KR100245048B1 - Reinforced soil structure - Google Patents

Abstract

The present invention provides a reinforced earth structure. Reinforcing soil structure of the present invention by fastening the base plate and the connecting plate with a connecting strap, and also formed as a prefabricated, it is possible to fold and assemble has the effect of convenient transport and use. The reinforcement earth structure of the present invention is composed of a plurality of cells as a whole, as well as for soft ground reinforcement, as well as to construct a front wall, such as retaining wall provides a multi-purpose structure that can be used for various purposes.

Description

Reinforced earth structure

1 is a perspective view of a reinforced earth structure showing a front retaining wall according to the prior art.

Figure 2 is a perspective view of the reinforcement earth structure in accordance with a preferred embodiment of the present invention.

3 is a perspective view of a reinforced earth structure according to a second embodiment of the present invention.

4 is a perspective view of a reinforcing soil structure according to a third embodiment of the present invention.

5 is a plan view of the reinforcement earth structure according to the fourth embodiment of the present invention.

6 is a plan view of the reinforcement earth structure according to the fifth embodiment of the present invention.

7 is a front view showing a part of the reinforcement soil structure according to the sixth embodiment of the present invention.

8 is a perspective view of the reinforcement soil structure of the sixth embodiment combining the parts of FIG.

9 is a perspective view of the reinforcement earth structure according to the seventh embodiment of the present invention.

10 is a perspective view showing a part of the reinforced earth structure according to the eighth embodiment of the present invention.

11 is a plan view of an eighth embodiment in which the parts of FIG. 10 are combined;

12 is a perspective view of a reinforced earth perforation according to a ninth embodiment of the present invention.

13 is a conceptual view for explaining an embodiment of the construction method of the reinforced earth structure of the present invention.

14 is a plan view of another embodiment of FIG.

* Explanation of symbols for main parts of the drawings

100: basic plate 102: connection plate

104: connecting string 201: unit plate

205: first connecting string 207: second connecting string

304: expansion plate 306: connecting string

402: coupling groove 404: coupling hole

510: base plate member 520: front connection plate

530: intermediate connection board

The present invention relates to a reinforcement earth structure, and more particularly, to a reinforcement structure of the cell form can be folded and assembled.

Generally, reinforcement soil structures of various methods are used to reinforce soft ground or to construct front walls such as retaining walls and dams. First, an example of the reinforcement soil structure used to reinforce the soft ground is described in Japanese Patent Laid-Open No. 58-106020. Such a conventional reinforced earth structure is configured by bonding at least two or more basic plates using a synthetic resin or a metal panel at regular intervals. Therefore, such a conventional reinforcement earth structure has to be spaced to be formed so as to put the filling material such as soil when installing, there is a lot of difficulties in the construction as well as difficult to open due to the restoring force.

Also, a conventional reinforced earth structure used to form a front wall, such as a retaining wall, is shown in FIG. Figure 1a is a method developed by the engineer Henry Vidal of France, assembling a plurality of concrete plates 20 provided by protruding the reinforcement connecting ring 10 to the inner side, and the reinforcing pipe to the reinforcing material connecting ring 10 By combining the field 30 is constructed by the method of stacking the filling material such as soil on the inner surface.

On the other hand, Figure 1b is developed in the United Kingdom, the hexagonal unit members 40 are stacked in close contact with each other. In addition, the unit members 40 are fastened by connecting rods 50 penetrating through the unit members 40 in order to maintain firmness when stacked. In addition, by connecting the reinforcing straps 60 to the connecting rods 50, the construction by the method of stacking the filling material such as soil on the inner surface.

However, such a reinforcement structure of the prior art has a problem that the reinforcing straps 60 are drawn, and therefore there is a problem that the structural weakness more than a certain height is difficult to laminate.

Therefore, an object of the present invention is to solve the problems described above, and to provide a multi-purpose reinforcement soil structure that can be used at the same time for the front wall construction, such as retaining walls, as well as for softening the semi-reinforced soft ground.

Another object of the present invention is to provide a reinforcement structure of the cell form can be folded and assembled.

Another object of the present invention is to provide a reinforcement soil structure that is easy to install, excellent in stability, and thus can be constructed with a high retaining wall.

Features of the present invention for achieving the above objects is a reinforcing soil structure, at least two or more base plate forming a first hole through which the first connecting strap, the second connecting cord can penetrate A first connection string which forms a hole and connects the base plate and the connection plate through the connection plate arranged between the base plates at an adjustment interval and through the first holes of the base plate and the second holes of the connection plate. It is in the reinforcement soil structure, including.

Another feature of the present invention is a reinforcement soil structure, which is made of a flexible material, is installed in a space formed between at least two base plates and the base plate and the joints are bonded to each other at predetermined intervals, And at least one or more expansion members extending laterally in the longitudinal direction of the base plates.

In still another aspect of the present invention, in the reinforcement soil structure, at least two or more base plates having first coupling grooves formed in an elongated plate shape and formed at predetermined intervals at one side end in the longitudinal direction thereof, and in the longitudinal direction of the base plates. Reinforcing soil structure comprising a first connecting plate is fastened to the first coupling groove in a substantially orthogonal direction.

Another feature of the present invention is a reinforcing soil structure, having a predetermined thickness and elongate, fastening to the coupling groove at least two basic plate-like member and both ends having coupling grooves formed on both sides at a predetermined interval in the longitudinal direction It is formed in the reinforcing soil structure including a connecting plate-like member formed integrally, and fastening the fastening portion to the coupling grooves of the basic plate-like member facing each other.

Hereinafter, various embodiments of the present invention will be described in more detail with reference to the drawings.

2 is a perspective view of the reinforcement earth structure in accordance with a preferred embodiment of the present invention. The reinforcement soil structure according to this embodiment includes at least two base plates 100, a plurality of connecting plates 102, and connecting strings 104 connecting the base plates 100 and the connecting plates 102 to each other. ). The base plate 100 and the connecting plate 102 are formed with a plurality of through holes through which the connecting string 104 can pass. Therefore, since the connecting string 104 passes through the through holes of the base plate 100 and the connecting plate 102, the base plate 100 and the connecting plate 102 are coupled to each other. Therefore, a reinforced soil structure in the form of a cell is formed. Here, the connection plate 102 may be configured to vary the size of the space portion formed by the base plates 100 and the connection plates 102 for construction purposes.

The reinforcement earth structure of the present invention configured as described above can be transported in a state of reducing the volume by rotating the connecting plate 102, while maintaining the connection string 104 loose, by pulling the connection string 104 in the field construction Since it can be developed in the shape as shown, there is an effect that not only provides a convenient advantage in construction but also enhances the robustness. As well as. Since the reinforced earth structure of the present invention maintains the cell shape, it provides various advantages such as being used as a drainage channel with a grid selected as needed.

The filling material such as soil in the reinforcement earth structure of the above configuration may be used for ground reinforcement by putting in a plurality of lattice, as well as to form a front wall such as a retaining wall by overlapping in the upward direction.

3 is a perspective view of a reinforced earth structure according to a second embodiment of the present invention. This embodiment is essentially the same as the embodiment of FIG. However, the connecting plate 102 of FIG. 2 is divided into an upper connecting plate 102A and a lower connecting plate 102B while maintaining a predetermined distance d up and down. The reason for maintaining the distance d in this way is to absorb and disperse the shock and the load received from the vertical. Since other operations and effects are the same as those of the embodiment of FIG. 2, detailed descriptions thereof will be omitted.

4 is a perspective view of the reinforcement earth structure according to the third embodiment of the present invention. The reinforcing soil structure of this embodiment includes a plurality of unit plates 201, a plurality of connecting plates 203 installed in a direction orthogonal to each other between the unit plates 201 facing each other, and the unit plates 201. The first connection strap 205 for fastening the unit plate member 201 and the second connection strap 207 for fastening the connection plate 203 is composed of. As can be seen from the drawings, the unit board members 201 are formed with holes through which the first connecting string 205 and the second connecting string 207 can penetrate, and the connecting plates 203 A hole is formed through which the second connecting string 207 can pass.

This embodiment has the advantage that it is convenient to apply to ground, curved surface, slope, rock area, other difficult site, such as the ground is curved. Other advantages, actions, and effects are the same as those of the first and second embodiments described above, and thus redundant description is omitted.

5 is a plan view of the reinforced earth structure according to the fourth embodiment of the present invention. The reinforcement soil structure of this embodiment has a plurality of base plates 302 extending in the longitudinal direction and formed in a plate shape. The base plates 302 are made of a material such as resin or metal, and the base plates 302 adjacent to each other are made of a material such as resin or metal, and in the longitudinal direction with the long main plates 302 adjacent to each other. They are joined to each other at predetermined intervals apart. Accordingly, when the base plates 302 are pulled in a substantially vertical direction in the longitudinal direction, the number of spaces is formed in a shape as shown in FIG. 5.

A plurality of expansion members are disposed in the space portion of the substrates 302. This expansion member consists of an expansion plate 304 arranged one by one in the space portion, and a connecting string 306 for fastening the expansion plate 304 to the base plate 302. As can be understood from the figure, the connecting string 306 penetrates holes (not shown) formed in the sides of the base plates 302 and holes (not shown) formed in the mounting plates 304, thereby extending the plate. Fasteners 304 to base plates 302.

Therefore, the loosening of the connecting string 306 during transportation, the expansion plate 304 by the elastic force of the base plate by rotating the approximately 90 ° by the base plate is in close contact can minimize the volume. In addition, since the connection string 306 is tensioned at both ends when the construction site, the reinforcement earth structure of the present invention can be installed in the shape as shown. In this state, filling materials such as soil are added to complete the construction. Other actions and effects will be readily understood to be similar to the above-described embodiments.

6 is a plan view of the reinforcement earth structure according to the fifth embodiment of the present invention. The configuration of this embodiment is essentially the same as the embodiment of FIG. However, without using the extension plates in the embodiment of FIG. 5, both ends of the base plates 302 are configured to have a predetermined length between the joints constituting the connecting strap 308. It is obvious that the tie must consist of a flexible material that can be folded. Therefore, the convenience of carrying and construction has the same effect as the embodiment of FIG.

7 is a front view showing a part of the reinforcement soil structure according to the sixth embodiment of the present invention. FIG. 7A shows a base plate 401, FIG. 7B shows a first connecting plate 403, and FIG. 7C shows a second connecting plate 405. FIG. The base plate 401 is formed in an elongated plate shape, and includes first coupling grooves 402 formed at predetermined intervals on one end portion in the longitudinal direction. In addition, the base plate 401 forms a second coupling hole 404 at a predetermined interval in a straight line with the first coupling groove 402. The first connecting plate 403 forms a second coupling groove 406 that engages with the first coupling groove 402 of the base plate 401. The first connecting plate 403 is coupled in a direction orthogonal to the longitudinal direction of the base tube 401. The second connecting plate 405 is a plate member that can be inserted into the second coupling hole 404 of the base plate 401.

8 is a perspective view of the reinforcement soil structure according to the sixth embodiment combining the parts of FIG. As described above in FIG. 7, the first coupling grooves 402 of the base plates 401 are coupled to the second coupling grooves 406 of the first connection plate 403 so as to face each other, and the base plate ( The second connecting plate 405 is inserted into the second coupling hole 404 of the 401 to be fastened. In this case, it is preferable that a predetermined interval 1 is spaced between the end portions of the first connecting plate 403 and the second connecting plate 405 facing each other. The reason for this is to absorb and disperse the impact or load received from the vertical as described above. Other operations and effects are similar to the embodiments described above, so detailed description thereof will be omitted.

9 is a perspective view of a reinforced earth structure according to a seventh embodiment of the present invention. The reinforced earth structure of this embodiment is essentially similar to the embodiment of FIG. However, the second connecting plate is removed, and a plurality of plate holes 408 are formed in the base plate. By removing the second connection plate, even if a separate drainage space is not provided, there is a sphere that uses the second coupling hole 404 of the base plate 401 as a drainage path. The reason why the plurality of through-holes 408 are formed in the base plate 401 is that when the filling material such as three surfaces is filled, both ends thereof are fixed, thereby improving the rigidity.

10 is a perspective view showing a part of the reinforcement soil structure according to the eighth embodiment of the present invention. FIG. 10A shows a basic plate member 510 which has a predetermined thickness and extends long. The base plate member 510 has coupling grooves 511 formed on both sides at predetermined intervals in the longitudinal direction. Figure 10b shows a front connection plate 520 for installing on the front of the reinforced earth structure. Fastening portions 521 are formed at both ends of the front connection plate 520 to couple to the coupling grooves 511 of the base plate member 510. 10C is an intermediate connecting plate 530 fastened to form spaces of a cell structure between the base plate members 510. The intermediate connecting plate 530 has fastening portions 531 fastened to the coupling grooves 511 of the base plate member 510 at both ends.

11 is a plan view of an eighth embodiment in which the parts of FIG. 10 are combined. The reinforced earth structure according to this embodiment uses a thick reinforced concrete or metal plate or other rigid material, and is suitable for use as the front wall of the structure by laminating in multiple layers. Assembly and use of this structure will be fully understood from the foregoing description even if the description is omitted. In addition, when constructing the reinforcement soil structure of this embodiment in the ocean or waterway, etc. by stacking the structure to install a traffic path on the top of the base plate member 510, it is possible to pour the filling material in the respective cells inside the field. In addition, the structure of this embodiment may be formed integrally, not a coupling structure.

12 is a perspective view of a reinforced earth structure according to a ninth embodiment of the present invention. The structure of this embodiment shows a structure in which several reinforced earth structures of FIG. 10 are stacked. Therefore, the same reference numerals are used for the same components. As can be seen from the figure, in order to firmly stack the structure, the base plate member 510 is formed with a plurality of receiving grooves 540 penetrating the plate member up and down. Therefore, the coupling rod 550 is fastened through the receiving groove 540 when the structures are stacked. In addition, through grooves 560 are formed in the base plate member 510, the front connecting plate 520, and the intermediate connecting plate 530. Therefore, when the front wall is flexibly stacked and installed on the sea surface as the structure of this embodiment, the stability of the structure is improved as well as the effect of blocking. In addition, due to the plurality of through grooves 560 formed therein, it is possible to reduce the seawater pressure by inducing the inflow of seawater up to a predetermined distance inside the front plate by creating a drainage space of various shapes. Therefore, as well as improving the durability of the structure there is also a high stability effect.

Figure 13 is a conceptual diagram for explaining an embodiment of the construction form of the reinforced earth structure according to the present invention. As can be seen from the figure, the construction can be performed in various ways by arbitrarily adjusting the lengths of the base plate 710 and the connecting plate 720. In addition, the reinforcement earth structure of the present invention may be omitted because the wall surface is formed, the installation of formwork or demolition process.

14 relates to another embodiment of the FIG. 13 embodiment. In this embodiment, the horizontal member 810 and the vertical member 820 are integrally formed. Although the figure is shown in a plan view, the height of the horizontal member 810 and the vertical member 820 can be selectively adjusted. In addition, the horizontal member 810 and the vertical member 820 are formed with holes (not shown) through which both ends penetrate.

As described above, the reinforced earth structure of the present invention may be used in various fields as described in the following construction examples as well as used in ground reinforcement, slope stability, dams, embankments, and the like.

(Construction example 1)

When the present invention is installed in the drainage path of the soft ground, in particular, the super soft ground improvement construction, it is possible to easily secure the trafficability by horizontally distributing the ground pressure, and to prevent inequality settling occurring on the soft ground. In addition, the cell structure to maximize the stability of the ground can reduce the thickness of the mat layer and excessive fill.

(Construction example 2)

Unlike the conventional injection method of solidification treatment, the chemicals and fillers are uniformly installed in the stirrer after installing the reinforcement frame, unlike the conventional method of solidification by securing the transportation route of the soft ground or strengthening the foundation ground when constructing the structure or preventing the leachate of waste or landfill. After the solidification process is installed inside the cell by using a pump or equipment, the solidified soil is firmly attached to each other through the space formed on the wall.

In addition, by selecting a certain portion (cell) of the structure to install the granular aggregate that is breathable and drainable and separated from the solidified soil, the problem of environmental destruction due to the formation of a barrier in a wide area is solved. In addition, it is possible to reduce the thickness of the solidified layer by improving the bearing capacity by the structure, to prevent uneven sedimentation, to improve the economic efficiency and workability and quality, and to effectively cope with the environmental destruction problem by the solidification treatment.

(Construction example 3)

When the drainage space is installed in the reinforcement soil structure of the present invention and installed at the bottom of waste or garbage landfill, it is possible to induce the leachate generated from the landfill site to one place, and to spread the pressure received by the ground by stacking the landfill. This makes it possible to increase the landfill layer, especially in the case of soft soils, which prevents ground behavior or uneven settlement due to landfill loads, and is constructed by the front face of the cell structure on the front of the lip length, resulting from the sliding caused by conventional landfill loads. Plate deformation can be prevented.

(Construction example 4)

When the reinforcement earth structure of the present invention is installed on the floor of the building or the top plate of the bridge, the earth pressure caused by the passing load or vibration received by the structure is dramatically distributed and accommodated by the filler to extend the life of the structure and reduce maintenance and repair costs. Become

(Construction example 5)

When the reinforcement soil structure of the present invention is used in roadsides such as banks, retaining walls, dams, roads, railways, etc., it is possible to overcome the problems of sliding or bearing capacity and the limitation of construction height caused by the installation of a conventional face plate by a stable cell structure. In addition, since the inclined surface of the front plate can be installed vertically or darkly, it is possible to increase the land utilization rate and reduce the cost. In addition, a drainage space is formed on the wall surface of a predetermined cell formed on the front plate, and a drainage path is formed inside the structure by using sand or gravel as a filler to achieve perfect drainage.

In particular, if the structure of the present invention is installed on roads or railways, the ground can be reduced to half by improved ground stability, and in structures such as embankments, retaining walls, and dams, the thickness of the dam can be reduced by improving ground stability and bearing capacity. There is a characteristic that can be repaired by dividing a certain part.

(Construction example 6)

When the present invention is applied to underground structures such as subways, tunnels, or tunnels to form drainage channels, the hydraulic pressure received by the structure can be eliminated and the earth pressure can be reduced.

(Construction example 7)

When constructing bridge pier, hangar or cover, etc., when constructing concrete after reinforcing reinforcement using the structure of the present invention, the wall surface of the reinforcement frame does not need to be installed or removed. It is possible to build a stronger structure by forming a stronger structure.

(Construction example 8)

When the geocell front panel is applied to a shelter or breakwater, or a quay wall or other waterway structure, it is possible to freely control the blocking and passage of seawater by selectively opening and closing the cell structure of the stable front panel and the drainage space installed on the wall, so that the breakwater or the breakwater or The water barrier structure of other waterway structures can be facilitated and the structure can be stabilized. In particular, the structure of the front plate can be deformed such as bending to become a barrier to the waves, thereby reducing damage caused by typhoons or tsunamis.

Utilizing the water barrier or wave blocking device of the present invention when installing breakwater embankments, the waste of aggregates or structures to be dumped to reduce the pressure of waves or seawater as in the prior art is reduced, and the upper part of the wave blocking device structure is used as a traffic path or fishing ground. It is possible to quickly construct a composite-use structure having a feature that can be utilized as a low cost.

(Construction example 9)

When the present invention is applied to the central separator of the road, it can be utilized for the combined use of the flower bed by using the cell space in addition to the separator function, and it is easy to renovate or dismantle the installation, and in particular, the rigid structure and the deformation of the outer wall can be freely The function of the separator is improved.

(Construction example 10)

When the present invention is applied when buried with gas, oil or other irrigation water, it is easy to cope with deformation of the ground, and local soil may be used instead of sand used for reinforcement of the foundation soil.

In addition to the construction examples described above it will be understood that the application range of the reinforcement earth structure according to the present invention is various. In addition, in addition to the embodiments of the present invention described above, it will be understood that modifications may be made to various embodiments without departing from the technical scope of the claims of the present invention described below.

Claims (11)

In the reinforcing soil structure, at least two base plates having a first hole through which the first connecting string penetrates, and forming a second hole through which the first connecting string penetrates, and between the base plates. Reinforcing soil structure characterized in that it comprises a connecting plate arranged at a predetermined interval and the first connecting strap for coupling the base plate and the connecting plate through the first holes of the base plate and the second hole of the connection plate. The reinforcing soil structure of claim 1, wherein the connection plate is dually arranged up and down while maintaining a predetermined interval. The reinforcing soil structure of claim 1, wherein the reinforcing soil structure is formed integrally with each other to couple the connection plates between the base plates. The unit plate of claim 1, wherein the base plate forms a third hole through which the second connecting string can pass, and the unit plates and the plurality of unit plates separated from each other so as to couple one connecting plate at a central portion thereof. Reinforcement earth structure characterized in that it comprises a second connecting string which is fastened through the third hole. In the reinforcement earth structure, at least two base plates formed in an elongated plate shape and having a first coupling groove and second coupling grooves formed at predetermined intervals at one side end in the longitudinal direction, substantially perpendicular to the longitudinal direction of the base plates. Reinforcing soil structure comprising a first connecting plate fastened to the first coupling groove in the direction, and a second connecting plate inserted into the second coupling groove spaced apart from the lower end of the first connecting plate by a predetermined interval . The reinforcement earth structure of claim 5, wherein the base plate and / or the connecting plate are formed with through holes. In the reinforcement earth structure, having a plurality of lattice structure consisting of cross members and vertical members that intersect each other, the members can be selectively adjusted in height, and the plurality of lattice structures can be filled with different filling Reinforcement earth structure, characterized in that. 8. The reinforcement earth structure of claim 7, wherein the members are formed with holes. 8. The reinforcement earth structure of claim 7, wherein the structure forms a drainage path connected to a predetermined grid and a hole formed in the members. 9. The reinforcement earth structure of claim 8, wherein the structure is for use in regulating the flow of water. Reinforcement earth structure, characterized in that the flow of water is controlled by opening and closing the hole of the structure.