KR101071572B1 - Structure of reinforced earth retaining wall for vegetation using wire mesh and construction method of the same - Google Patents

Abstract

Disclosed is a greening reinforced retaining wall structure using a wire mesh, and a method of constructing the same. A plurality of longitudinal wires and a plurality of transverse wires are combined to form a grid shape and inclined to form a slope corresponding to the wall surface, and a plurality of longitudinal wires and a plurality of transverse wires are combined to form a grid to form a retaining wall. A structural wire mesh having a horizontal portion coupled to the inclined portion in a direction; A reinforcing wire mesh coupled to the structural wire mesh with a plurality of longitudinal wires and a plurality of transverse wires coupled to form a lattice shape and spaced apart from the inclined portion so as to face the front of the inclined portion at a predetermined distance; A tension reinforcing member coupled to the horizontal portion and disposed along the longitudinal direction of the longitudinal iron wire of the horizontal portion; A soil leakage preventing mat disposed on the rear surface of the inclined portion; Filling material is filled and compacted on the tensile reinforcing material; And the reinforcement earth retaining wall structure using the wire mesh including vegetation soil installed on the front surface of the reinforcing wire mesh to cover the structural wire mesh, by separately building a greening layer covering the structural wire mesh constituting the wall material of the reinforcing earth retaining wall to prevent fire or external impact. Damage caused by this can be prevented.

Description

Structure of reinforced earth retaining wall for vegetation using wire mesh and construction method of the same}

The present invention relates to a greening reinforced soil retaining wall structure using a wire mesh and a construction method thereof. More specifically, it is possible to construct a greening layer covering the structural wire mesh constituting the wall material of the reinforced earth retaining wall to prevent damage caused by fire or external impact, and to reinforce the retaining earth retaining wall structure using the wire mesh and its construction method. will be.

Soil is generally not strongly adhered to the particles, unlike materials such as rock, steel and concrete. Therefore, there is a limit in exerting predetermined strength only by the soil particle itself. Therefore, the retaining wall configured to install the reinforcement having a tensile force in the soil in order to increase the tensile force of the soil to integrate the soil and the reinforcing material to resist the shear shear retaining wall.

Reinforcing soil retaining wall in general is formed by connecting the reinforcement to the wall material such as blocks (blocks), concrete panels (panel), wire mesh, and the like to form and compact the soil on the reinforcement. On the other hand, in order to stabilize the wall surface of the retaining wall, a greening method of greening grass or the like on the wall surface is performed in parallel.

1 is a view for explaining the greening reinforced soil retaining wall using a wire mesh according to the prior art. Greening reinforcement earth retaining wall using a wire mesh according to the prior art repeats at least two or more layers of wall panels, which are reinforcement in the form of a wire mesh consisting of a plurality of longitudinal wires (1) and transverse wires (3) on the base crushed stone (15) After the multi-stage stacking is installed, the bottom reinforcement material such as geogrid 7 is installed at the lower end of each wall panel, and the earth and sand leakage prevention mat 13 and the vegetation mat 14 are sequentially installed on the rear of the wall panel. After laying the fill material on the floor reinforcement (7) is formed by compacting. The vegetation mat 14 is attached to the seed of the plant, and as time passes, the plant grows on the wall, recording the wall.

However, in the case of greening reinforcement soil retaining wall using a wire mesh according to the prior art, the reinforcement material and the soil leakage prevention mat are exposed on the surface of the reinforcement soil retaining wall wall, and when the fire occurs such as a forest fire, the retaining wall structure is directly exposed to the fire and damage occurs. There is a concern.

Since the reinforcement and the fill material correspond to the structural material of the reinforcement soil retaining wall, the damage of the reinforcement material and the soil leakage prevention mat means the damage of the reinforcement soil retaining wall structure itself, and thus the retaining wall itself may collapse.

In addition, since vegetation mats for vegetation of plants are arranged on the rear of the wall panel, it is difficult to recover the greening when the greening plants are damaged by fire.

2 is a photograph before the fire of the reinforcement earth retaining wall is greening, Figure 3 is a photograph after the fire of the reinforcement earth retaining wall is greening. Referring to FIG. 3, it can be seen that the greening plant 102 planted on the wall surface of the reinforcement soil retaining wall 100 is burned down to the fire, and the fabric mesh 104 constituting the wall surface material is damaged by the fire.

In addition, when constructing a levee road with greening reinforcement soil retaining wall using a wire mesh according to the prior art, there is a fear that the reinforcement and the soil leakage prevention mat is exposed to the retaining wall surface to be damaged by an external impact such as a vehicle.

Republic of Korea Patent Publication No. 10-0891299 (2009.04.06)

The present invention can provide a greening reinforcement earth retaining wall structure and construction method using a wire mesh that can prevent damage caused by fire or external impact by separately building a greening layer covering the structural wire mesh constituting the wall surface material of the reinforced earth retaining wall. .

In addition, it is possible to provide a greening reinforcement soil retaining wall structure and a construction method using a wire mesh that can be restored even if the greening layer is damaged by forming a greening layer outside the wall surface material of the reinforced soil retaining wall.

According to an aspect of the present invention, as a reinforcement earth retaining wall structure capable of greening on the wall surface, a plurality of longitudinal wires and a plurality of transverse wires are combined to form a lattice shape inclined corresponding to the wall surface, a plurality of A structural wire mesh having a horizontal wire coupled to a longitudinal wire and a plurality of transverse wires to form a lattice shape and coupled to the inclined portion in the horizontal direction inside the retaining wall; A plurality of longitudinal wires and a plurality of transverse wires are joined to form a grid shape, and a reinforcing wire mesh coupled to the structural wire mesh by being spaced apart from the inclined part so that a rear surface thereof faces the front of the inclined part; A tension reinforcing member coupled to the horizontal portion and disposed along a longitudinal direction of the longitudinal iron wire of the horizontal portion; A soil leakage preventing mat disposed on the rear surface of the inclined portion; Filling material is filled and compacted on the tensile reinforcing material; And vegetation soil installed on the front surface of the reinforcing wire mesh to cover the structural wire mesh.

The longitudinal iron wire of the horizontal portion may be formed by bending and extending the longitudinal iron wire of the inclined portion in the horizontal direction.

The reinforcement earth retaining wall structure using the wire mesh may further include a slope maintaining bar interposed between the slope and the horizontal portion to maintain the slope of the slope and the horizontal portion.

At the end of the horizontal portion, a coupling ring may be formed, and the lower end of the longitudinal iron wire of the inclined portion may be inserted into and coupled to the coupling ring.

At the bottom of the longitudinal wire of the reinforcing wire mesh, a ring portion bent in parallel with the horizontal portion, bent upward again may be formed, the end portion of the ring portion may be inserted into the coupling ring to be coupled.

The structural wire mesh and the reinforcing wire mesh may be arranged in plural in the retaining wall height direction, and the upper end of the longitudinal wire of the reinforcing wire mesh is bent to the front surface of the inclined portion and again parallel to the longitudinal wire of the inclined portion. The bending portion may be formed, in this case, the end of the connecting portion of the reinforcing wire mesh disposed at the lower end and the upper end of the longitudinal wire of the inclined portion disposed at the lower end, the coupling of the horizontal portion disposed at the upper end It can be inserted into the ring.

The lower end of the longitudinal wire of the reinforcing wire mesh, it may be bent in parallel with the horizontal portion extending to the horizontal wire of the horizontal portion, the ring portion bent upward again to be caught by the horizontal wire of the horizontal portion may be formed have.

The tensile reinforcing material may be a geogrid including a tensile strip coupled to the horizontal portion, and a transverse strip coupled to the tensile strip in the lateral direction.

A connecting ring may be formed at an end of the horizontal wire in the horizontal portion. In this case, the reinforcing earth retaining wall structure using the wire mesh, one end of the tension reinforcing material is rolled and fixed, and the connecting bar is caught on the connecting ring. It may include.

The structural wire mesh may be arranged in plural in the transverse direction such that the side ends of the structural wire mesh overlap each other, and the reinforcing wire mesh may be disposed such that the side end portions of the inclined portions overlapping each other are inward and the side ends overlap each other. It may be coupled to a plurality of the structural wire mesh.

The vegetation soil may contain seeds of green plants.

According to another aspect of the present invention, a plurality of longitudinal wires and a plurality of transverse wires are combined to form a lattice shape and inclined corresponding to the wall surface, a plurality of longitudinal wires and a plurality of transverse wires are coupled A structural wire mesh having a horizontal portion coupled to the inclined portion in a horizontal direction in the retaining wall; A plurality of longitudinal wires and a plurality of transverse wires are combined to form a grid shape, using a reinforcing wire mesh spaced apart from the inclined portion by a predetermined distance so that the rear surface is opposed to the front of the inclined portion, the reinforcing wire mesh coupled to the structural wire mesh A method of constructing a retaining wall retaining wall structure capable of connecting the reinforcing wire mesh to the structural wire mesh so that the horizontal portion of the structural wire mesh is placed on a horizontal plane, and the rear surface of the reinforcing wire mesh is spaced at a predetermined interval to face the front surface of the inclined portion. step; Coupling a tensile stiffener to the horizontal portion and disposing the tensile stiffener along a longitudinal direction of the longitudinal wire of the horizontal portion; Disposing a soil leakage preventing mat on the rear surface of the inclined portion; Filling and filling the fill material on the tensile reinforcing material; And laying vegetation soil on the front side of the reinforcing wire mesh to cover the structural wire mesh. There is provided a greening reinforcement soil retaining wall structure construction method using a wire mesh.

Coupling the reinforcing wire mesh with the structural wire mesh, the step of installing a plurality of structural wire mesh in the transverse direction so that the side ends overlap each other; And a side end portion of the structural wire mesh overlapping each other, and coupling a plurality of reinforcing wire meshes to the structural wire mesh so that the side end portions overlap each other.

According to an embodiment of the present invention, the greening layer covering the structural wire mesh constituting the wall surface material of the reinforced earth retaining wall can be separately constructed to prevent damage due to fire or external impact.

In addition, the greening layer is formed outside the wall surface of the reinforced soil retaining wall, so that the greening layer can be restored even if the greening layer is damaged.

1 is a view for explaining a greening reinforcement earth retaining wall using a wire mesh according to the prior art.
Figure 2 is a photograph of the fire before the reinforcement retaining wall made of greening.
3 is a photograph after the fire of the reinforcement soil retaining wall made of greening.
Figure 4 is a side view of the greening reinforced soil retaining wall structure using a wire mesh according to an embodiment of the present invention.
5 is a perspective view of a structural wire mesh of the greening reinforced soil retaining wall structure using a wire mesh according to an embodiment of the present invention.
6 is a perspective view of a reinforcing wire mesh of the greening reinforcement earth retaining wall structure using a wire mesh according to an embodiment of the present invention.
7 is a view for explaining the connection relationship between the tensile reinforcement of the greening reinforced soil retaining wall structure using a wire mesh according to an embodiment of the present invention.
8 is a side view of the greening reinforcement earth retaining wall structure using a wire mesh according to another embodiment of the present invention.
9 is a perspective view of a structural wire mesh of the greening reinforced soil retaining wall structure using a wire mesh according to another embodiment of the present invention.
10 is a flow chart of the greening reinforced soil retaining wall structure construction method using a wire mesh according to another embodiment of the present invention.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In the following description of the present invention, if it is determined that the detailed description of the related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, an embodiment of a greening reinforced soil retaining wall structure and a construction method using a wire mesh according to the present invention will be described in detail with reference to the accompanying drawings, and in the following description with reference to the accompanying drawings, the same or corresponding components are the same drawings. The numbering and duplicate description thereof will be omitted.

4 is a side view of the greening reinforced soil retaining wall structure using a wire mesh according to an embodiment of the present invention, Figure 5 is a perspective view of a structural wire mesh of greening reinforced soil retaining wall structure using a wire mesh according to an embodiment of the present invention, Figure 6 It is a perspective view of a reinforcing wire mesh of the greening reinforcement earth retaining wall structure using a wire mesh according to an embodiment of the present invention. And, Figure 7 is a view for explaining the connection relationship between the tensile reinforcement of the greening reinforced soil retaining wall structure using a wire mesh according to an embodiment of the present invention.

4 to 7, the structural wire mesh 12, the inclined portion 14, the horizontal portion 16, the longitudinal wires 18 and 34, the coupling ring 19 and the transverse wires 20 and 36. , Slope retaining bar (22), connecting ring (28), reinforcing wire mesh (32), ring part (38), connecting part (40), basic concrete (42), tension reinforcing material (44), connecting bar (48), earth and sand The spill prevention mat 50, the fill material 52, the vegetation soil 54, the tension strip 56, the transverse strip 58, and the geogrid 60 are illustrated.

Greening reinforcement earth retaining wall structure using a wire mesh according to the present embodiment, the plurality of longitudinal wires 18 and the plurality of transverse wires 20 are combined to form a grid shape and the inclined portion 14 inclined corresponding to the wall surface And a structural wire mesh having a plurality of longitudinal wires 18 and a plurality of transverse wires 20 coupled to each other to form a lattice shape and having a horizontal portion 16 coupled to the inclined portion 14 in the horizontal direction inside the retaining wall ( 12); The plurality of longitudinal wires 34 and the plurality of transverse wires 36 are combined to form a lattice shape, and the rear surface is spaced apart from the inclined portion 14 by a predetermined distance so as to face the front surface of the inclined portion 14. Reinforcing wire mesh 32 is coupled to; A tension reinforcing member 44 coupled to the horizontal portion 16 and disposed along the longitudinal direction of the longitudinal wire 18 of the horizontal portion 16; A soil leakage preventing mat (50) disposed on the rear surface of the inclined portion (14); Filling material 52 is filled and compacted on the tensile reinforcing material 44; And a vegetation layer 54 installed on the front side of the reinforcing wire mesh 32 to cover the structural wire mesh 12, and separately constructing a greening layer covering the structural wire mesh 12 constituting the wall material of the reinforced earth retaining wall. It can prevent damage by fire or external shock.

The structural wire mesh 12 includes a plurality of longitudinal wires 18 and a plurality of transverse wires 20 coupled to each other to form a lattice shape and an inclined portion 14 to be inclined corresponding to a wall surface, and a plurality of longitudinal wires. 18 and the plurality of transverse wires 20 are combined to form a grid shape and has a horizontal portion 16 coupled to the inclined portion 14 in the horizontal direction inside the retaining wall.

The inclined portion 14 is disposed substantially parallel to the inclination angle of the wall surface to be formed. Then, the horizontal portion 16 is disposed in the inner horizontal direction of the retaining wall to be coupled to form at the bottom of the inclined portion (14).

The angle of the inclined portion 14 with respect to the horizontal portion 16 may be changed according to the angle of the wall surface to be formed. In the present embodiment, the inclined wall is described, but it can be applied to the case of the substantially vertical straight wall.

The inclined portion 14 and the horizontal portion 16 may be formed in a lattice form by arranging a plurality of longitudinal wires 18 in parallel, and combining a plurality of transverse wires 20 in the transverse direction. have.

Horizontal wire 20 of the inclined portion 14 may be coupled to the back direction of the inclined portion (14). Accordingly, the earth pressure of the fill material 52 acts on the transverse wire 20 first, and the earth pressure acting on the transverse wire 20 acts on the longitudinal wire 18 so that the transverse wire 20 and the longitudinal direction are applied. The wires 18 may be together to support the earth pressure.

By the horizontal portion 16 of the structural wire mesh 12, the structural wire mesh 12 may be stably placed on the upper surface of the base concrete 42 or the fill material 52.

Structural wire mesh 12 serves as a structural member of the reinforcement earth retaining wall, and serves as a wall surface to hold the fill material 52 that is filled and compacted on the rear surface of the structural wire mesh 12. Therefore, there should be no damage for structural stability of the reinforced earth retaining wall.

In order to couple the inclined portion 14 and the horizontal portion 16 of the structural wire mesh 12, an end portion of the horizontal portion 16, a coupling ring 19 may be formed, and the longitudinal direction of the inclined portion 14. The lower end of the iron wire 18 may be inserted into the coupling ring 19 to be coupled. The coupling ring 19 has a ring-shaped ring shape, but in this embodiment, it presents a circular ring shape, but does not limit its shape such as a ring shape having a long hole in one direction.

The inclined holding bar 22 is for maintaining the inclination of the inclined portion 14 and the horizontal portion 16 and is interposed between the inclined portion 14 and the horizontal portion 16. In this embodiment, as the inclined retaining bar 22, hooks are formed at both ends, and the hooks at both ends are respectively formed at the intersections of the longitudinal wires 18 and the transverse wires 20 of the inclined portion 14 and the horizontal portion 16, respectively. It suggests to be installed to hang.

The angle of the inclined portion 14 with respect to the horizontal portion 16 can be easily adjusted by adjusting the length of the inclined holding bar 22. This allows the inclined portion 14 and the horizontal portion 16 constituting the structural wire mesh 12 to be manufactured in advance as a unit module in the factory, and can be applied to the reinforced soil retaining wall having various inclinations. In addition, the separation form of the inclined portion 14 and the horizontal portion 16 provides convenience in transporting the wire mesh.

In this embodiment, the inclined portion 14 and the horizontal portion 16 of the structural wire mesh 12 is shown to be separated from each other when combined with the construction, but as shown in the other embodiments to be described below the inclined portion 14 It is also possible that the horizontal portion 16 is integrally formed. In this case, the longitudinal wire 18 of the horizontal portion 16 is formed by bending and extending the longitudinal wire 18 of the inclined portion 14 in the horizontal direction, and the longitudinal wire of the horizontal portion 16 ( 18) the horizontal wire 20 is coupled in the horizontal direction to form a horizontal portion (16).

The reinforcing wire mesh 32 is formed by combining a plurality of longitudinal wires 34 and a plurality of transverse wires 36 to form a lattice shape. The back surface of the reinforcing wire mesh 32 is spaced apart from the inclined portion 14 so as to face the front of the inclined portion 14 of the structural wire mesh 12 is coupled to the structural wire mesh 12. The space between the reinforcing wire mesh 32 and the structural wire mesh 12 may be sufficiently secured vegetation space between the reinforcing wire mesh 32 and the structural wire mesh 12 so that a foundation for vegetation may be formed.

The transverse wire 36 of the reinforcing wire mesh 32 may be coupled to the front direction of the reinforcing wire mesh 32. When the vegetation soil 54, which will be described later, is sprayed to cover the structural wire mesh 12, the impact load of the vegetation soil 54 first acts on the transverse wire 36, and the impact acts on the transverse wire 36. The load may act on the longitudinal wire 34 so that the transverse wire 36 and the longitudinal wire 34 support the impact load together.

The distance between the inclined portion 14 and the reinforcing wire mesh 32 may vary depending on the thickness of the vegetation soil 54 for covering the inclined portion 14.

The reinforcing wire mesh 32 allows the vegetation soil 54 to be described later to be easily attached to the reinforcing soil retaining wall. In addition, it is possible to increase the rigidity of the wall surface material of the reinforced earth retaining wall by strengthening the coupling between the structural wire mesh 12 disposed in the transverse direction.

In order to join the structural wire mesh 12 and the reinforcing wire mesh 32, the lower end of the longitudinal wire 34 of the reinforcing wire mesh 32 is bent in parallel with the horizontal portion 16 and bent upwardly again. 38) can be formed. Accordingly, the reinforcing wire mesh 32 may be coupled to the structural wire mesh 12 by inserting an end portion of the ring portion 38 into the coupling ring 19.

On the other hand, the bottom of the longitudinal wire 34 of the reinforcing wire mesh 32 is bent in parallel with the horizontal portion 16 to extend to the horizontal wire 20 of the horizontal portion 16, the horizontal portion of the It is also possible to form a ring portion 38 that is bent upward again to be caught by the transverse wire 20. In this case, the reinforcing wire mesh 32 is coupled to the structural wire mesh 12 so that the end portion of the ring portion 38 is caught by the horizontal wire line 20 of the horizontal portion 16.

The connecting portion 40 is bent to the front surface of the inclined portion 14 at the upper end of the longitudinal wire 34 of the reinforcing wire mesh 32 and bent again in parallel with the longitudinal wire 18 of the inclined portion 14. ) May be formed. Accordingly, the end portion of the connecting portion 40 of the reinforcing wire mesh 32 is disposed in parallel with the upper end of the longitudinal wire 18 of the inclined portion 14, and this portion is tied with a tie to form the reinforcing wire mesh 32. It may be coupled to the structural wire mesh 12.

On the other hand, as in the present embodiment, when constructing a reinforced earth retaining wall by arranging a plurality of structural wire mesh 12 and the reinforcing wire mesh 32 in the retaining wall height direction, the connecting portion 40 of the reinforcing wire mesh 32 disposed at the bottom The upper end of the longitudinal wire line 18 of the inclined portion 14 disposed at the end and the lower end of the wire is inserted into the coupling ring 19 of the horizontal portion 16 of the structural wire mesh 12 disposed at the upper end thereof. 12) and the reinforcing wire mesh 32 may be combined with each other.

Tensile reinforcement 44 is coupled to the horizontal portion 16 of the structural wire mesh 12, it is disposed in the horizontal direction to be located inside the retaining wall to be formed. Tensile reinforcing material 44 is the frictional force with the landfill material 52 is increased as the landfill material 52, which will be described later is filled and compacted, and restrains the lateral displacement due to the pressure action of the landfill material (52).

As the tensile reinforcing material 44, a tensile strip in the form of a strip resistant to tension may be used. The end of the tension strip can be connected to the horizontal portion 16 and laid along the longitudinal direction of the longitudinal wire 18 of the horizontal portion 16 to fill and fill the fill material 52 for the purpose of constructing the reinforcement soil retaining wall. have.

On the other hand, as in the present embodiment, as the tensile reinforcing material 44, includes a tension strip 56 coupled to the horizontal portion 16, and a transverse strip 58 coupled laterally to the tensile strip 56. Geogrid 60 may be used. The geogrid 60 is produced in the form of a grid by combining the transverse strips 58 in the transverse direction with respect to the tensile strip 56 is subjected to a tensile force. In this case, the tension strip 56 should be disposed in the longitudinal direction of the horizontal portion 16.

In order to couple the tension reinforcement 44 to the horizontal portion 16, a hook-shaped connecting ring 28 is formed at the end of the longitudinal wire 18 of the horizontal portion 16, and the tension reinforcement 44 After rolling and fixing one end to the connecting bar 48, the connecting bar 48 can be hooked to the connecting ring 28, and the other end of the tension reinforcing material 44 can be pulled to install the tensile reinforcing material 44.

In the case where the tension strip is used as the tension reinforcing material (44), a plurality of tension strips (56) are coupled to the connection bar (48) at regular intervals by winding one end of the tension strip on the connection bar (48) and fixing it with a tie or the like. Pull the other end of the tension strip 56 in the state in which the connecting bar 48 is hooked to the link ring 28, and extend the tension strip 56 in the longitudinal direction of the longitudinal wire 18 of the horizontal portion 16. To place.

In the case where the geogrid 60 is used as the tension reinforcing material 44 as in the present embodiment, as shown in FIG. 7, the tension strips 56 have the longitudinal direction of the longitudinal wires 18 of the horizontal portion 16. One end of the geogrid 60 in the state to be arranged in the state is wound around the connecting bar 48 and fixed with a tie at a predetermined interval, and then the other side of the geogrid 60 in the state to hang the connecting bar 48 to the connecting ring 28 Pull the end to install the geogrid 60. The reason why the one end of the tension reinforcement 44 is rolled and fixed to the connecting bar 48 is that the transverse strip 58 of the geogrid 60 receives the bearing pressure of the fill material 52 rather than supporting the tensile force. This is to allow the tension strip 56 to sufficiently support the tensile force.

The soil leakage preventing mat 50 is coupled to the rear surface of the inclined portion 14 so as to face each other, and prevents the landfill material 52 from flowing out through the inclined portion 14. Non-woven fabric may be used as the soil leakage prevention mat (50).

The fill material 52 refers to an earth structure formed by being filled and compacted on the tensile reinforcement 44. The structural wire mesh 12, the tensile reinforcing material 44, and the fill material 52 is integrated with each other to form a reinforced earth retaining wall structure.

Vegetation soil 54 is installed in the front direction of the reinforcing wire mesh 32 to cover the structural wire mesh (12). The vegetation soil 54 can be easily attached to the surface of the reinforced soil retaining wall by the reinforcing wire mesh (32). According to the covering of the vegetation soil 54 and the reinforcing wire mesh 32, the structural wire mesh 12 may be located inside the retaining wall, thereby protecting it from fire or external impact load. Vegetation soil 54 is a soil reinforced with fertilizer components in a viscous soil that can secure a large amount of organic matter and soil moisture when drying, it can be sprayed by a high-pressure sprayer. On the other hand, the vegetation soil 54 may be laid in advance by mixing the seeds of the green plant in advance.

Since the reinforcing wire mesh 32 is added separately from the structural wire mesh 12 constituting the structural member of the reinforced earth retaining wall, even if the vegetation soil 54 and the reinforcing wire mesh 32 are damaged by fire or impact load, the structural wire mesh ( It is easy to restore the recording layer by rebuilding in 12).

8 is a side view of a green reinforced soil retaining wall structure using a wire mesh according to another embodiment of the present invention, Figure 9 is a perspective view of a structural wire mesh of a green reinforced soil retaining wall structure using a wire mesh according to another embodiment of the present invention.

8 and 9, the structural wire mesh 12, the inclined portion 14, the horizontal portion 16, the longitudinal wires 18 and 34, the coupling ring 19, and the transverse wires 20 and 36. , Slope retaining bar (22), connecting ring (28), reinforcing wire mesh (32), ring part (38), connecting part (40), basic concrete (42), tension reinforcing material (44), connecting bar (48), earth and sand The spill prevention mat 50, the fill material 52, the vegetation soil 54 is shown.

Unlike the above-described embodiment, the green reinforced soil retaining wall structure using the wire mesh according to the present embodiment has a form in which the inclined portion 14 and the horizontal portion 16 of the structural wire mesh 12 are integrally formed.

In order to form the structural wire mesh 12 integrally, the lower end portions of the longitudinal wires 18 and 34 of the inclined portion 14 are bent and extended in the horizontal direction to form the longitudinal wires 18 of the horizontal portion 16. The structural wire mesh 12 is formed by combining the longitudinal wires 18 of the inclined portion 14 and the transverse wires 20 in the transverse direction with respect to the longitudinal wires 18 of the horizontal portion 16. .

The shape of the reinforcing wire mesh 32 according to the present embodiment is similar to the shape of the reinforcing wire mesh 32 according to the above-described embodiment.

In order to couple the structural wire mesh 12 and the reinforcing wire mesh 32, the lower end of the longitudinal wire 34 of the reinforcing wire mesh 32 is bent in parallel with the horizontal portion 16 so that the horizontal wire of the horizontal portion 16 ( It is possible to form an annular portion 38 extending up to 20) and bent upward again to be caught by the transverse wire 20 of the horizontal portion 16. Accordingly, the reinforcing wire mesh 32 may be coupled to the structural wire mesh 12 so that the end portion of the ring portion 38 is caught by the horizontal wire 20 of the horizontal portion 16.

And, the upper end of the longitudinal wire 34 of the reinforcing wire mesh 32, the connection portion 40 is bent to the front of the inclined portion 14, and bent back in parallel with the inclined portion 14 may be formed. In this case, the end portion of the connecting portion 40 of the reinforcing wire mesh 32 is disposed in parallel with the upper end of the longitudinal wire 18 of the inclined portion 14, and tie this portion with a tie to connect the reinforcing wire mesh 32. It may be coupled to the structural wire mesh 12.

In the present embodiment, the structural wire mesh 12 and the reinforcing wire mesh 32 are separately manufactured and presented in the form of assembling during construction. However, the structural wire mesh 12 and the reinforcing wire mesh 32 may be integrally manufactured in a factory. have.

Since other components are as described above, a description thereof will be omitted.

10 is a flowchart illustrating a method for constructing a greening reinforced soil retaining wall structure using a wire mesh according to another embodiment of the present invention.

In the construction method of the green reinforced soil retaining wall structure using the wire mesh according to the present embodiment, a plurality of longitudinal wires 18 and a plurality of transverse wires 20 are combined to form a lattice shape to form a slope corresponding to the wall surface 14 and a plurality of longitudinal wires 18 and a plurality of transverse wires 20 are combined to form a grid and the horizontal portion 16 coupled to the inclined portion 14 in the horizontal direction inside the retaining wall. A structural wire mesh 12 provided; The plurality of longitudinal wires 34 and the plurality of transverse wires 36 are combined to form a lattice shape, and the structural wire mesh 12 is spaced apart from the inclined part 14 so as to face the front of the inclined part 14. As a method of constructing a reinforcement earth retaining wall structure that can be greened on a wall surface using a reinforcing wire mesh 32 coupled to the wall surface, the horizontal portion 16 of the structural wire mesh 12 is placed on a horizontal surface, and a back surface of the reinforcing wire mesh 32 is used. Coupling the reinforcing wire mesh 32 to the structural wire mesh 12 so as to be spaced apart from the front surface of the inclined portion 14 by a predetermined distance; Coupling the tensile stiffener (44) to the horizontal portion (16) and disposing the tensile stiffener (44) along the longitudinal direction of the horizontal portion (16); Disposing the earth and sand spill prevention mat (50) on the rear surface of the inclined portion (14); Filling and compacting the fill material (52) on top of the tensile reinforcement (44); And laying vegetation soil 54 on the front side of the reinforcing wire mesh 32 to cover the structural wire mesh 12.

The construction method of the greening reinforced soil retaining wall structure using the wire mesh according to the present embodiment will be described with reference to FIG.

First, the horizontal portion 16 of the structural wire mesh 12 is placed on a horizontal plane, the reinforcing wire mesh 12 so that the rear surface of the reinforcing wire mesh 32 is spaced at a predetermined interval to face the front surface of the structural wire mesh 12 To be coupled (S100). The horizontal surface may be the base concrete 42 of the retaining wall structure, or may be the upper surface of the reinforced soil retaining wall unit structure of the lower first constructed when the reinforced soil retaining wall unit structure is installed in multiple stages.

The structural wire mesh 12 is installed so that the horizontal portion 16 of the structural wire mesh 12 is placed on the upper horizontal surface of the base concrete 42. In order to couple the inclined portion 14 and the horizontal portion 16 of the structural wire mesh 12, an end portion of the horizontal portion 16, a coupling ring 19 may be formed, and the longitudinal direction of the inclined portion 14. The lower end of the iron wire 18 may be inserted into the coupling ring 19 to be coupled.

The lower end of the longitudinal iron wire 18 of the inclined portion 14 is inserted into the engaging ring 19 of the horizontal portion 16 and the inclined portion 14 and the horizontal portion 16 are interposed therebetween. Ensure the slope is maintained.

In order to join the structural wire mesh 12 and the reinforcing wire mesh 32, the lower end of the longitudinal wire 34 of the reinforcing wire mesh 32 is bent in parallel with the horizontal portion 16 and bent upwardly again. 38 may be formed, and at the upper end of the longitudinal wire 34 of the reinforcing wire mesh 32, bent to the front surface of the inclined portion 14, and parallel to the longitudinal wire 18 of the inclined portion 14. The connecting portion 40 may be formed again. In this case, the reinforcing wire mesh 32 may be coupled to the structural wire mesh 12 by inserting the end of the ring portion 38 into the coupling ring 19.

When the plurality of structural wire meshes 12 are disposed in the horizontal direction in the horizontal direction, the side ends of the structural wire meshes 12 may be arranged in the horizontal direction so as to overlap each other. This is to allow the plurality of structural wire meshes 12 arranged in the transverse direction to be integrally connected to each other.

In this case, the side end portions of the inclined portions 14 overlapping each other are located inside, and the plurality of reinforcing wire meshes 32 may be coupled to the structural wire mesh 12 so that the side ends of the reinforcing wire mesh 32 also overlap each other. The plurality of structural wire mesh 12 and the reinforcing wire mesh 32 may be connected to each other to serve as a wall surface material.

Then, the tensile stiffener 44 is coupled to the horizontal portion 16 and the tensile stiffener 44 is disposed along the longitudinal direction of the longitudinal wire 18 of the horizontal portion 16 (S200). Tensile reinforcing material 44 is the frictional force with the landfill material 52 is increased as the landfill material 52, which will be described later is filled and compacted, and restrains the lateral displacement due to the pressure action of the landfill material (52).

Then, the earth and sand leakage prevention mat 50 is disposed on the rear surface of the inclined portion 14 (S300). One surface is coupled to the rear surface of the structural wire mesh 12 to prevent the landfill material 52 from flowing out through the structural wire mesh 12. Non-woven fabric may be used as the soil leakage prevention mat (50).

Then, the landfill material 52 is filled and compacted on the tensile reinforcing material 44 (S400). The fill material 52 refers to an earth structure formed by being filled and compacted on the tensile reinforcement 44. As the fill material 52 is filled and compacted, the frictional force between the tensile reinforcing material 44 and the fill material 52 is increased, and restrains transverse displacement due to the acupressure action of the fill material 52. As a result, the structural wire mesh 12, the reinforcing wire mesh 32, the tensile reinforcing material 44, and the fill material 52 is integrated with each other to form a reinforced earth retaining wall unit structure.

When constructing a plurality of reinforced earth retaining wall unit structures in the height direction of the retaining wall to build a reinforcement retaining wall, a method of combining the upper and lower reinforced earth retaining wall unit structures with each other will be described.

The upper end of the longitudinal wire line 18 of the inclined portion 14 and the end of the connection portion 40 of the reinforcing wire mesh 32 disposed at the bottom to the top surface of the fill material 52 of the reinforcement retaining wall unit structure at the bottom is exposed The coupling ring 19 of the horizontal portion 16 of the upper structural wire mesh 12 is connected to the end of the exposed portion 40 of the lower end and the upper end of the longitudinal wire 18 of the inclined portion 14. The horizontal portion 16 is disposed on the top surface of the fill material 52 so as to be inserted. Then, the inclined portion 14 is installed so that the lower end of the inclined portion 14 of the upper structural wire mesh 12 is inserted into the coupling ring 19, so that the inclined portions of the inclined portion 14 and the horizontal portion 16 are maintained. Install the inclined holding bar (22). In this case, the reinforcing wire mesh 32 may be installed on the front of the structural wire mesh 12 so that the end of the ring portion 38 of the upper reinforcing wire mesh 32 is inserted into the coupling ring 19.

The subsequent steps are as described above. By repeating the above process, the reinforced earth retaining wall unit structure is laminated to form a reinforced earth retaining wall structure.

When the reinforced soil retaining wall structure is formed, vegetation soil 54 is installed in the front direction of the reinforced wire mesh 32 to cover the structural wire mesh 12 (S500). According to the covering of the vegetation soil 54, the structural wire mesh 12 is located inside the retaining wall, which can be protected from fire or external impact load.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

Many embodiments other than the above-described embodiments are within the scope of the claims of the present invention.

12: structural wire mesh 14: inclined portion
16: horizontal portion 18, 34: longitudinal wire
19: binding ring 20, 36: transverse wire
22: inclined retaining bar 28: connecting ring
32: reinforcing wire mesh 38: ring portion
40: connection part 42: foundation concrete
44: tensile reinforcing material 48: connecting bar
50: earth and sand leakage prevention mat 52: landfill
54: vegetation soil 56: tension strip
58: transverse strip 60: geogrid

Claims (13)

As a reinforcement retaining wall structure that can be greened on the wall,
A plurality of longitudinal wires and a plurality of transverse wires are combined to form a lattice shape and an inclined portion that is inclined corresponding to the wall surface, and a plurality of longitudinal wires and a plurality of transverse wires are combined to form a grid shape and the retaining wall A structural wire mesh having a horizontal portion coupled to the inclined portion in an inner horizontal direction;
A plurality of longitudinal wires and a plurality of transverse wires are joined to form a grid shape, and a reinforcing wire mesh coupled to the structural wire mesh by being spaced apart from the inclined part so that a rear surface thereof faces the front of the inclined part;
A tension reinforcing member coupled to the horizontal portion and disposed along a longitudinal direction of the longitudinal iron wire of the horizontal portion;
A soil leakage preventing mat disposed on the rear surface of the inclined portion;
Filling material is filled and compacted on the tensile reinforcing material; And
Retaining reinforcement earth retaining wall structure using a wire mesh, including vegetation soil is installed in front of the reinforcing wire mesh covering the structural wire mesh.
The method of claim 1,
The longitudinal iron wire of the horizontal portion,
The longitudinal iron wire of the inclined portion is bent in the horizontal direction is formed, characterized in that the green reinforcement soil retaining wall structure using a wire mesh.
The method of claim 1,
And a slope maintaining bar interposed between the slope and the horizontal portion to maintain the slope of the slope and the horizontal portion.
The method of claim 1,
At the end of the horizontal portion, a coupling ring is formed,
The lower end of the longitudinal iron wire of the inclined portion is characterized in that the coupling is inserted into the coupling ring, greening reinforced soil retaining wall structure using a wire mesh.
The method of claim 4, wherein
At the bottom of the longitudinal wire of the reinforcing wire mesh,
The ring portion is bent in parallel with the horizontal portion, and further bent upwards,
End of the ring portion is inserted into the coupling ring, characterized in that coupled, green reinforced soil retaining wall structure using a wire mesh.
The method of claim 5,
The structural wire mesh and the reinforcing wire mesh are arranged in plurality in the retaining wall height direction,
On the upper end of the longitudinal wire of the reinforcing wire mesh,
A connection portion is bent up to the front surface of the inclined portion and bent again in parallel with the longitudinal wire of the inclined portion,
An end of the connecting portion of the reinforcing wire mesh disposed at the bottom and the upper end of the longitudinal wire of the inclined portion disposed at the bottom, characterized in that inserted into the coupling ring of the horizontal portion disposed at the top, using a wire mesh Greening reinforcement retaining wall structure.
The method of claim 1,
At the bottom of the longitudinal wire of the reinforcing wire mesh,
Reinforced earth retaining wall structure using a wire mesh, characterized in that the ring is bent in parallel with the horizontal portion is extended to the horizontal line of the horizontal portion, and bent upward again to be caught by the horizontal line of the horizontal portion, .
The method of claim 1,
The tensile reinforcing material,
And a geogrid including a tension strip coupled to the horizontal portion and a transverse strip coupled to the tension strip in a lateral direction.
The method of claim 1,
A connecting ring is formed at the end of the longitudinal iron wire of the horizontal portion,
One end of the tensile reinforcing material is rolled and fixed, and further comprising a connection bar that is caught on the connecting ring, green reinforced soil retaining wall structure using a wire mesh.
The method of claim 1,
The structural wire mesh,
A plurality of side end portions of the structural wire mesh are disposed in the transverse direction so as to overlap each other,
The reinforcing wire mesh,
The side end portion of the inclined portion overlapping each other is located inside, characterized in that coupled to the plurality of structural wire mesh so that the side end portion overlap each other, greening reinforced soil retaining wall structure using a wire mesh.
The method of claim 1,
In the vegetation soil,
Greening reinforcement earth retaining wall structure using a wire mesh, characterized in that seeds of greening plants are contained.
A plurality of longitudinal wires and a plurality of transverse wires are combined to form a lattice shape and an inclined portion that is inclined corresponding to the wall surface, and a plurality of longitudinal wires and a plurality of transverse wires are combined to form a grid shape and the retaining wall inside A structural wire mesh having a horizontal portion coupled to the inclined portion in a horizontal direction; A plurality of longitudinal wires and a plurality of transverse wires are combined to form a grid shape, using a reinforcing wire mesh spaced apart from the inclined portion by a predetermined distance so that the rear surface is opposed to the front of the inclined portion, the reinforcing wire mesh coupled to the structural wire mesh As a construction method of reinforced earth retaining wall structure,
Coupling the reinforcing wire mesh to the structural wire mesh so that the horizontal portion of the structural wire mesh lies on a horizontal plane, and the rear surface of the reinforcing wire mesh is spaced apart by a predetermined distance from the front surface of the inclined portion;
Coupling a tensile stiffener to the horizontal portion and disposing the tensile stiffener along a longitudinal direction of the longitudinal wire of the horizontal portion;
Disposing a soil leakage preventing mat on the rear surface of the inclined portion;
Filling and filling the fill material on the tensile reinforcing material; And
And installing vegetation soil on the front side of the reinforcing wire mesh to cover the structural wire mesh.
The method of claim 12,
Coupling the reinforcing wire mesh to the structural wire mesh,
Installing a plurality of structural wire meshes in a transverse direction such that side ends thereof overlap each other; And
Reinforcing wall retaining wall structure construction method using a wire mesh, characterized in that the side end portion of the structural wire mesh overlapping each other is located inside, and comprising a plurality of reinforcing wire mesh to the structural wire mesh so that the side ends overlap each other. .

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