KR101981432B1 - Retaining wall for vegetation having a chain wire net and stair-type front for enhancing adhesion force of green soil and, construction methods thereof - Google Patents

Abstract

The present invention relates to a vegetation retaining wall and a construction method thereof and, more specifically, to a vegetation retaining wall and a construction method thereof, wherein a chain link wire net and a stair-type front surface are used to increase an adhesion force of green soil and widen a moisture absorption area. Moreover, geogrid is used to form a counterweight fill structure, and a lightweight reinforcing wire net is used to simplify construction, reduce a period of construction, and easily supply materials. In addition, the stair-type front surface can be formed with a front surface frame having a simple structure, and the front surface frame can be reused.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vegetation retaining wall having a chain network and a stepped front wall for enhancing adhesion to green soil,

The present invention relates to a vegetation retaining wall and a method of constructing the same, and more particularly, to a vegetation retaining wall and a method of constructing the vegetation retaining wall, Since the lightweight reinforcement wire mesh is used, it is easy to construct, it is possible to shorten the air (construction period), it is easy to supply and receive materials, the front frame with simple structure can form the stepped front, Retaining wall and a construction method thereof.

Generally, the vegetation retaining wall is a retaining wall capable of vegetation on the front side, and the construction is increasing recently because it shows nature-friendly scenery.

Fig. 1 shows an example of such a vegetation retaining wall. The vegetation retaining wall comprises a front frame 10, a cover layer 20 formed on the rear side of the front frame 10, a reinforcing rod 30 installed to connect the upper and lower front frames 10, (40).

As shown in FIG. 2, the front frame 10 is made by welding the longitudinal reinforcing bars and the transverse reinforcing bars, but the longitudinal reinforcing bars are bent at an acute angle. The front frame 10 is provided with reinforcing bars 15 and 17 to prevent it from being bent due to earth pressure. When the upper and lower front frames 10 are stacked, an elastic cushion material 50 may be provided between the front frames 10. The reinforcing rod 30 is installed to connect the upper and lower front frames 10 from the front surface of the retaining wall, thereby preventing the occurrence of a call-up phenomenon.

The front frame 10 serves to form a space for compaction with the embankment. Then, the front frame 10 and the reinforcing bar 30 are buried in the retaining wall without being removed.

However, the vegetation retaining wall has a problem in that the adhesion force of the rye soil to be sprayed on the front surface of the vegetation retention wall is weak, so that the rye soil is liable to be lost after the completion of the construction, the vegetation is difficult to be activated, and the water absorption area is narrow.

Also, since the front frame 10 is complicated in structure, it is difficult to manufacture and expensive, and the front frame 10 and the reinforcing bar 30 are buried, making it difficult to recycle and economical.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems. It is an object of the present invention to provide a vegetation retaining wall having an increased adhesion of Rye soil buried on the front surface of a retaining wall, Lt; / RTI >

It is another object of the present invention to provide a vegetation retaining wall and a method of constructing the vegetation retaining wall which can form a stepped surface with a front frame having a simple structure and use only a lightweight material,

It is a further object of the present invention to provide a method for manufacturing a pressurized vegetable glaze which is easy to construct, can shorten air (construction period) and can recycle the front frame because it forms a pressed soil structure by using geogrids and uses a lightweight reinforcing wire net, Retaining wall and a construction method thereof.

A method of constructing a vegetation retaining wall according to a preferred embodiment of the present invention includes the steps of: (a) providing a front frame (120) for providing a space for fill and supporting a compaction load; (b) installing a stiffener (130); (c) after step (b), embedding and compacting the stiffener 130; (d) repeating steps (a) through (c) above the compaction of step (c) until a predetermined height is reached; (e) installing the chain link wire net 150 to cover the front surface of the vegetation retaining wall after the step (d); And (f) attaching the rye soil 160 to the front surface of the vegetation retaining wall after the step (e).

The front frame 120 of the upper layer is installed closer to the slope side than the front frame 120 of the lower layer, thereby forming a step on the front surface of the retaining wall.

It is preferable that the chain link wire net 150 is installed in a stair-like shape so as to cooperate with the stairway to improve the adhesion of Rye soil.

The stiffener 130 may include a reinforcement wire net 131 installed on the bottom or plastered layer, a nonwoven fabric 133 disposed on the reinforcing wire net 131 and geosynthetic fibers 135 disposed on the nonwoven fabric 133 have. The geosynthetic fiber 135 is preferably elongated toward the slope side.

The reinforcing member 130 is installed to extend forward from the front frame 120. After the embedding of the step (c) and the extended portion of the stiffener 130 after covering the embossed portion, And is fixed to the pin 137.

The embedding and compaction of the step (c) are performed twice, and the height of the step is preferably 30 cm to 80 cm.

Meanwhile, a vegetation mat may be further installed between the reinforcing wire net 131 and the nonwoven fabric 133.

It is preferable that the step of removing the front frame 120 between the step (c) and the step (d).

The front frame 120 may include a support and a plate 125. The support members may be installed at predetermined intervals on the back surface of the plate member 125 to support the plate member 125. [

The support base includes a metal bar (121) formed to be long toward a slope; A vertical member 122 vertically installed on the metal bar 121 to support the plate 125; And an inclined member 123 slantingly installed to connect the metal bar 121 and the vertical member 122 to support the vertical member 122.

The vegetation retaining wall 100 according to a preferred embodiment of the present invention includes a clad part 140 formed of a plurality of embedding and compaction layers 142; A stiffener 130 installed on each layer 142 to reinforce the clad part 140; A chain link wire net 150 installed to cover the front surface of the fillet 140; And rye soils 160 attached to the front surface of the clay body 140.

단면 형상으로 설치된다.The chain link wire net 150 helps to attach the rye soil 160 and the stiffener 130 is wrapped around the lower and front and top sides of each layer 142

Sectional shape.

The front surface of the upper layer 142 is formed closer to the slope than the front surface of the lower layer 142 so that a step is formed on the front surface of the clad part 140. The chain link network 150 is preferably installed in a stepped shape so as to cooperate with the step.

The present invention has the following effects.

First, since the chain link network 150 and the stepped front surface are provided, adhesion of Rye soil to the front surface of the retaining wall is improved, the vegetation survival rate is high, and the water absorption area is wide.

Second, the front frame 120 having a simple structure can be used to form a stepped surface, and since only lightweight materials are used, the work is easy and the material supply and demand is easy.

Thirdly, since the pressurized soil structure is formed by using the geogrid 135 and the lightweight reinforcement wire net 131 is used, it is possible to simplify the construction, shorten the air (construction period), and reuse the front frame 120 It is economical.

1 is a cross-sectional view showing an example of a vegetation retaining wall according to the prior art.
FIG. 2 is a perspective view showing a front frame and a reinforcing rod provided on the vegetation retaining wall of FIG. 1;
3 is a sectional view showing a vegetation retaining wall according to a preferred embodiment of the present invention.
4 to 9 are sectional views sequentially showing a construction process of the vegetation retaining wall.
10 is an exploded perspective view of the front frame;
11 is a photograph showing a stepped front surface of a retaining wall, to which a reinforcing material is applied;
12 is a photograph showing the installation of a chain link wire mesh.
FIG. 13 is a photograph showing spraying and spraying of Rye soil.
14 is a photograph showing a finished vegetation retaining wall according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely examples of the present invention and are not intended to represent all of the technical ideas of the present invention, so that various equivalents And variations are possible.

[Structure of vegetation retaining wall]

3 is a cross-sectional view showing a vegetation retaining wall according to a preferred embodiment of the present invention.

As shown in the figure, the vegetation retaining wall 100 is formed by stepwise mounting a plurality of embankment and compaction layers 142. The front surface of the upper layer 142 is located closer to the oblique side than the front surface of the lower layer 142, A staircase is formed on the front surface. The step increases the adhesion of rye soil and increases the water absorption area.

The height of each layer 142 is preferably about 30 cm to 80 cm, and most preferably 50 cm. Each layer 142 is preferably composed of two layers of clay and compaction.

If the height of the layer 142 is less than 30 cm, the number of embankments and compaction is excessively increased, which is uneconomical. If the height of the layer 142 exceeds 80 cm, the possibility of embossing is increased.

단면 형상을 갖는다. 그리고, 각 층의 윗면에는 보강재(130)를 고정시키기 위한 앵커핀(137)이 소정 간격으로 설치될 수 있다. The lower surface, the front surface, and the upper surface of the tip of each layer 142 are covered with the stiffener 130. That is, the stiffener 130

Sectional shape. Anchor pins 137 for fixing the stiffener 130 may be provided at predetermined intervals on the upper surface of each layer.

The reinforcing member 130 includes a reinforcement wire net 131 installed on the bottom surface of the reinforcing wire net 131 and a nonwoven fabric 133 laid on the reinforcing wire net 131 and geosynthetic fibers 135 laid on the nonwoven fabric 133. 11 shows a state in which the stiffener 130 is installed.

단면 형상으로 벤딩될 수 있는 것이 바람직하다. The reinforcing wire netting 131 is a lattice-type wire netting formed by laminating a transverse direction wire and a longitudinal direction wire, thereby enhancing the stability of the retaining wall and supporting the earth pressure. The reinforcing wire net 131 is made of galvanized wire having a diameter of 3.2 mm or more for corrosion prevention

It is preferable that it can be bent into a cross-sectional shape.

The nonwoven fabric 133 is intended to prevent the outflow of the gravel, retain moisture, and smoothly penetrate the roots of the plant, and is preferably a single-fiber nonwoven fabric of 350 g.

A vegetation mat (not shown) may be further provided between the reinforcing wire net 131 and the nonwoven fabric 133.

The geosynthetic fiber 135 is for securing the structural stability of the retaining wall by forming reinforcing soil. Geogrid is preferable as the geosynthetic fiber 135, but geomat, geonet, geomembrane and the like can also be used.

On the other hand, a chain link network 150 is installed on the front surface of the vegetation retaining wall 100. As shown in FIG. 12, it is preferable that the chain link network 150 is installed so as to cover the entire area from the upper end to the lower end of the retaining wall, and is installed stepwise so as to cooperate with the step on the front face of the retaining wall.

The chain link wire net 150 is known in the art as a diaphragm net, which is made by laminating resin-coated wires.

After the chain link wire net 150 is installed, the rye soil 160 is sprayed onto the front surface of the retaining wall. FIG. 13 shows the spraying process of the rye soil 160, and FIG. 14 shows the wall after the spraying of the rye soil 160 is completed.

The construction in which the chain link wire net 150 is installed in a stepwise manner on the front side of the stepped retaining wall increases the adhesive force of the rye soil 160. The rye soils 160 are preferably constructed to have a thickness of about 10 cm or more.
As shown in FIGS. 3 and 14, a step is formed on the front surface of the retaining wall by alternately repeating the small end portions 171 and the tangs 173, so that the chain link network 150 is formed with the step The planting of the jaws 173 and the small ends 171 can be performed more smoothly.

[Explanation of construction method of vegetation retaining wall]

Hereinafter, a method of constructing a vegetation retaining wall will be described with reference to FIGS.

First, as shown in FIG. 4, the ground is tapped and the pipe 112 is installed on the slope side. If necessary, the foundation 110 may be provided on the grounded ground. The compaction of the ground is such that a predetermined supporting force can be exerted in consideration of the weight of the embankment 140 and the strength of the ground.

Next, as shown in Fig. 5, the front frame 120 is installed on the bottom surface. As described above, the front frame 120 is composed of a plate member 125 and a support member. It is preferable that one plate member 125 is installed to support two or more support members. For ease of movement and installation, it is preferred that the plate 125 and the support are separable. A form widely used in a construction site may be used as the plate material 125. [

As shown in FIG. 10, the support may include a metal bar 121, a vertical member 122, and a slope member 123.

It is preferable that the metal bar (bar) 121 is made of a metal bar having a narrow width w and a small thickness in order to easily pull out the support from the ground after compaction is completed. The metal bar 121 is preferably long toward the slope and preferably has a predetermined rigidity in order to prevent the support from being conducted due to the earth pressure.

The vertical member 122 is a member vertically installed on the metal bar 121 to support the plate member 125. The vertical member 122 is inclined to connect the metal bar 121 and the vertical member 122, . The vertical member 122 and the slope member 123 may be made of metal, but may be made of wood.

After the installation of the front frame 120 is completed, a stiffener 130 is installed on the base 110 as shown in FIG. Specifically, the reinforcing wire net 131 is provided on the base 110, the nonwoven fabric 133 is laid on the reinforcing wire net 131, and the geosynthetic fibers 135 are laid on the nonwoven fabric 133. The reinforcing wire net 131, the nonwoven fabric 133 and the geosynthetic fibers 135 are installed so as to extend further forward than the predetermined position on the front face of the retaining wall (in this case, The fibers 135 cover the front frame 120).

The reinforcing wire net 131 and the nonwoven fabric 133 are provided to have a length covering the lower surface and the front surface of the front end portion of the embankment and the compaction layer 142 and the upper surface of the front end portion, It is preferable to provide the entire bottom surface, the front surface, and the top surface so as to cover the top surface.

7, the embedding is carried out after the embedding, and then the end portion of the layer 142 is sandwiched between the reinforcement wire net 131, the nonwoven fabric 133 and the geosynthetic fiber 135, And then fixed with an anchor pin 137.

It is preferable that the embankment and compaction are completed two times rather than one time. For example, if the embankment and the compaction layer 142 have a height of 50 cm, they are compaction with the first embankment at a height of 25 cm and then compaction with a second embankment at a height of 25 cm.

After completing the embedding and compaction layer 142, the front frame 120 is removed. At this time, since the thickness of the metal bar 121 is small and the width w is narrow, it can be relatively easily pulled out.

After the front frame 120 is removed, the front frame 120 is installed on the upper surface of the completed layer 142, and the above process is repeated. At this time, the front frame 120 of the upper layer is installed closer to the slope side than the front frame 120 of the lower layer in order to form the front surface of the retaining wall in a stepped manner.

After the front frame 120 is installed, the embossing layer 142 is formed to a predetermined height by repeating the above process. FIGS. 8 and 11 show the clay body 140 made by this process.

Next, as shown in FIGS. 9 and 12, a chain link wire net 150 is installed on the entire surface of the fillet 140. The chain link wire net 150 is a wire net made of resin-coated wires, known as a diaphragm net.

It is preferable that the chain link wire net 150 is installed so as to cover the entire surface from the upper end to the lower end of the clad part 140. It is preferable that the chain link network 150 is installed in a stepped shape so as to cooperate with the step of the front surface of the embankment portion 140 in order to increase the adhesion of the rye soil 160. [ That is, if the chain link network 150 is kept at a distance from the front surface of the embankment, the adhesion of the rye soil 160 can be increased, so that the chain link network 150 is installed stepwise.

 When the installation of the chain link network 150 is completed, the rye soil 160 is sprayed and attached. Fig. 13 shows spraying of rye soil, and Fig. 14 shows a wall after spraying of rye soil. It is preferred that the laver soil layer has a thickness of about 10 cm or more. The step of forming the front surface of the embankment portion 140 and the stepwise formation of the chain link network 150 increase the adhesion of the rye soil 160. [

10: front frame 15, 17: rebar
20: embankment and compaction layer 30: reinforcement rod
40: geogrid 50: elastic cushioning material
100: vegetation retaining wall 110: foundation
112: Pipe tube 120: Front frame
121: metal bar 122: vertical member
123: slope material 125: plate material
130: stiffener 131: reinforcement wire mesh
133: non-woven fabric 135: geotextile
137: anchor pin 140:
142: Embankment and compaction layer 150: Chain link wire mesh
160: Rye soil w: Width of metal bar

Claims (10)

(a) providing a front frame (120) for supporting clay and compaction;
(b) installing a stiffener (130);
(c) embedding and compacting the stiffener 130 after the step (b), drawing and removing the front frame 120 when the embedding and compaction are completed;
(d) repeating steps (a) through (c) above the compaction of step (c) until a predetermined height is reached;
(e) installing the chain link wire net 150 to cover the front surface of the vegetation retaining wall after the step (d); And
(f) attaching the rye soil 160 to the front surface of the vegetation retaining wall after the step (e)
The chain link network 150 assists in the attachment of the rye soil 160. The front frame 120 forms a space for the embankment and supports the earth pressure generated during compaction,
The front frame 120 of the upper layer is installed closer to the oblique side than the front frame 120 of the lower layer so that a step portion 171 and a step 173, Is formed,
The planting of the small end 171 and the jaw 173 can be performed more smoothly by providing the chain link wire net 150 in a stepped shape so as to cooperate with the step,
The reinforcing member 130 includes a reinforcement wire net 131 installed on a bottom surface or a compaction layer, a nonwoven fabric 133 installed on the reinforcing wire net 131, and a geogrid,
The geogrid is extended to the slope,
The stiffener 130 is installed to extend forward from the front frame 120. The embedment of the step (c) and the extended portion of the stiffener 130 after the compaction are performed on the front surface of the embankment and the compaction layer And the upper surface is covered. delete delete The method according to claim 1,
The method of claim 1, wherein the step (c) is performed twice and the height of the step is 30 cm to 80 cm. The method according to claim 1,
Wherein a vegetation mat is installed between the reinforcing wire net (131) and the nonwoven fabric (133). The method according to any one of claims 1, 4, and 5,
The front frame 120 includes a support member and a plate member 125,
Wherein the support members are installed at predetermined intervals on a rear surface of the plate member to support the plate member. The method according to claim 6,
The support includes:
A metal bar (bar) 121 formed long toward the slope;
A vertical member 122 vertically installed on the metal bar 121 to support the plate 125; And
And a slope member (123) slantingly installed to connect the metal bar (121) and the vertical member (122) to support the vertical member (122). delete delete delete

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