having a uniform thickness, and a rectangular plate portion 16 having a uniform thickness. The wall unit plate 10' A rectangular stepped protrusion 18 formed by a groove formed to have a uniform thickness on the entire lower surface of the lower end of the rectangular plate portion 16, And a through hole 13 formed in the center. It is preferable that the size and depth of the rectangular stepped groove portion 17 are equal to each other in the size and thickness of the rectangular stepped protrusion portion 18 so that the rectangular stepped protrusion portion 18 can be formed into the rectangular stepped groove portion 17. [ The rectangular stepped protrusion 18 which is the lower side of the wall unit plate 10 is inserted into the line coupling groove 5 of the base portion B and is engaged. It is preferable that the sealing member S is coupled between the line connecting groove 5 of the base portion B and the rectangular stepped protrusion 18 of the wall unit plate 10. The sealing member S is preferably a rubber plate (or packing).

The wall unit plate can be implemented in various forms.

The unit walls W are formed on both sides of the base portion B and then the two unit walls W are connected to the plurality of unit horizontal connecting units 20 so that the two unit walls W do not spread The step S3 proceeds (see Fig. 7). It is preferable that the unit horizontal connecting unit 20 connects the wall unit plates 10 facing each other one on the other. The unit horizontal connecting unit 20 includes bolts 21 that are respectively coupled to the wall unit plates 10 facing each other and connecting wires 21 that connect the bolts 21 to each other, And a nut 23 which is fastened to the bolt 21 on the outside of the wall unit plate 10. A bolt 21 is inserted into the through hole 13 of one of the wall unit plates 10 facing each other and the nut 23 is fastened to the bolt 21, The bolt 21 is inserted into the through hole 13 of the wall unit plate 10 and the nut 23 is fastened to the bolt 21. At this time, the nut 23 is fastened to the outside of the wall unit plate 10. It is preferable that the lid 27 is fastened to the bolt 21 protruding outside the nut 23 as shown in Fig.

9, the unit horizontal connecting unit 20 'is provided with two male threaded portions 24a at both end portions thereof and two wall unit plates 10' facing each other, A horizontal bar 24 through which one screw thread section passes through one wall unit plate 10 and the other screw thread section 24a passes through another one of the wall unit plates 10, An outer nut 25 which is fastened to the male screw thread portion 24a of the horizontal bar 24 so as to be brought into contact with the outer surface of the horizontal bar 24 so as to be brought into contact with the outer surface of the horizontal bar 24, And an outer nut 26 that is fastened to the outer surface 24a. The male screw portion 24a of the horizontal bar 24 is inserted through the through hole 13 of the wall unit plate 10. [ It is preferable that the lid 27 is fastened to the male screw portion 24a of the horizontal bar 24 protruding outside the outer nut 26. [

The unit horizontal connecting units 20 are connected to the two unit walls W and then the filling space formed by the two unit walls W is filled with the fluid filler 30 and solidified in step S4 (See Fig. 10). It is preferable that the fluid filler 30 is filled above or below each overlap portion 12 of the wall unit plates 10 of the unit wall W. [ The fluid filler 30 preferably comprises on-site useful soil, water, cement, and hydrogen peroxide . More preferably, it is 62 to 67 wt%, the water is 20 to 30 wt%, the cement is 3 to 10 wt%, and the hydrogen peroxide is 5 wt%. The cement comprises lime and the lime is preferably 10% of the weight of the cement. It is desirable to determine the exact ratio of ingredients in accordance with the amount of # 200 throughput (finely divided) of the useful soil on site. For example, according to the experimental data, when the amount of # 200 passing through the field useful soil is 10, it includes 67% by weight of on-site useful soil, 25% by weight of water, 3% by weight of cement and 5% by weight of hydrogen peroxide.

As described above, the fluidity filler 30 has a curing time of 4 to 7 minutes. In addition, the above mixing ratio maintains the highest back pressure strength while re-excavation is possible.

The fluidized filler 30 is filled in the filling space and cemented, and then the unit walls W, the unit horizontal connecting units 20 and the unit wall W of the unit retaining wall including the filled padding material are respectively mounted on the wall unit plates 10 are combined in one step to form a unit wall forming step S5 in which another unit wall W is formed on the unit walls W of the unit retaining wall. The wall unit plate 10 constituting another unit wall W is the same as the wall unit plate 10 constituting the unit wall W of the unit retaining wall. The upper non-overlapping portion 14 of the wall unit plate 10 of the unit retaining wall and the lower non-overlapping portion 14 of the wall unit plate 10 when the wall unit plate 10 is coupled to the unit walls W of the unit retaining wall 15).

A connecting step S6 is performed in which two unit walls W are connected to a plurality of unit horizontal connecting units 20 so that two unit walls W are not opened after the unit wall forming step. The unit horizontal connecting unit 20 is the same as the unit horizontal connecting unit 20 constituting the unit retaining wall.

After the connection step, the filling space formed by the two unit walls W is filled with the fluid filler 30 and the filling step S7 is performed. The fluid filler 30 is the same as the fluid filler 30 described above. As the unit wall forming step, the connecting step, and the filling step are performed, another unit retaining wall integrally connected to the unit retaining wall is formed on the unit retaining wall.

Then, a step S8 of repeating the unit wall forming step, the connecting step, and the filling step is repeated until the set height is reached (refer to FIG. 11).

Hereinafter, the operation and effect of the method of constructing the reinforced earth retaining wall using the fluid filler according to the present invention will be described.

The present invention relates to a method of manufacturing a reinforced earth retaining wall in which a concrete base portion (B) is applied to a foundation where a reinforced earth retaining wall is to be installed, and a unit space in which a filling space is formed by joining the wall unit plates (10) A wall W is formed and connected to the unit horizontal connecting unit 20 so that the wall unit plates 10 facing each other among the wall unit plates 10 of the unit wall W are not opened, The unit retaining wall is constructed by backfilling and cementing with the fluid filling material 30 and the unit retaining wall is repeatedly constructed up to the height set on the unit retaining wall.

As described above, according to the present invention, the fluid filling material 30 is backfilled in the filling space formed between the unit walls W, and the fluid filling material 30 is solidified and integrated with the unit walls W to form a retaining wall. Not only the settlement is minimized but also the supporting force for supporting the load is increased. It is also possible to prevent the generation of oysters on the backfill material during rainfall, thereby preventing collapse of the retaining wall due to rainfall.

Also, since the fluid filler 30 is backfilled in the filling space between the unitary walls W and the fluid filler 30 is solidified to form a retaining wall, the curing time of the fluid filler 30 is fast, .

10; Wall unit plate 20; Unit horizontal connecting unit
30; Flowable filler B; Base portion
W; Unit wall

Claims (10)

Constructing a foundation part on a ground to which a retaining wall is to be applied, comprising the steps of providing a base block such that straight line connecting grooves are formed on both sides of the base part;
Forming a unit wall on both sides of the base by joining the wall unit plates horizontally in one stage on both sides of the base;
Connecting the two unit walls to a plurality of unit horizontal connecting units so that the two unit walls are not opened;
Filling and solidifying the filling space formed by the two unit walls with a fluid filler;
A unit wall is formed by uniting the wall unit plates with the unit walls of the unit retaining wall including the unit walls, the unit horizontal connecting units and the solidified filler to form the unit wall on each unit wall of the unit retaining wall step;
A connecting step of connecting the two unit walls to a plurality of unit horizontal connecting units so that the two unit walls are not opened;
Filling the filling space formed by the two unit walls with a fluid filling material and consolidating the filling space;
Repeating the unit wall forming step, the connecting step, and the filling step to a set height,
Wherein the wall unit unit plate is formed by integrally forming two square plates having a uniform thickness, wherein the wall unit unit plates are integrally formed by overlapping only a part of the square unit plates, the overlapped portions forming a square, a through hole formed at the center of the overlapping square portions, Wherein the non-overlapping upper and lower portions of the square unit plates are formed to have the same width so that the lower non-overlapping portions of the wall unit plates are inserted and joined to the line connecting grooves of the base portion, The wall unit plates are joined while overlapping the non-overlapping portions,
Wherein the unit horizontal connecting unit includes bolts respectively coupled to the wall unit plates facing each other, a connecting wire connecting the bolts, and a nut fastened to the bolt from the outside of the wall unit plate,
Wherein the fluidity filler comprises in situ useful soil, water, cement, hydrogen peroxide, wherein the field useful soil comprises 62-67 wt%, water is 20-30 wt%, cement is 3-10 wt%, hydrogen peroxide is 5 % ≪ / RTI &
Wherein the flowable filler has a cementation time of 4 to 7 minutes. The method as claimed in claim 1, wherein a sealing member is provided between two adjacent wall unit plates adjacent to each other in the unit wall. The method as claimed in claim 2, wherein the sealing member is a rubber plate. delete delete delete delete delete delete delete

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