KR102549947B1 - Eco-friendly vegetation wire mesh composite mat for reinforcement and restoration of slopes and its construction method - Google Patents

Abstract

The present invention relates to an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration and a method of constructing the same, and in particular, the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration is disposed along a slope, and the interior through an open upper surface. a lower wire mesh filled with gabionite; An upper wire mesh installed on the upper surface of the lower wire mesh and filled with soil through the open upper surface; a first geotextile nonwoven fabric installed on the bottom surface of the upper wire mesh; A seed mat installed on the upper surface of the upper wire netting with vegetation seeds attached thereto; a cover wire mesh installed on the upper surface of the seed mat; It is configured to include a; cover reinforcement crossbar installed on the upper surface of the cover wire mesh, and the slope is reinforced and the vegetation of the slope is restored, so that the environment of the slope naturally matches the surrounding environment.

Description

Eco-friendly vegetation wire mesh composite mat for reinforcement and restoration of slopes and its construction method {Eco-friendly vegetation wire mesh composite mat for reinforcement and restoration of slopes and its construction method}

The present invention relates to an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration and a method for constructing the same, and in particular, an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration to enable vegetation on the slope while reinforcing and restoring the damaged slope, and It's about how it's built.

Since Korea is a mountainous terrain, when building roads or various buildings, slopes are inevitably formed on both sides of the road or around the building.

Accordingly, methods that are generally implemented to reinforce slopes include a method of constructing a slope by applying cement to the slope and a method of constructing a slope using gabion (gabion).

However, since the method of constructing a slope with cement is to work with cement concrete on the slope, there is a disadvantage in that it is not environmentally friendly and insipid because plants cannot grow on the slope.

Due to these problems, the Gabion method was subsequently developed. Stone materials such as waste natural stones or broken stones are filled in a polygonal body made of metal wire mesh, and then the lid of the wire mesh is closed, and the wire mesh is seated and stacked on the slope in the vertical and horizontal directions.

This gabion method has the advantage of being able to circulate air between the slope and the atmosphere, discharging runoff water very smoothly by the water pressure at the back of the slope, and looking good, but there is a risk of soil loss on the slope and cement As with the construction of slopes by landslides, there is a problem that it is difficult for plants to grow.

Publication No. 10-2018-0131918 (Application No.: 10-2017-0068649, Title of Invention: Slope Vegetation Method Using Gabion)

The present invention has been made to solve the above-mentioned problems of the prior art, while reinforcing and restoring the damaged slope using gabion, and at the same time enabling vegetation on the slope to be naturally linked to the surrounding environment. Eco-friendly for slope reinforcement and restoration The purpose is to provide a vegetation wire mesh composite mat and its construction method.

An eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention for solving the above problems includes a lower wire mesh disposed along a slope and filled with gabionite therein through an open upper surface; An upper wire mesh installed on the upper surface of the lower wire mesh and filled with soil through the open upper surface; a first geotextile nonwoven fabric installed on the bottom surface of the upper wire mesh; A seed mat installed on the upper surface of the upper wire netting with vegetation seeds attached thereto; a cover wire mesh installed on the upper surface of the seed mat; It is configured to include; a cover reinforcing crossbar installed on the upper surface of the cover wire mesh.

In addition, the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention includes a lower wire mesh disposed along the slope and filled with gabionite therein through an open upper surface; a first geotextile nonwoven fabric installed on the upper surface of the lower wire mesh; an upper wire mesh installed on the upper surface of the first geotextile nonwoven fabric and filled with earth and sand through the open upper surface; An intermediate reinforcing crossbar installed on the bottom surface of the upper wire mesh; A seed mat installed on the upper surface of the upper wire netting with vegetation seeds attached thereto; a cover wire mesh installed on the upper surface of the seed mat; It may be configured to include; a cover reinforcing crossbar installed on the upper surface of the cover wire mesh.

Here, it is configured to further include a second geotextile nonwoven fabric installed between the bottom surface and the slope of the lower wire mesh.

In addition, the lower wire mesh is partitioned into a plurality of inner spaces by partition wire meshes installed therein.

In addition, the seed mat and the vegetation; Vegetation seeds attached to the upper surface of the vegetation; A PE geomok net laminated on the upper surface of the vegetation seed; It consists of a non-woven fabric laminated on the upper surface of the PE geomock net.

In addition, the lower wire mesh, the upper wire mesh, and the cover wire mesh are formed by arranging galvanized wire crosswise in the vertical and horizontal directions.

On the other hand, the construction method of the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention includes the steps of evenly arranging the slope; A step of fixing the lower wire mesh, the inner space of which is partitioned by the partition wire mesh and whose top surface is open, to the slope with reinforcing bar piles; filling the inside of the lower wire mesh with gabionite; installing a first geotextile nonwoven fabric on the upper surface of the lower wire mesh; installing an upper wire mesh with an open upper surface and an inner space formed on the upper surface of the first geotextile nonwoven fabric; installing an intermediate reinforcing crossbar on the bottom surface of the upper wire mesh; compacting after laying earth and sand inside the upper wire mesh; Installing a seed mat to which vegetation seeds are attached on the upper surface of the upper wire mesh; installing a cover wire mesh on the upper surface of the seed mat; It is configured to include; installing a cover reinforcement crossbar on the upper surface of the cover wire mesh.

In addition, the construction method of the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention includes the steps of evenly arranging the slope; A step of fixing the lower wire mesh, the inner space of which is partitioned by the partition wire mesh and whose top surface is open, to the slope with reinforcing bar piles; filling the inside of the lower wire mesh with gabionite; Installing an upper wire mesh with an open upper surface and an inner space on the upper surface of the lower wire mesh; installing a first geotextile nonwoven fabric on the bottom surface of the upper wire mesh; compacting after laying earth and sand inside the upper wire mesh; Installing a seed mat to which vegetation seeds are attached on the upper surface of the upper wire mesh; installing a cover wire mesh on the upper surface of the seed mat; It may be configured to include; installing a cover reinforcement crossbar on the upper surface of the cover wire mesh.

Here, a step of installing a second geotextile nonwoven fabric on an evenly arranged slope before installing the lower wire mesh is further included.

Eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration of the present invention configured as described above and its construction method have a lower wire mesh filled with gabion stone installed on the slope to reinforce the slope, and the vegetation seeds attached to the seed mat As the vegetation on the slope is restored through growth, there is an advantage that the environment of the slope naturally blends with the surrounding environment.

In addition, there is an advantage in that it is possible to block the occurrence of a full stomach phenomenon due to tortoise or gabion being tilted to one side by the cover reinforcement crossbar and the middle reinforcement crossbar.

1 is a view showing the installation of an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention.
Figure 2 is an enlarged view of the eco-friendly vegetation wire mesh composite mat shown in FIG.
Figure 3 shows an embodiment of an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention.
Figure 4 is a view showing another embodiment of the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention.
Figure 5 is a diagram showing the eco-friendly vegetation wire mesh composite mat shown in FIG.
Figure 6 is a diagram showing the eco-friendly vegetation wire mesh composite mat shown in FIG.
Figure 7 is a block diagram showing an eco-friendly vegetation wire mesh composite mat construction method for slope reinforcement and restoration according to the present invention.

Hereinafter, an embodiment of an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention and a construction method thereof will be described in detail with reference to the accompanying drawings.

1 is a diagram showing the installation of an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention, and FIG. 2 is an enlarged view of the environmentally friendly vegetation wire mesh composite mat shown in FIG.

And, Figure 3 is a diagram showing an embodiment of an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention, Figure 4 is another embodiment of an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention It is an example diagram.

In addition, FIG. 5 is a view showing the eco-friendly vegetation wire mesh composite mat shown in FIG. 3, and FIG. 6 is a view showing the eco-friendly vegetation wire mesh composite mat shown in FIG.

Eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention includes a lower wire mesh 10, an upper wire mesh 20 installed on the upper surface of the lower wire mesh 10, and an upper wire mesh 20 on the bottom surface. The first geotextile nonwoven fabric 30 installed, the seed mat 40 installed on the upper surface of the upper wire mesh 20 with the vegetation seeds 42 attached thereto, and the seed mat 40 installed on the upper surface It is configured to include a cover wire mesh 50 and a cover reinforcing crossbar 60 installed on the upper surface of the cover wire mesh 50.

The lower wire mesh 10 is disposed along a slope, and gabionite (A) is filled therein through an open upper surface.

In other words, the lower wire mesh 10 is formed by arranging galvanized iron wires crosswise in the horizontal and vertical directions, and has a bottom surface in a square shape and a side wall surface erected at an angle of about 90 degrees upward from the edge of the bottom surface. It consists of The bottom surface and the side wall surface are firmly bound to each other with a tie line, so that the lower wire mesh 10 has a structure surrounded by wire mesh except for the upper surface.

In addition, the lower wire mesh 10 has a plurality of inner spaces by one or more partition wire meshes 11 installed therein.

The partition wire mesh 11 is formed in a quadrangular shape by arranging galvanized iron wires crosswise in the vertical and horizontal directions. Since (A) is filled, it is possible to prevent too many gabion stones (A) from being filled in either space. As such, the gabion stone (A) filled in the lower wire mesh 10 is a rock such as a natural stone or a broken stone.

Like the lower wire mesh 10, the upper wire mesh 20 is formed by arranging galvanized iron wires crosswise in the horizontal and vertical directions, and has an angle of about 90 degrees upward from the bottom surface of the square shape and the edge of the bottom surface. It is composed of side walls erected with the upper surface open and the remaining surface surrounded by wire mesh. This upper wire mesh 20 is disposed on the upper surface of the lower wire mesh 10 filled with gabionite (A) and firmly bound to the lower wire mesh 10 using a tie line or the like.

The interior of the upper wire mesh 20 is filled with soil through the open upper surface and then compacted.

The first geotextile nonwoven fabric 30 is installed on the bottom surface of the upper wire mesh 20 and is pressed by soil B filled in the upper wire mesh 20. The first geotextile nonwoven fabric 30 serves to block soil sand in the upper wire mesh 20 from being introduced into the lower wire mesh 10.

Meanwhile, a second geotextile nonwoven fabric 70 may be further installed between the bottom surface and the inclined surface of the lower wire mesh 10 . The second geotextile nonwoven fabric 70 is selectively installed in close contact with the slope, and is firmly bound to the outside of the bottom surface of the lower wire mesh 10 using a tie line or the like. The second geotextile nonwoven fabric 70 prevents the gabionite A from escaping out of the lower wire mesh 10 while allowing the vegetation wire mesh composite mat to adhere to the slope.

The seed mat 40 is a reinforced non-woven fabric to which vegetation seeds 42 are attached, and is installed on the upper surface of the upper wire mesh 20 filled with soil B to allow plants to grow on the slope later. The seed mat 40 includes vegetation land 41, vegetation seeds 42 attached to the upper surface of the vegetation land 41, PE soil net 43 laminated on the upper surface of the vegetation seed 42, and , It is composed of a non-woven fabric 44 laminated on the upper surface of the PE geomock net 43.

The vegetation 41 is placed on the upper surface of the upper wire netting 20 filled with sand (B) and is in contact with the soil (B), and is made of 100% natural pulp, so it is soft and has strong moisturizing power.

The vegetation seed 42 is a plant species seed attached to the vegetation 41, and grows later to increase the resilience of the natural ecosystem.

The PE (Poly Ethylene) civil net 43 increases the tensile strength of the non-woven fabric 44 to stabilize the structure and maintains its shape by lowering the elongation.

The non-woven fabric 44 has excellent water permeability and prevents soil loss through a filtering action.

The cover wire mesh 50 is formed by arranging galvanized iron wires crosswise in the horizontal and vertical directions, and is installed on the upper surface of the non-woven fabric 44 of the seed mat 40. This cover wire mesh 50 is firmly fixed to the lower wire mesh 10 using a tie line, etc., and is also tied to the seed mat 40 with a tie line.

One or more of the cover reinforcement crossbars 60 are installed on the upper surface of the cover wire mesh 50, and may be used by making a large diameter reinforcing bar in an X shape or using a thin metal plate in an X shape. In the case of using reinforcing bars, it is made into an X shape by tying it with a tie line, and in case of using a metal plate, it is made in an X shape by bolting.

When a vegetation wire mesh composite mat is installed on a slope and a certain amount of time passes, a fullness phenomenon may occur due to the tilting of soil (B) or gabionite (A), but the cover reinforcement crossbar (60) prevents the fullness phenomenon can do.

Above, the eco-friendly vegetation wire mesh composite mat shown in FIGS. 1 to 3 and 5 has been described, and now the eco-friendly vegetation wire mesh composite mat shown in FIGS. 4 and 6 will be described. However, the description of the same configuration is minimized and only the parts with differences are explained.

The eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration shown in FIGS. 4 and 6 includes a lower wire mesh 10 disposed along the slope and filled with gabionite (A) therein through an open upper surface, The first geotextile nonwoven fabric 30 installed on the upper surface of the lower wire mesh 10, and the upper wire mesh 20 installed on the upper surface of the first geotextile nonwoven fabric 30 and filled with soil through the open upper surface ), the intermediate reinforcing crossbar 80 installed on the bottom surface of the upper wire mesh 20, and the seed mat 40 installed on the upper surface of the upper wire mesh 20 with the vegetation seeds 42 attached thereto , It is configured to include a cover wire mesh 50 installed on the upper surface of the seed mat 40 and a cover reinforcing crossbar 60 installed on the upper surface of the cover wire mesh 50.

The eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration shown in FIGS. 4 and 6 further includes an intermediate reinforcing crossbar 80 when compared to the eco-friendly vegetation wire mesh composite mat shown in FIGS. 1 to 3 and 5, there is.

The intermediate reinforcing crossbars 80 are selectively installed, and one or more are installed and fixed to the bottom surface of the lower wire mesh 10 using a tie line or the like to prevent the fullness phenomenon together with the cover reinforcing crossbars 60.

As the intermediate reinforcing crossbar 80 is installed on the bottom surface of the lower wire mesh 10, the first geotextile nonwoven fabric 30 installed on the bottom surface of the upper wire mesh 20 in FIGS. It is installed between the upper surface of the lower wire mesh 10 filled with (A) and the bottom surface of the upper wire mesh 20, and the gabion stone (A) filled in the lower wire mesh 10 and the soil (B) filled in the upper wire mesh 20 are prevent leakage to the outside.

The construction method of the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration constructed as described above is completed through several steps as shown in FIG.

7 is a block diagram showing a method of constructing an eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention.

First, it starts with the process of arranging the slope evenly (S1).

After the slope is evenly arranged, the second geotextile nonwoven fabric 70 is selectively installed on the slope (S2).

If the second geotextile nonwoven fabric 70 is not installed, the inner space is partitioned by the partition wire mesh 11 and the lower wire mesh 10 whose upper surface is open is fixed to the slope with the reinforcing bar pile (C) (S3) . That is, the lower wire mesh 10 is fixed to the slope by driving the other end of the reinforcing bar pile (C) connected to the lower wire mesh 10 at one end deeply into the slope.

When the second geotextile nonwoven fabric 70 is installed on the slope, the lower wire mesh 10 and the second geotextile nonwoven fabric 70 are connected together at one end of the reinforcing bar pile (C), and then the other end is placed inside the slope. The bottom wire mesh 10 and the second geotextile nonwoven fabric 70 are fixed to the slope by driving them deeply.

After the lower wire mesh 10 is installed on the slope, the inside of the lower wire mesh 10 is filled with gabion stone (A) (S4).

Thereafter, the first geotextile nonwoven fabric 30 is installed and fixed on the upper surface of the lower wire mesh 10 filled with gabion stone (A) (S5).

Then, the upper wire mesh 20, the upper surface of which is open and has an internal space, is installed and fixed on the upper surface of the first geotextile nonwoven fabric 30 (S6).

After the upper wire mesh 20 is installed, one or more intermediate reinforcing crossbars 80 are installed on the bottom surface of the upper wire mesh 20 (S7).

After installing the intermediate reinforcing crossbar 80, soil (B) is laid inside the upper wire mesh 20 and compacted (S8).

Thereafter, a seed mat 40 to which vegetation seeds 42 are attached is installed on the upper surface of the upper wire mesh 20 filled with soil B (S9).

After the seed mat 40 is installed, the cover wire mesh 50 is installed on the upper surface of the seed mat 40 using a tie line or the like (S10).

Finally, the construction is completed by installing the cover reinforcement crossbar 60 on the upper surface of the cover wire mesh 50 (S11). Here, the cover reinforcement crossbar 60 is made of an X shape by binding reinforcing bars with a tie line or by bolting a metal plate to make an X shape.

In the above, the construction method of the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention shown in FIG. It also includes construction methods.

The construction method of the eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration according to the present invention without installing the intermediate reinforcing crossbar 80 includes the steps of evenly arranging the slope, and the second geotextile nonwoven fabric (70 ) and fixing the lower wire mesh (10) and the second geotextile nonwoven fabric (70) with the inner space partitioned by the partition wire mesh (11) and the upper surface open to the slope with the reinforcing bar pile (C). And, filling the inside of the lower wire mesh 10 with gabion stone (A), installing an upper wire mesh 20 with an open upper surface and an inner space formed on the upper surface of the lower wire mesh 10, The step of installing the first geotextile nonwoven fabric 30 on the bottom surface of the upper wire mesh 20, the step of laying earth and sand inside the upper wire mesh 20 and compacting it, and The step of installing the seed mat 40 to which the vegetation seeds 42 are attached, the step of installing the cover wire mesh 50 on the upper surface of the seed mat 40, and the cover reinforcing crossbar 60 on the upper surface of the cover wire mesh. ) It is configured including the step of installing.

10: lower wire mesh 11: partition wire mesh
20: upper wire mesh 30: first geotextile nonwoven fabric
40: seed mat 41: vegetation
42: vegetation seed 43: PE civil network
44: non-woven fabric 50: cover wire mesh
60: cover reinforcement crossbar 70: second geotextile nonwoven fabric
80: intermediate reinforcing crossbar
A: Gabionite B: Earth and sand
C: Rebar Pile

Claims (9)

delete It is arranged along the slope, and gabionite (A) is filled inside through the open upper surface. a lower wire mesh 10 formed by being arranged in a crosswise direction; a first geotextile nonwoven fabric 30 installed on the upper surface of the lower wire mesh 10; an upper wire mesh 20 installed on the upper surface of the first geotextile nonwoven fabric 30, filled with soil B through the open upper surface, and formed by crossing galvanized iron wires in the horizontal and vertical directions; An intermediate reinforcing crossbar 80 installed on the bottom surface of the upper wire mesh 20 and made into an X shape by tying reinforcing bars with a tie line or by bolting a metal plate; A seed mat 40 installed on the upper surface of the upper wire mesh 20 with vegetation seeds 42 attached thereto; a cover wire mesh 50 installed on the upper surface of the seed mat 40 and formed by crossing galvanized iron wires in the horizontal and vertical directions; A cover reinforcement crossbar 60 installed on the upper surface of the cover wire mesh 50 and made into an X shape by tying reinforcing bars with a tie line or by bolting a metal plate; It is configured to include; a second geotextile nonwoven fabric 70 installed on the lower wire mesh 10,
The second geotextile nonwoven fabric 70 is installed between the bottom surface and the slope of the lower wire mesh 10,
The seed mat 40 includes vegetation 41, vegetation seeds 42 attached to the upper surface of the vegetation 41, PE soil net 43 laminated on the upper surface of the vegetation 42, and , It consists of a non-woven fabric 44 laminated on the upper surface of the PE civil net 43, but the vegetation 41 is made of 100% natural pulp,
The cover wire mesh 50 is tied and fixed with the lower wire mesh 10 and the seed mat 40 with a tie line,
After connecting the lower wire mesh (10) and the second geotextile non-woven fabric (70) to one end of the reinforcing bar pile (C) bent in a 'U' shape, the other end is driven into the slope to form a lower wire mesh (10) and An eco-friendly vegetation wire mesh composite mat for slope reinforcement and restoration, characterized in that the second geotextile nonwoven fabric (70) is fixed to the slope.
delete delete delete delete arranging the slope evenly; installing a second geotextile non-woven fabric 70 on the evenly arranged slope; The inner space is partitioned by the partition wire mesh 11, the upper surface is opened, and the lower wire mesh 10 formed by crossing galvanized iron wires in the horizontal and vertical directions is installed on the second geotextile nonwoven fabric 70, and is formed in a U shape. Connecting the second geotextile nonwoven fabric 70 and the lower wire mesh 10 together at one end of the reinforcing bar pile (C) bent into a shape, and then fixing the other end by driving it into a slope; Filling gabionite (A) in the lower wire mesh (10); installing a first geotextile nonwoven fabric (30) on the upper surface of the lower wire mesh (10); installing an upper wire mesh (20) with an open upper surface and an inner space formed on the upper surface of the first geotextile nonwoven fabric (30); Installing an intermediate reinforcing crossbar 80 on the bottom surface of the upper wire mesh 20; compacting after laying soil (B) inside the upper wire mesh (20); Installing a seed mat (40) made of 100% natural pulp and containing vegetation (41) to which vegetation seeds (42) are attached to the upper surface on the upper surface of the upper wire mesh (20); installing a cover wire mesh (50) on the upper surface of the seed mat (40) and fixing the cover wire mesh (50) with the seed mat (40) and the lower wire mesh (10) with a tie line; Installing a cover reinforcement crossbar 60 that is installed on the upper surface of the cover wire mesh 50 by tying reinforcing bars with a tie line to form an X shape and installed on the upper surface of the cover wire mesh 50 or by bolting a metal plate to make an X shape and installed on the upper surface of the cover wire mesh 50 Eco-friendly vegetation wire mesh composite mat construction method for slope reinforcement and restoration, characterized in that it is composed of; delete delete

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