KR101166881B1 - Environmentally-friendly revetment structure - Google Patents

Abstract

The present invention relates to the field of civil engineering, and relates to a natural revetment structure for protecting a lake by a natural friendly method. In particular, the present invention frame 10 is formed vegetation space portion 12 for vegetation; Is connected to at least one of the vegetation space portion 12 of the mold 10 and buried in the ground (2) to induce moisture in the ground (2) to the vegetation space portion 12 of the mold (10) It presents a natural shore relief structure including a core 20.

Revetment, Nature, Eco-friendly, Vegetation, Vegetation, Heartwood, Capillary, Porous

Description

Natural Revetment Structure {Environmentally-friendly revetment structure}

The present invention relates to the field of civil engineering, and relates to a natural revetment structure for protecting a lake by a natural friendly method.

The term 'vegetation' refers to a state in which trees are planted, and 'greenness' refers to a state in which grass, such as grass, is planted. Hereinafter, 'vegetation' is used as a concept including the 'greenness'.

In general, slopes such as slopes and slopes of shores are easily eroded or lost due to water, wind, etc., and thus, a shoreline construction method for constructing shoreline structures on slopes of shores to protect the shores of lakes is implemented.

However, for the construction of the framework for the protection of the rafts, the inherent vegetation zone is inevitably damaged, which causes enormous damage to the natural ecosystem around the rafts, and damages the aesthetics due to the damage to the vegetation zone and the depressed raft structure.

Therefore, in recent years, it is possible to prevent the collapse of the shoreline, but at least by creating a unique vegetation zone so that the habitat of living organisms can be made by itself, conserving and restoring the ecosystem and the collapse of the shoreline by the vegetation zone itself. There is an urgent need for a raft construction method that can prevent this problem.

The present invention has been made to solve the above problems, to create a vegetation zone to prevent the collapse of the lakes, as well as to provide a framework for the natural shoreline structure that can preserve and restore the ecosystem of the lakes. do.

In order to solve the above problems, the present invention is a mold 10 is formed with a vegetation space portion 12 for vegetation; Is connected to at least one of the vegetation space portion 12 of the mold 10 and buried in the ground (2) to induce moisture in the ground (2) to the vegetation space portion 12 of the mold (10) It presents a natural shore relief structure including a core 20.

The vegetation space portion 12 may be composed of a capillary portion 12A connected to the core material 20 and a main body portion 12B extended upwardly of the capillary portion 12A.

The capillary portion 12A may be formed to a size into which the core material 20 may be inserted.

The body portion 12B may have a shape in which the cross-sectional size gradually decreases toward the capillary portion 12A.

Filling material 14 may be filled in the vegetation space portion 12.

At the head of the core 20, a hygroscopic film 24 for preventing the loss of the filler 14 through the core 20 may be laid.

The core 20 may be formed with a coating layer 22 for waterproofing and indexing the side so that moisture may be induced only along the longitudinal direction of the core 20.

The coating layer 22 may be formed by a coating material including bentonite.

The core material 20 may include a capillary tube 30 for inducing moisture in the ground 2 to the vegetation space part 12 by capillary action.

The core material 20 may further include a porous member 40 filled in the capillary 30.

The core 20 may be made of a porous member 40 for guiding moisture in the ground 2 to the vegetation space 12 by capillary action.

The core material 20 may be made of wood.

The timber forming the core 20 may be a thin timber 50.

The thin timber 50 may be preservatively treated with a preservative including salt.

In addition, the present invention to solve the above problems is a plurality of frameworks 10 is formed with a vegetation space portion 12 for vegetation; At least one core material 20 embedded in the ground 2 so as to be connected to the vegetation space part 12 of the mold 10 of the plurality of molds 10 to induce moisture in the ground 2; A natural relief structure including a hygroscopic member 60 for guiding moisture induced by the core material 20 to the plurality of molds 10 is provided.

According to the present invention, the vegetation zone can be stably formed by inducing moisture in the ground to the vegetation by heartwood during a drought, and thus a natural friendly revetment method can be performed.

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

As shown in FIG. 1, the natural shore revetment structure according to the present invention includes a frame 10 in which a vegetation space part 12 for vegetation is formed; Core material 20 connected to at least one of the vegetation space portion 12 of the frame 10 and embedded in the ground (2) so as to induce moisture in the ground (2) to the vegetation space portion 12 of the frame (10) It may be configured to include).

That is, the core material 20 serves as a passage for supplying moisture in the ground 2 which is groundwater, thereby providing moisture to the vegetation space part 12 and the ground surface through the core material 20 during the drought. We can supply enough.

Therefore, since the vegetation 4 can stably grow and grow, the vegetation zone can be easily created and the ecosystem can be restored and preserved. The vegetation zone thus formed can more reliably prevent the collapse of the lake. Can be obtained.

This core 20 is as shown in Figures 2-6. According to the method for supplying the moisture in the ground (2) can be configured in various ways, in particular, the capillary tube (30) for inducing the moisture in the ground (2) to the vegetation space portion 12 by the capillary phenomenon, one of natural phenomena It can be composed of).

Since the core 20 is configured for the capillary phenomenon, it is not necessary to build a power unit such as a pump for supplying moisture in the ground (2), it can be installed at a low cost, and most of all is environmentally friendly The effect can be obtained.

In addition, the capillary 30 serves as a reinforcing material, it is possible to more firmly protect the lake.

Capillary tube 30 may be formed of any material, such as synthetic resin, metal pipes, wood as long as it can induce a capillary phenomenon.

At this time, when the core material 20 is composed of a capillary tube 30, as shown in Figure 4, when the filling material 14 is filled in the vegetation space portion 12, the core material 20 in the head of the core material 20 It is more preferable that the hygroscopic membrane 24 is configured to prevent the loss of the filler material 14 through the core material 20 so that the moisture induced by the core material 20 can be transferred to the vegetation space part 12. The hygroscopic film 24 may be made of various materials such as nonwoven fabric, sponge, wood flour and the like.

In addition, the core material 20 may further include a porous member 40 filled in the capillary tube 30 to guide the moisture in the ground 2 to the vegetation space 12 more easily by capillary action. have.

The porous member 40 may be any material, such as nonwoven fabric, sponge, wood flour, as long as it can induce a capillary phenomenon.

When the core material 20 is formed of the capillary tube 30 and the porous member 40 as described above, the porous member 40 may be protected by the capillary tube 30, and moisture induced in the middle of the porous member 40 may be applied. It can be prevented from being lost to the ground (2), the moisture of the ground (2) is guided to the vegetation space portion 12 more smoothly by the porous features of the porous member 40 as well as the structural features of the capillary tube 30 It can be taken advantage of.

Alternatively, the core material 20 may be composed of only the porous member 40 for guiding moisture in the ground 2 to the vegetation space part 12 by capillary phenomenon caused by porosity like the stem of a plant.

Or the core material 20 is made of wood as shown in particular in Figures 7 and 8, it can be more eco-friendly construction method, can reinforce the ground (2), to the capillary tube 30 described above The capillary phenomenon and the porosity can be achieved at the same time.

In particular, the timber constituting the core material 20 by recycling the thin timber 50 removed from the revetment for the revetment method, by reducing the cost of processing the thin timber 50, cost reduction for forming the core 20 (20) You can take more.

At this time, by not removing at least some of the branches 54 of the thinning tree 50, the branches 54 of the thinning tree 50 are ground like wedges in a different direction from the body 52 of the thinning tree 50. It is possible to further take advantage of being able to prevent the detachment of the thinning tree 50.

At this time, the wood can be insufficient as a reinforcing material that has a large number of holes in the nature and easy to corrode, requiring a solid strength, the wood constituting the core material 20 is preferably treated by an antiseptic solution containing salt, such as saline. Do.

On the other hand, the core 20 is more preferable for the following reasons that the coating layer 22 for waterproofing and index is formed on the side so that moisture can be induced only along the longitudinal direction of the core 20.

That is, since the moisture induced in the core material 20 can be prevented from being lost to the ground 2 in the middle, sufficient moisture can be supplied to the vegetation space part 12 by the core material 20, The underground 2 around the periphery 2 can be prevented from becoming fragile due to the high water content.

In addition, it is possible to prevent the core material 20 from being corroded by the surrounding moisture by waterproof.

In addition, due to the exponential property, it is possible to prevent external moisture such as rivers from leaking into the ground 2 due to a gap between the core 20 and the ground 2, thereby preventing the ground 2 around the core 20 from being soft. Can be.

The coating layer 22 for the waterproof and the index can be made in a variety of ways, in particular by forming the coating layer 30 on the outer surface of the pile member 4 by the coating material containing bentonite (bentonite), Can be met at the same time.

In other words, bentonite is clay composed of extremely fine particles, and the main mineral is montmorillonite, and the clay is a very viscous clay produced by decomposition of the volcanic ash. Such bentonite has a property of swelling by moisture and expanding in volume or several tens of times in volume, which is very suitable as a waterproofing material and an indexing material.

In addition, in order to more firmly form the coating layer 30, the coating material may further comprise a glue.

As shown in FIGS. 1 to 8, the core material 20 may be configured to correspond one by one to each vegetation space part 12.

Hereinafter, the frame 10 described above will be described in detail.

Frame 10 may be made of a permanent material such as concrete or synthetic resin, but supports vegetation 4 until vegetation 4 stably slides and grows to form vegetation zone and finally returns to nature by corrosion. It may be more preferable to be made of environmentally friendly materials such as wood so that you can go.

Vegetation space portion 12 may be characterized in that the vegetation 4 is formed so as to penetrate easily to the ground (2).

That is, as the vegetation 4 stably grows in the ground 2, the roots 4A of the vegetation 2 are entangled with each other in the ground 2 to form a net.

Therefore, the slope surface of the lake can be reinforced more firmly by the vegetation zone composition, the frame 10 can be more stably bound to the ground 2 by the vegetation 4, the frame 10 is corroded Even if the vegetation zone can be enough to maintain the protection method.

The vegetation space 12 may have various shapes, and in particular, may include a capillary portion 12A connected to the core material 20 and a main body portion 12B extending upwardly of the capillary portion 12A. In particular, the capillary portion 12A is more preferably formed to a size that can be inserted into the core material (20). As shown in the figure, the body portion 12B may have a shape in which the cross-sectional size gradually decreases toward the capillary portion 12A, and may take various shapes as necessary.

Accordingly, the head of the core 20 is inserted into the capillary portion 12A so as not to be shaken, so that the core 20 and the frame 10 can be firmly coupled, and moisture in the ground 2 induced by the core 20 is induced. You can prevent this from being lost elsewhere.

In addition, the filling material 14 is filled in the vegetation space portion 12, it can be supported so that the vegetation (4) can stable and grow stably, the gap between the vegetation space portion 12 and the core material 20 The filling force can be improved by being filled. Filler 14 may be made of a variety of materials, such as soil, earth and sand, and may include, in particular, fertilizer powder to help the growth and growth of the vegetation (4). In addition, in order for the vegetation 4 to grow into a perennial plant, the space must be secured as the vegetation 4 is grown, and thus the filling material 14 may be more preferably made of corrosive material such as a crest.

The frame 10 may be formed to be constructed as a single frame 10, but may be formed to form a plurality of the frame 10 in a framed manner as shown, anchor member as necessary It may be bound to the ground 2 by, for example.

The plurality of molds 10 may be bound together by a binding member that binds to each other so as to be relatively movable. That is, the plurality of molds 10 are bound together as one by a binding member, thereby supporting each other against external forces such as flow rate and distributing loads from each other. Therefore, even if the level of the river, the flow rate increases, or the wind speed increases due to heavy flooding or heavy rainfall, the departure of the vegetation 8 including the frame 10 can be prevented, and thus the vegetation zone is stably formed. In addition, it is possible to obtain the effect that the collapse of the lake can be prevented by the shore structure and the composition vegetation zone.

Such a binding member may have any configuration as long as it can bind the plurality of molds 10. However, the binding member allows the external force to be canceled by elastically allowing the plurality of the molds 10 to be moved elastically rather than binding the frames 10 without any movement, so that the plurality of the molds 10 can be returned after the external force is applied. It is more preferable that it consists of.

The binding member made of a flexible material may have various shapes, and may have a corrugated pipe shape to have sufficient elastic force, or may have a band shape to easily bind the plurality of molds 10.

Meanwhile, as shown in FIG. 9, the core material 20 may be buried in the ground 2 so as to be connected to the vegetation space part 12 of the some frame 10 of the plurality of frames 10. In addition, the moisture induced by the core 20 to supply water from the vegetation space portion 12 that is not connected to the core 20, the plurality of the frame 10 It may further include a hygroscopic member 60 to guide to.

That is, some vegetation space portion 12 may be directly supplied to the core 20 through the moisture induced in the core 20, the remaining vegetation as the moisture is induced from the core 20 to the hygroscopic member 60 The space 12 may be supplied with moisture guided by the hygroscopic member 60.

Therefore, the number of core materials 20 can be reduced, thereby reducing construction costs, and minimizing disturbance of the ground 2 due to embedding of the core material 20 to more reliably prevent the collapse of the ground 2. In addition, the moisture absorbing member 60 may take an advantage of inducing moisture in the ground 2 even in the place where the core 20 is difficult to embed.

Since the above has just been described with respect to some of the preferred embodiments that can be implemented by the present invention, as is well known the scope of the present invention should not be construed as limited to the above embodiments, the present invention described above All of the technical ideas together with the technical idea of the base will be included in the scope of the present invention.

1 is a view showing a natural revetment structure according to the present invention,

1 is a schematic view of a natural revetment structure according to the first embodiment.

2 is a partial cross-sectional side view of FIG.

3 is an enlarged view of a portion 'A' of FIG. 2;

4 is another embodiment of FIG.

5 is an enlarged view of a portion 'B' of FIG. 2;

Figure 6 is another embodiment of FIG.

FIG. 7 is a view corresponding to FIG. 2, and is a partial cross-sectional side view of the natural repose structure according to the second embodiment; FIG.

8 is a perspective view of the core of FIG. 7.

9 is a schematic view of a natural revetment structure according to the third embodiment.

DESCRIPTION OF THE REFERENCE NUMERALS

2; Underground 4; Vegetation

6; Pile member 10; frame

12; Vegetation space 20; Heartwood

22; Coating layer 24; Hygroscopic membrane

30; Capillary tube 40; Porous member

50; Thin logging 54; Branch

Claims (15)

A frame 10 in which a vegetation space part 12 is formed for vegetation, and a core material 20 connected to at least one of the vegetation space parts 12 of the frame 10 and embedded in the ground; The core material 20 is made of thin timber 50 preservatively treated with a preservative containing a salt to induce moisture in the ground (2) to the vegetation space portion 12 of the frame 10, In addition, the natural revetment structure, characterized in that the coating layer 22 is formed by a coating material containing bentonite (bentonite) so that water can be induced only along the longitudinal direction of the core material (20). The method according to claim 1, The vegetation space portion 12 is a natural revetment structure consisting of a capillary portion (12A) is connected to the core material 20, and the body portion (12B) formed to extend above the capillary portion (12A). The method according to claim 2, The capillary portion (12A) is a natural revetment structure formed to a size that can be inserted into the core material (20). The method according to claim 2, The main body portion (12B) is a natural revetment structure taking the shape that the cross-sectional size gradually decreases toward the capillary portion (12A). The method according to claim 1, Natural vegetation structure filled with the filling material 14 is the vegetation space portion 12. The method of claim 5, The head of the core 20 is a natural revetment structure having a hygroscopic membrane 24 to prevent the loss of the filler material 14 through the core 20. delete delete The method according to any one of claims 1 to 6, The core material 20 is a natural shore relief structure including a capillary tube (30) for inducing the moisture in the ground (2) to the vegetation space portion 12 by the capillary phenomenon. The method of claim 9, The core material 20 is a natural revetment structure further comprises a porous member 40 filled in the capillary (30). The method according to any one of claims 1 to 6, The core material 20 is a natural shore relief structure made of a porous member 40 for inducing moisture in the ground (2) to the vegetation space portion 12 by capillary action. delete delete delete The vegetation space portion 12 for vegetation is formed in the ground (2) to be connected to the vegetation space portion 12 of the plurality of the frame 10, some of the plurality of the frame 10 is formed At least one core member (20) for inducing moisture in the ground (2), and a hygroscopic member (60) for guiding the moisture induced by the core member (20) to the plurality of molds (10); The core material 20 is made of thin timber 50 preservatively treated with a preservative containing a salt to induce moisture in the ground (2) to the vegetation space portion 12 of the frame 10, In addition, the natural revetment structure, characterized in that the coating layer 22 is formed by a coating material containing bentonite (bentonite) so that water can be induced only along the longitudinal direction of the core material (20).

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