KR20170124388A - afforestation method using a slanted holder one-piece mesh - Google Patents

Abstract

The present invention relates to an afforestation method and, more specifically, relates to an afforestation method using slanted holder one-piece mesh, which can provide convenience for construction and a stable coupling force with earth and sand on a slope. Therefore, even though earth and sand is swept, a collapse of the slope can be prevented in advance to improve durability. Moreover, the afforestation method can be semi-permanently applied. In addition, plants can be cultivated, and in accordance with seasons and environments, various plants can be replaced and cultivated for the afforestation method to be applied in an eco-friendly manner.

Description

[0001] The present invention relates to a slope holder,

The present invention relates to a slope greening method, and more particularly, to an incision slope preventing vegetation from being collapsed due to loss of slope and the like, thereby securing the stability of the slope and forming an environmentally friendly slope The present invention relates to a slope greening method using an inclined holder integrated mesh for making a slope holder.

In general, slope greening is to create vegetation bases by installing structures such as vegetation mats or vegetation blocks in order to prevent slope collapse and slope failure in rivers, waterways, slopes, etc., And green environment to harmonize with the surrounding environment.

The conventional slope recording method disclosed in Korean Patent Publication No. 10-2004-92523 is made of concrete, the outer wall is composed of a vertical wall, the inner wall is divided into a sloping rectangular outer frame and a space portion inside the outer frame, And the inner divider frame is formed to have a lower height than the outer frame and the bent portion is formed at the corner of the outer frame to be used for protecting the slope of the river bank, the lakes and the coast, and the slope erosion , And it is used in various forms such as filling the soil in the space of the rectangular frame, green vegetation in the planting, and environment friendly in filling the stone.

However, in the above-mentioned prior art, the recording method using a square-shaped environmental block is very inconvenient in construction due to the individual constitution of the blocks, and soil loss due to inflow of rain during frequent rainfall occurs frequently due to weak binding force between each block. There is a problem in that it partially collapses and the durability is weak, so that there is a problem that maintenance is very difficult.

In addition, there is a problem in that the plants to be planted are uneven in appearance due to the irregular planting characteristics, and the plants can not be easily replaced according to the season or the surrounding environment.

Korean Patent Publication No. 10-2004-92523.

Disclosure of Invention Technical Problem [8] The present invention has been made to solve the above problems, and it is an object of the present invention to provide a method for improving the durability by preventing slope collapse due to loss of soil, The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a slope greening method using an inclined holder integrated mesh for semi-permanent application.

In addition, the present invention provides a slope greening method using an inclined holder integrated mesh for enabling a plant to be planted, and to be applied in a very environmentally friendly manner, .

As a specific means for attaining the above-mentioned object, a slope compaction step of finishing a slope surface;

A plurality of tubular sloping holders vertically inclined on the sloped slope are used to mesh the sloped holders so that the lower end face of the sloped holders of the mesh is sandwiched between the sloped faces and the mesh, fair;

A toughening process for filling up the soil so that the lower portion of the inclined holder is embedded in the space between the surface of the slope and the installed mesh;

A concrete finishing process for finishing the surface by pouring concrete from the mesh to the upper surface of the slope holder; And

And a plant planting process for planting the plant in a slope holder filled with soil.

As described above, the slope greening method using the inclined holder integrated mesh of the present invention improves the bonding force between the slope and the slope of the slope by using the mesh, thereby preventing the slope of the slope and so on. In particular, the surface is finished with concrete so that the effect can be applied semi-permanently.

In addition, the inclined holders capable of individual planting of plants are exposed at regular intervals on the surface, so that planting of plants is very easy, and it is possible to replace plants with various plants according to the season, environment and surrounding landscape The effect can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall process diagram of a slope greening method using an inclined holder integrated mesh of the present invention. FIG.
2 is a schematic view of a slope compaction process showing a slope veneer method using an inclined holder integrated mesh of the present invention.
3 is a perspective view showing an inclined holder integrated mesh of the present invention.
Fig. 4 is a bottom view of the inclined holder integrated mesh of the present invention. Fig.
FIG. 5 is a schematic view of a mesh installation process of the slope greening method using the inclined holder integrated mesh of the present invention.
6 is a perspective view of the gap maintaining means of the slope greening method using the inclined holder integrated mesh of the present invention.
7 is a schematic view of a mesh fixing process of a slope greening method using the inclined holder integrated mesh of the present invention.
FIG. 8 is a schematic view of the tamping process of the slope greening method using the inclined holder integrated mesh of the present invention. FIG.
FIG. 9 is a schematic view of a concrete finishing process of a slope greening method using an inclined holder integrated mesh of the present invention. FIG.
10 is a schematic view of plant planting process of the slope greening method using the inclined holder integrated mesh of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

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

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall process diagram of a slope greening method using an inclined holder integrated mesh of the present invention. FIG.

1, the slope greening method using the inclined holder integrated mesh according to the present invention includes a slope compaction step (S100), a mesh installation step (S200), a toughening step (S300), a concrete finishing step (S400) , And plant planting process (S500).

First, in the slope compaction step (SlOO)

Referring to FIG. 2, a slope 10 is formed by excavating a slope 10 through a conventional excavator or the like so as to secure the slope 10 formed thereon. The compaction may be performed according to the inclination and the degree of curvature.

Thereafter, in the mesh installation step (S200)

The inclined holder integrated mesh 100 may be arranged on the slope 10 formed as described above.

3 and 4, the mesh 100 may be provided with the inclined holders 110 integrally formed by plastic injection molding.

At this time, the mesh 100 has a shape of an oblique tube having an open top so that the soil can be filled therein, and the oblique holder 110 is arranged at regular intervals before, after, left, and right.

The oblique holders 110 are connected to each other by using a plurality of vertical bars 131 and a horizontal bar 132. The vertical bars 131 and the horizontal bars 132 132 to form a lattice-shaped mesh 100.

Each of the vertical bars 131 and the horizontal bars 132 is formed with depressed grooves 131a and 132a on one side thereof and also has a plurality of through-type binding holes 131b and 132b.

The mesh 100 may be connected to the left and right sides of the mesh 100. For this purpose, one end of each of the lateral bars 132 is folded twice so as to form a step to form a connection portion having the joint hole 136 do.

The other end of each of the lateral bars 132 is configured to be further supported by the connecting portion 135 and further formed with a resilient piece 137 having a locking projection 138 to be engageable with the engaging hole 136.

That is, the mesh 100 sandwiches the elastic piece 137 formed on the lateral bar 132 of the mesh 100, which is adjacent to the coupling hole 136 formed in the connecting portion 135 of the lateral bar 132, The engagement protrusion 138 of the resilient piece 137 is resiliently engaged with the engagement hole 136 to be engaged.

In addition, the lower inner side of each of the inclined holders 110 is configured to be able to discharge water and to be closed through a string 111 so as to prevent leakage of the soil.

At this time, the water line 111a, which allows water to be discharged to the slope 10 through the water line 111 when the water penetrates into the rain in the process of planting and growing plants in the slant holder 110, So that the water through hole 111a is formed around the peripheral edge of the peripheral edge of the peripheral edge of the peripheral edge of the peripheral edge.

In addition, the strips 111 are formed in the middle portion, and a plurality of the guiding guide holes 111b, which are routed to the slopes 10,

5, the lower end surface of the oblique holder 110 is mounted on the oblique surface 10 by using the mesh 100 constructed as described above in the mesh installing step (S200) A space is formed between the slope 10 and the mesh 100 according to the degree of protrusion of the slope holder 110.

The meshes 100 may be continuously connected to each other through the joint holes 136 and the elastic pieces 137 of the connecting portions 135 of the neighboring meshes 100 as described above. As shown in FIG.

The mesh 100 may be further subjected to a mesh fixing step S210 for maintaining a gap with the slope 10 and applying a fixing force to the mesh 100. For this purpose, Means 200 may be further provided.

At this time, the gap maintaining means 200 first forms the upper support portion 211 having the shape of "X ", and four spacing rods 212 protruding downward from the end portion of the upper support portion 211 are formed A mesh support 210 is constructed.

The space retaining rods 212 penetrate the space retaining rods 212 to constitute a mesh supporting plate 220 which can slide up and down.

Each of the spacing rods 212 is formed with upper and lower two stages below the mesh support plate 220 and upper and lower rubber rings 230 230 '.

The space maintaining means 200 is provided with a support plate 240 separated from the mesh support 210. The support plate 240 has a disc shape and the gap maintaining rods 212 are passed through .

7, when the mesh 100 is fixed by using the gap maintaining means 200 configured as described above, first, the slope 10 is formed at a position opposing the mesh support 210 to be installed, The support plate 240 may be provided.

Thereafter, the vertical bar 131 and the horizontal bar 132 of the mesh 100 are separated by using the spacing rod 212 of the mesh support 210 in a state where the mesh support 210 and the mesh support plate 220 are separated from each other. The mesh support plate 220 is engaged with the mesh support plate 220 from the lower portion and the mesh support plate 220 is connected to the hollow support bar 212 through the gap between the vertical bar 131 and the horizontal bar 132. [ The vertical bar 131 and the horizontal bar 132 may be constrained between the upper support portions 211. [

Then, the lower end of the gap maintaining rod 212 may be inserted into the support plate 240 and inserted into the slope 10 to be fixed.

In the above process, the upper and lower rubber rings 230 and 230 'support and fix the bottom surface of the mesh support plate 220 by using the upper rubber ring 230 to maintain the binding force of the mesh 100 And the lower rubber ring 230 'is used to fix the support plate 240 on the upper portion of the support plate 240 so that the gap between the support plate 240 and the mesh support plate 220 is maintained. It is possible to keep the mesh 100 and the slope 10 at regular intervals and to fix the mesh 100 in a fixed manner.

Thereafter, the toughening step (S300)

As shown in FIG. 8, the gravel 300 is filled with the surface of the slope 10 and the space between the installed meshes 100. The gravel thus buried is inclined at an angle So that the lower portion of the holder 110 is buried and fixed.

If the gap between the slope 10 and the mesh 100 is maintained using the gap maintaining means 200 in the process of filling the gravel 300 as described above, It is possible to stably fill up the gravel with respect to the space and to maintain the installation force of the mesh 100, thereby improving the durability of the gravel by improving the binding force of the gravel.

3, the recessed grooves 131a and 132a formed in the vertical bar 131 and the horizontal bar 132 are filled with the gravel 300. In other words, So that the binding force between the mesh 100 and the gypsum 300 is increased.

Thereafter, the concrete finishing step (S400)

The surface is closed by pouring concrete from the upper portion of the mesh 100 to the upper end surface of the inclined holder 110 as shown in FIG.

In other words, the concrete surface can be formed on the sloped surface by casting the concrete 400 as described above, and it is possible to secure the stability of the slope while being semi-permanent. Also, when the concrete is poured, Thereby enabling stable construction.

3, the concrete 400 is filled in the through-hole binding holes 131b and 132b formed in the vertical bar 131 and the horizontal bar 132, as shown in FIG. 3 The bonding force and the bonding force between the mesh 100 and the concrete 400 are increased.

Thereafter, the plant planting process (S500)

As shown in FIG. 10, the plants can be planted in the inclined holder 110 exposed by the concrete finishing surface, and the greening of the slopes can be formed through the plants thus planted. In the slope greening method using the inclined holder integrated mesh Construction will be completed.

In the course of raising the plants planted in the inclined holder 110 as described above, moisture is discharged to the slope 10 through the water passage hole 111a of the stripping network 111 while rainfall is prevented, In addition, the growing roots can be fixed on the slope (10) by distributing the roots uniformly during the growth of the plants through the induction guide hole (111b) of the rope (111) .

As described above, in the slope greening method using the inclined holder integrated mesh of the present invention, it is possible to perform a firm finishing work on the slope, and the stability of the slope is ensured.

In addition, it is possible to plant the plants in each of the slope holders 110, thereby enabling the composition of the greenery, and the plant to be planted can be easily replaced according to the season or the surrounding environment, And the lower end of the inclined holder 110 is finished through the drawing net 111. Also, drainage of the gravel-like material is prevented even during rainy days, and the root of the gravel-like holder 110 can be fixed on the slope 10 with good stability.

100: mesh 110: incline holder
111: String of color 111a: Water penetration
111b: an induction inducer 131: a vertical bar
132: Horizontal bar 135: Connection
136: joint ball 137: elastic piece
138: stumbling block 200: space maintaining means
210: mesh support zone 211: upper support
212: spacing rod 220: mesh support plate
230,230 ': Upper and lower rubber rings 240: Support plate
S100: slope compaction step S200: mesh installation step
S210: Mesh fixing step S300: Tosemising process
S400: concrete finishing process S500: plant planting process

Claims (5)

A slope surface compaction step (S100) of finishing the surface of the slope (10);
A plurality of tubular tilting holders 110 vertically tilted on a sloping slope are used so that the lower end surface of the tilting holder 110 of the mesh 100 is sloped 10) and the mesh (100) so as to form a space therebetween;
A tamping step (S300) of filling up the soil so that the lower part of the inclined holder (110) is embedded in the space between the surface of the slope (10) and the installed mesh (100);
A concrete finishing step (S400) of placing the concrete from the mesh (100) to the upper end surface of the inclined holder (110) to finish the surface; And
(S500) for planting the plant in a slope holder (110) filled with soil. The slope greening method using an inclined holder integrated mesh.
The method according to claim 1,
In the mesh installation step S200,
The mesh (100)
A slope holder 110, which is configured in the form of a front openable tubular body capable of filling soil therein, and is arranged at regular intervals in front, back, left, and right; And
The plurality of inclined holders 110 are connected to the front, rear, left, and right sides of the inclined holders 110, respectively, and each of the plurality of inclined holders 110 has a plurality of recessed grooves 131a, 132a and a plurality of through-type binding holes 131b, And a vertical bar (131) and a horizontal bar (132).
3. The method of claim 2,
One end of each of the lateral bars 132 is bent twice to form a step to form a connecting portion 135 having an engaging hole 136,
The other end of each of the lateral bars 132 is configured to be further supported by the connecting portion 135 and further includes a resilient piece 137 having a locking protrusion 138 to be engageable with the engaging hole 136,
Wherein the mesh (100) is connected to the left and right through the horizontal bar (132) continuously.
The method according to claim 1,
The lower end of the inclined holder 110 is constructed so that water can be drained and finished with a string 111 for preventing the loss of soil,
The pull string 111 is formed by a water through hole 111a formed around the water hole for allowing water to flow and a plurality of guide pins 111b formed at the middle portion for distributing the root of the plant when the root is fixed. Slope greening method using inclined holder integrated mesh.
The method according to claim 1,
After the mesh installation step S200, a mesh fixing step S210 for maintaining the gap between the slope 10 and the mesh 100 and fixing the mesh 100 is further performed,
In the mesh fixing step S210,
A mesh support 210 having an upper support portion 211 and a plurality of spacing rods 212 protruding downward from the ends of the upper support portion 211, Upper and lower rubber rings 230 and 230 'capable of adjusting the upper and lower positions along the gap retaining rods 212 and the upper and lower rubber rings 230 and 230' Further comprising spacing means (200) including a support plate (240) through which it is inserted,
The support plate 240 is installed on the slope 10 against the mesh support 210,
The mesh support plate 220 is engaged from the upper portion of the mesh 100 and the lower portion of the gap retaining rod 212 by using the gap retaining rods 212 of the mesh support 210, Thereby fixing the mesh 100 between the upper support 211 and the mesh support plate 220,
The gap holding rod 212 of the mesh support 210 is inserted into the support plate 240 and fixed to the slope so that the lower rubber ring 230 'is fixed to the upper portion of the support plate 240 Slope Reconstruction Method Using Slope Holder Integrated Mesh.

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