KR20030025369A - Retaining wall reinforcement - Google Patents

Abstract

In the reinforcing material for reinforcing the retaining wall of the present invention, an object thereof is to provide a retaining wall reinforcing material having an excellent retaining wall reinforcing effect by increasing the frictional force with the fill land deposited on the rear surface of the retaining wall.

According to the present invention, when the one or more layers of the steel frame 20 filled with the filler 80 is stacked to embed the soil retaining retaining wall 10 to be embedded in the soil 2 to prevent displacement of the steel frame 20 In the retaining wall reinforcement used as a tendon, there is provided a retaining wall reinforcement having a linear shape in which at least a part of the longitudinal section of the strip is refracted.

It is also preferred that the refracted linear of the present invention form a waveform.

More preferably, the refracted linear forms a zig-zag.

It is preferable that some longitudinal cross-sections from the ends to be connected to the steel frame 20 of the present invention are straight, and some longitudinal cross-sections from the opposite ends are refracted linearly.

Description

Corrugated Retaining Wall Reinforcement {Retaining wall reinforcement}

The present invention relates to a reinforcing material installed on a retaining wall to reinforce the retaining wall, and more particularly, to a retaining wall reinforcing material having a structure that is processed to have corrosion resistance and increases friction with soil.

Retaining wall refers to a wall that is built so that soil does not collapse in response to earth pressure. Generally, it is used to prevent ground collapse that occurs when the soil is piled up on a steeper slope or the mountain is cut. It is a structure made.

The conventional retaining wall types include a block retaining wall, a gravity concrete retaining wall, and a special reinforced concrete retaining wall. The first retaining wall includes a shaft wall, which is widely used since ancient times. Construct using concrete blocks.

Secondly, the gravity concrete retaining wall is a structure that prevents the collapse of the ground by the weight of the concrete itself, and is adopted when the height is relatively low. Third, the special reinforced concrete retaining wall is economical for the gravity concrete retaining wall because the retaining wall becomes larger. Or it is used when it is necessary to favor the use of paper with the wall vertically, and there are various forms such as an inverted T type and an auxiliary wall type. In addition, there is a simple retaining wall using a steel plate or a fence.

The retaining wall using the conventional concrete is the collapse of the retaining wall due to wind and water damage, which is because the rainwater penetrates the ground on the back of the retaining wall to weaken the ground, there is a risk that the retaining wall is collapsed due to the large earth pressure applied to the retaining wall.

In order to prevent the collapse of the retaining wall, the retaining wall is reinforced by fastening the reinforcing material on the back surface of the retaining wall and placing the reinforcing material inside the earth-filled soil deposited on the back wall of the retaining wall.

1 is a longitudinal cross-sectional view of a retaining wall stiffener according to the prior art.

The reinforcement 7 as shown in Figure 1 was made of a material of steel, geotextiles (Woven geotextiles), or geogrid (Geogrid). The front end of this reinforcing material 7 is fastened to the panel 1 or the block of concrete, and the rear end is accommodated inside the soil 2.

However, this reinforcing material (7) has a flat shape and the extensibility of the geosynthetic fiber itself, so that the reinforcing force for reinforcing the retaining soil retaining wall is weak. Steel plates having a flat shape have a relatively low frictional force, and geotextiles have a disadvantage that their reinforcement is weakened or corroded over time due to their elongation.

Therefore, in order to improve the reinforcement of the reinforcing material (7), the width of the reinforcing material (7) should be widened. In this case, the unit cost of the reinforcing material increases, and the retaining wall construction cost increases. In addition, the conventional reinforcement (7) is fixed by the angle (5) that is embedded in the concrete retaining wall (1), because the weak tensile strength (Tensile Strength), the fastening portion of the angle (5) easily breaks the reinforcement ( There is a disadvantage that 7) is easily separated from the concrete panel 1.

The present invention has been proposed in order to solve the problems of the prior art as described above, the construction can be quickly and easily construction, fastened to the retaining wall using an environmentally friendly prefabricated steel frame, has a large bearing capacity to support the retaining wall The purpose is to provide a retaining wall reinforcement resistant to corrosion resistance.

1 is a longitudinal cross-sectional view of a retaining wall stiffener according to the prior art,

Figure 2 is a cross-sectional view of the retaining wall showing the installation relationship of the retaining wall reinforcing material according to an embodiment of the present invention,

3 is a longitudinal sectional view (a) and a plan view (b) of the retaining wall stiffener shown in FIG.

4 is a partial perspective view showing the retaining wall and the reinforcing material fastened to the retaining wall shown in FIG.

5 is a perspective view showing a fastening relationship between the steel frame and the reinforcement of the retaining wall shown in FIG.

6 is a longitudinal sectional view showing a mechanism of the retaining wall stiffener shown in FIG.

♠ Explanation of symbols on the main parts of the drawings.

1, 10: retaining wall 7, 70: reinforcement

20: steel frame 21: the first L-shaped steel

22: second L-shaped steel 23: strip steel sheet

29 cover 31 side screen

32: upper screen 75: fastener

80: filling material

According to the present invention for achieving the above object, the retaining wall reinforcement is used as a tendon to be embedded in the soil to prevent the displacement of the steel frame when installing the retaining wall for soil storage by stacking one or more layers of steel frame filled with filler A retaining wall reinforcement is provided in which at least a portion of the longitudinal cross section of the strip is refracted linearly.

It is also preferred that the refracted linear of the present invention form a waveform.

More preferably, the refracted linear forms a zig-zag.

It is preferable that some longitudinal cross-sections from the ends to be connected to the steel frame of the present invention are straight, and some longitudinal cross-sections from the opposite ends are refracted linear.

In the following, with reference to the accompanying drawings a preferred embodiment of the retaining wall reinforcement according to the present invention will be described in detail.

2 is a cross-sectional view of the retaining wall showing the installation relationship of the retaining wall stiffener according to an embodiment of the present invention, Figure 3 is a longitudinal sectional view (a) and a plan view (b) of the retaining wall stiffener shown in Figure 2, Figure 4 is a partial perspective view showing the retaining wall and the reinforcing material fastened to the retaining wall shown in Figure 2, Figure 5 is a perspective view showing a fastening relationship between the steel frame and the reinforcement of the retaining wall shown in Figure 4, Figure 6 Longitudinal sectional drawing which shows a mechanism for a retaining wall stiffener.

As shown in FIGS. 2 and 3 (a) and (b), the reinforcing material 70 mainly uses a galvanized steel sheet having a wavy shape in the longitudinal direction. This reinforcing material 70 is located embedded in the earth and sand (2) is buried in the state fastened to the back surface of the retaining wall (10). And the front end of the reinforcing material 70 is fastened to the retaining wall 10, the through hole 74 is formed, is fastened to the steel frame 20 forming the retaining wall (10).

On the other hand, as shown in Figure 4, the retaining wall 10 is a steel frame 20 of the hexahedron, screens 31 and 32 are installed on the side and top and bottom of the hexahedron, and the inside of the steel frame 20 And fillers such as stones and rocks to be filled.

Steel frame 20 is the end of the twelve first L-shaped steel 21 is connected to form a hexahedron, wherein the inner surface of the first L-shaped steel 21 to face the interior of the steel frame 20 of the hexahedron Connected. Then, the cover portion 29 is fastened to the first L-shaped steel 21 in a state in which the cover portion 29 surrounds the connection portion of the first L-shaped steel 21 at the portion where the first L-shaped steel 21 is interconnected.

On the four sides of the steel frame 20, a plurality of second L-shaped steels 22 are parallel to the four sides by bolting with the upper and lower first L-shaped steels 21 on the four sides of the steel frame 20. Is fixed. Here, the second L-shaped steels 22 become members of the side screen 31.

In addition, a plurality of strip steel plates 23 are disposed along the length of the steel frame 20 in the width direction of the steel frame 20 in four first L-shaped steels 21 positioned on the upper and lower surfaces of the steel frame 20. The first L-shaped steel 21 and the strip steel plate 23 are fixed by bolting.

Here, the arrangement relationship of the steel frame 20 is to place the steel frame 20 on the ground on which the ground foundation work is completed to install the retaining wall (10). After the both ends of the steel frame 20 are fixed in close contact with each other, the one-stage retaining wall 10a having the length of the retaining wall 10 is formed, and the steel frame 20 of another layer is laminated on the one-stage retaining wall 10a. To form a two-stage retaining wall 10b. Thus, several stages are stacked to form the height of the final retaining wall 10.

On the other hand, as shown in Figure 5, a pair of through-holes 26 are formed in the middle portion of the second L-shaped steel 22 of the steel frame 20 located in the site contact with the fill.

The L-shaped fastening piece 75 is fixed to the through hole 27 formed in the second L-shaped steel 22 located on the side of the steel frame 20. A pair of through holes 77 are formed on one surface and the other surface of the fastening piece 75, respectively, and the through holes 77 formed on one surface of the fastening piece 75 correspond to the through holes 26 formed in the second L-shaped steel 22. The bolt 90 is inserted in the state, and the nut 91 is fastened and fixed to the bolt 90. In addition, the through hole 77 formed on the other surface of the fastening piece 75 is fastened and fixed with the bolt 90 and the nut 91 at a position corresponding to the pair of through holes 74 formed at the tip of the reinforcing material 70. do.

And, this reinforcing material 70 is embedded in the earth and sand (2) and is fixed by the earth pressure of the earth to be compacted. Therefore, the resistance of the retaining wall 10 against the earth pressure of the fill land is increased by this reinforcing material 70.

In the above, the front end of the reinforcing material 70 and the steel frame 20 are fastened by using the fastening piece 75. However, although not shown in the drawing, the reinforcing material bent at a right angle without using the fastening piece 75 ( 70) the tip may be fastened to the steel frame 20 with bolts and nuts.

The corrugated retaining wall stiffener constructed as described above will be described in detail.

First, in order to fill the ground, the ground on which the retaining wall 10 will be located is laid out. Thereafter, the first L-shaped steel 21, the second L-shaped steel 22, and the strip steel plate 23 are assembled as described above to form the steel frame 20 on the ground, and then the filler 80 is formed. Is filled and the one-stage retaining wall 10a is formed. And it fills in as much as the height in which the reinforcing material 70 was installed. At this time, by installing the reinforcing material 70 in the steel frame 20, and then fill up to the height to install the next reinforcing material (70).

On the other hand, after filling the height of the first stage retaining wall 10a, the steel frame 20 is assembled on the upper surface of the first stage retaining wall 10a to form the second stage retaining wall 10b. At this time, the two-stage retaining wall 10b is assembled and arranged upright from the upper surface of the one-stage retaining wall 10a. On the other hand, in another stacking method, as shown in Figure 2, the two-stage retaining wall (10b) can be laminated by moving in the land direction by a predetermined distance from the upper surface of the first-stage retaining wall (10a), which is Considering the earth pressure, it is possible to maintain the safety of construction.

In this way, the steel frame 20 of the two-stage retaining wall 10b is assembled and laminated on the upper surface of the first-stage retaining wall 10a, and the stones and rocks are formed inside the steel frame 20 of the two-stage retaining wall 10b. After filling the filler 80, the reinforcing material 70 is embedded after filling by the height of the reinforcing material to be installed.

Repeating these steps to build the retaining wall 10 to the height to fill. Since the filling material 80, such as a stone and a rock, is filled in the inside of the steel frame 20, the retaining wall 10 can plant a plant.

On the other hand, the retaining wall 10 is subjected to earth pressure to the front portion of the retaining wall 10 by the earthen soil (2). Due to the earth pressure acting on the retaining wall 10, the tensile force acts on the retaining wall 10 in the reinforcing material 70. At this time, the relationship in which the friction force between the reinforcing material 70 and the soil 2 is applied is as shown in FIG. As shown in FIG. 6, the tensile force is injected by the waveform of the reinforcing material 70, and the tensile force is dispersed, so that the reinforcing force for supporting the retaining wall 10 is improved, and the soil which presses on the upper part of the reinforcing material 70 ( The friction area with 2) can be large to offset the force acting toward the retaining wall (10).

As described in detail above, the retaining wall reinforcement of the present invention has the advantage that the force supporting the retaining soil retaining wall is large by dispersing the force acting toward the retaining wall.

In addition, since the retaining wall reinforcement material of the present invention has a large friction area with the earth and sand to be deposited, there is an advantage that the earth pressure applied from the upper portion of the reinforcement and the stress acting toward the retaining wall are mutually canceled to safely support the reinforcement soil retaining wall.

In addition, the retaining wall reinforcing material of the present invention, as described above, because the horizontal bearing force of the reinforcement soil retaining wall is large, it is possible to safely support the retaining wall sufficiently even if the width of the reinforcing material is narrowed. Therefore, there is an advantage that the manufacturing cost of the reinforcing material is reduced.

Although the technical idea of the retaining wall stiffener of the present invention has been described above with the accompanying drawings, this is illustrative of the best embodiment of the present invention and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (4)

In the retaining wall reinforcement material used as a tendon which is embedded in the earth and sand to prevent displacement of the steel frame when laminating at least one layer of the steel frame filled with fillers to install the retaining wall for soil storage, A retaining wall reinforcement, characterized in that at least a portion of the longitudinal cross section of the strip is refracted linearly. The method according to claim 1, Retaining wall reinforcement, characterized in that the refracted linear form a waveform. The method according to claim 1, Retaining wall reinforcement, characterized in that the refracted linear form a zig-zag (zig-zag) type. The method according to any one of claims 1 to 3, Some longitudinal sections from the ends to be connected to the steel frame are straight, Retaining wall reinforcement, characterized in that the longitudinal section of the part from the opposite end is a refracted linear.