KR100753980B1 - Aquatic Ecosystem Restoration Method Using Porous Structure - Google Patents

Abstract

The present invention relates to a method for restoring an aquatic ecosystem using a porous structure, and more particularly, embedding the porous structure in a waterfront area to provide sufficient moisture for seed germination or plant growth with no power, thereby promoting plant growth and swelling. The present invention relates to a method for restoring aquatic ecosystems using porous structures that can be formed into natural water spaces (vegetation areas, islands, keys, etc.).

The method for restoring the water ecosystem using the porous structure according to the present invention includes the steps of forming a concrete porous structure having a porosity of 10 to 70% by mixing aggregates of 5 to 40 mm in size, cement, water, and admixture into a mold; Filling an aggregate having a size of 5 to 40 mm in the inside of the plum tube to form a plume tubular porous structure; Filling a 5-40 mm aggregate into a frame made of a metal mesh to form a mesh-like porous structure; A porous structure selection step of selecting one or more of the concrete porous structure, the plume tube porous structure, and the mesh porous structure; A porous structure embedding step of embedding the porous structure selected in the porous structure selection step by a desired length in the waterfront space direction at a position lower than the average water level of the stream; A river water induction step of inducing water of the river into the ground of the waterfront space through the embedded porous structure; It characterized in that it comprises a plant growth step of sowing or seeding the desired plant seeds on top of the waterfront space in which the river water is introduced through the river water induction step.

Description

Method for recovering aquatic ecosystem using porous structure

1 is a process chart showing a method for restoring a water ecosystem using a porous structure according to the present invention.

2 is a view showing a porous structure according to the present invention,

       Figure 2a is a concrete porous structure,

       2b is a plume tubular porous structure,

       2C is a meshed porous structure.

Figure 3 shows the state of use of the porous structure according to the present invention,

       3A is a view for showing a state before installation of the porous structure,

       3B is a view for showing the installed state of the porous structure.

Figure 4 is a view showing the growth after 3 months of reed seed sowing in the four weeks area where the porous structure is embedded.

<Explanation of symbols for main parts of the drawings>

1: plum tube

2: metal mesh

The present invention relates to a method for restoring an aquatic ecosystem using a porous structure, and more particularly, embedding the porous structure in a waterfront area to provide sufficient moisture for seed germination or plant growth with no power, thereby promoting plant growth and swelling. The present invention relates to a method for restoring aquatic ecosystems using porous structures that can be formed into natural water spaces (vegetation areas, islands, keys, etc.).

In general, aquatic ecosystems are divided into marine ecosystems and broth ecosystems, and aquatic ecosystems are divided into purified water, runoff and wetland ecosystems, and rivers are ecological pathways for environmental self-cleaning and habitat and movement of living organisms. In addition, the area where the marine ecosystem and the aquatic ecosystem meet is called a brackish area and has a very high ecological value.

In particular, rivers are one of the most ecological spaces in which biodiversity has been damaged by human interference, and the transformation and decline of ecosystem functions and structures have been most seriously progressed. Freshwater ecosystems, including rivers, are an important resource, estimated to have a production capacity of $ 33 trillion per year, and must be protected and restored for human sustainable survival.

To date, rivers have been installed only for the management and use of humans, and dams, rivers, and reservoirs have been installed to increase water banks to improve flood protection and to provide stable water to protect cities and agricultural land from flooding. .

Many aquatic ecosystem restoration technologies so far have been constructed for human purposes, such as technology to avoid existing shoreline blocks and install porous vegetation blocks and gabions that can be used for civil stability and plant growth. Direct restoration to restore the aquatic ecosystem whose original function and structure have been destroyed by human activities such as passive restoration technology that introduces plants while maintaining structure, removal of protection banks, meandering naturalization of river, and restoration of keys Can be divided into technologies.

Conventional techniques are applied to determine that there is enough water needed for riverside vegetation growth, but in reality is a very dry area, such as wind flowing along the stream, smooth drainage.

As a result, the plant is grown only in areas where there are dead or underground moisture. Therefore, the exposed soil is eroded during flooding.

That is, although water is essential for the entire plant growth, including early seed germination, river waterside areas are easily dried due to high dikes and small inflows, and thus have many difficulties for plants to grow and grow. Conventional related technologies for smooth plant growth in these areas are mostly related to vegetation plant growth using organic compost, livestock meal, poultry, forest processing by-products, sewage sludge, etc., and increase water retention by adding some super absorbent resins. Techniques are reported.

However, the technologies utilized for the recycling of waste are not constant in the effects of plant uptake and growth, and when used directly on riversides without buffer zones, harmful substances such as heavy metals contained in the product can be leaked and become non-point sources of rivers. There was a problem that could be.

In addition, there is a problem that requires the labor costs and costs according to the energy consumption used to operate the plants by supplying water using an automatic irrigation system for the growth of plants.

Therefore, the present invention has been invented to solve the above problems, by embedding the porous structure in the existing waterside area by supplying the moisture necessary for seed germination or plant growth without power to promote the growth and sticking of the plant in a short time to natural The present invention provides a method for restoring aquatic ecosystems using a porous structure that is formed into a water space.

A method for restoring the water ecosystem using the porous structure according to the present invention for achieving the above object is a concrete porous structure having a porosity of 10 to 70% by mixing aggregates of 5 to 40 mm in size, cement, water, and admixture into a mold Forming a; Filling an aggregate having a size of 5 to 40 mm in the inside of the plum tube to form a plume tubular porous structure; Filling a 5-40 mm aggregate into a frame made of a metal mesh to form a mesh-like porous structure; A porous structure selection step of selecting one or more of the concrete porous structure, the plume tube porous structure, and the mesh porous structure; A porous structure embedding step of embedding the porous structure selected in the porous structure selection step by a desired length in the waterfront space direction at a position lower than the average water level of the stream; A river water induction step of inducing water of the river into the ground of the waterfront space through the embedded porous structure; It characterized in that it comprises a plant growth step of sowing or seeding the desired plant seeds on top of the waterfront space in which the river water is introduced through the river water induction step.

In addition, the porous concrete structure is characterized in that the cylindrical shape which is advantageous for distributing the load coming from the top, and in the form of a rectangular column having an excellent watering function than the cylindrical shape.

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

1 is a process chart showing a method for restoring a water ecosystem using a porous structure according to the present invention, Figure 2 is a porous structure according to the present invention, Figure 2a is a concrete porous structure, Figure 2b is a plumbular porous structure 2C is a mesh-like porous structure. 3 is a view showing a state of use of the porous structure according to the present invention, Figure 3a is a view for showing the state before installation of the porous structure, Figure 3b is a view for showing the installed state of the porous structure.

As shown in Figures 1 to 3, the method of restoring the water ecosystem using the porous structure according to the present invention is a mixture of 5 ~ 40mm size aggregate, cement, water, admixture into the mold and the concrete type of porosity 10 ~ 70% Forming a porous structure (100); Filling the inside of the plume tube 1 with an aggregate having a size of 5 to 40 mm to form a plume tube-shaped porous structure (200); Filling a frame of 5 ~ 40mm aggregate in a frame made of a metal mesh (2) to form a mesh-like porous structure (300); A porous structure selection step 400 of selecting one or more of the concrete porous structure, the plume tube porous structure, and the mesh porous structure; A porous structure embedding step (500) for embedding the porous structure selected in the porous structure selection step (400) by a desired length in the waterfront space direction at a position lower than the average water level of the stream; A river water derivation step 600 for guiding water in the river to the ground of the waterside space through the embedded porous structure; It comprises a plant growth step 700 for sowing or seeding the desired plant seeds on top of the waterfront space in which the river water is introduced through the river water induction step 600.

That is, the water ecosystem restoration method using the porous structure of the present invention, the porous structure such as concrete porous structure, plume tube-type porous structure, mesh-type porous structure is lower than the average water level of the river in the waterfront space (key area, coarse water, etc.) Since it is buried in the area, it is possible to create a vegetation zone by swelling and applying the applied plants by allowing the water surface space underground irrigation with no power.

Hereinafter, the specific method of the water ecosystem restoration method using the porous structure of the present invention will be described step by step.

As shown in Figure 2a, in the step of forming a concrete porous structure (100), a concrete porous structure formed with commercially available cement and 5 to 40mm aggregate as a main material to form a porosity of 10 to 70% by adding water and admixture To produce.

The concrete porous structure is manufactured in the form of a square column and a cylinder, and the cylinder has a function of distributing the load coming from the upper part, so that many people can observe and visit the waterfront area around the promenade, equipment, and structure. It is preferable to apply the rectangular columnar shape to the area of concern for drying damage because the waterside area is wider than the cylindrical shape because the watering function is superior.

As shown in FIG. 2B, in the step 200 of forming a plume tube-shaped porous structure, the plume tube 1 is generally U-shaped or U-shaped.

That is to fill a U-shaped or U-shaped or circular flute tube (1) inside the aggregate size of 5 ~ 40mm to produce a porous tube-like porous structure. In particular, the U-shaped plume tube (1) is mainly used in places where the flow velocity of the stream is low or the inflow of river water does not have to be large. The '-shaped' plume tube (1) has a high flow rate of the river or inflow of the river water. It is advisable to install it in this much needed area.

As shown in Figure 2c, in the step of forming a mesh-like porous structure (300), after forming a rectangular frame with a metal mesh (2) and then filling the aggregate size of 5 ~ 40mm in the frame aggregate is not disturbed Manufactured by sealing tightly with iron wire.

The manufactured mesh-type porous structure has advantages such as good workability, short construction time, and low construction cost. In addition, since the durability to withstand damage is weaker than that of the concrete porous structure and the plumbed tubular porous structure, it is not suitable in the place where heavy structures and vehicles or people flow on the ground.

As shown in FIG. 3, in the step 500 of embedding the porous structure selected in the porous structure selection step 400 of selecting one or more of the concrete, plume, and mesh porous structures, As such, the general water space is a mud component of the impermeable bottom layer. In this case, the soil moisture is distributed by concentrating only on a certain area in contact with water due to the impermeable layer. In this case, areas away from the water will be supplied with water using an artificial irrigation system. The usual use of such watering systems requires not only energy sources such as electricity and oil, but also a lot of labor and time.

Therefore, when the porous structure is embedded at a position lower than the average water level of the river in the waterfront space direction as shown in Figure 3b, the area of the effective moisture layer required for the plant is widely distributed. Due to the water distribution characteristics, plants can be distributed over a large area of waterfront to secure river stability and create an ecological environment.

On the other hand, in the river water derivation step 600, although water is typically guided to the waterfront space using a watering system, in the present invention, the porous structure at a length and interval to be constructed in the waterfront space direction at a position lower than the average water level of the stream By embedding the water in the river can be induced into the ground of the waterfront space.

In the plant growth stage 700, the concrete, plume tube, and mesh-type porous structures are embedded and covered in the waterfront space at a position lower than the average river level in the waterside region such as the coarse ground and the river side. Experiments were carried out by sowing seeds of reeds, which are known to be difficult to construct through seed sowing.

For experiments, the waterfront area next to the river is divided into 4 sections by a certain area, and then the 'waterfront space without embedding porous structure', 'waterfront space with embedded concrete porous structure', and 'waterfront with embedded porous tube structure' Space 'and' a waterfront space in which a mesh-type porous structure is embedded ', and seed reeds having a germination promoting treatment were sown therein.

<Table 1> Greening rate of reeds in waterfront spaces in which general waterfront spaces and porous structures are embedded

Waterside space without embedding porous structure Waterfront space with concrete porous structure embedded Waterfront space embedded with a plume tubular porous structure Waterfront space with mesh-type porous structure embedded 30 days after sowing  56%  75%  76%  78% 3 months after sowing  73%  100%  99%  100%

As shown in <Table 1>, 'a waterfront space in which a concrete porous structure is embedded' and a waterfront space in which a porous porous structure is embedded, as compared to 'a waterfront space in which a porous structure is not embedded' In addition, it can be seen that the greening ratio is high in the 'waterfront space in which the mesh-type porous structure is embedded'.

This is because the germination and growth rate of the seeded reed seeds is increased by providing a smooth water supply without using an artificial irrigation system.

On the other hand, Figure 4 is a view showing the growth after three months of reed seed sowing in the four-week area embedded with the porous structure.

As shown in Figure 4, even when far away from the river with water is smoothly supplied so that the seeded reed seeds are germinated and grown uniformly it can be seen that 100% greening of the composition in the third month of sowing.

On the other hand, the plant growth step 700 further comprises a germination promoting process of hormonal treatment and endothelial weakening treatment. Therefore, early germination of plant seeds, early induction can be induced to make the vegetation composition faster.

As described above, the water ecosystem restoration method using the porous structure according to the present invention by installing the porous structure in the waterfront area in contact with the river, river, keys, etc. to the desired width and length to provide a rubber hose, sprinkler, automatic watering system, etc. It is possible to grow plants by enabling proper water supply without using.

In addition, since it does not use energy such as oil and electricity, it not only reduces costs, but also has the effect of creating an evenly distributed vegetation zone in the waterside area without putting a separate labor force.

Claims (3)

Mixing 5-40 mm aggregate, cement, water, and admixture into a mold to form a porous porous structure having a porosity of 10 to 70%; Filling an aggregate having a size of 5 to 40 mm in the inside of the plum tube to form a plume tubular porous structure; Filling a 5-40 mm aggregate into a frame made of a metal mesh to form a mesh-like porous structure; A porous structure selection step of selecting one or more of the concrete porous structure, the plume tube porous structure, and the mesh porous structure; A porous structure embedding step of embedding the porous structure selected in the porous structure selection step by a desired length in the waterfront space direction at a position lower than the average water level of the stream; A river water induction step of inducing water of the river into the ground of the waterfront space through the embedded porous structure; The method of restoring the water ecosystem using a porous structure, characterized in that comprises a plant growth step of sowing or seeding the desired plant seeds in the upper waterfront space in which the river water is introduced through the river water induction step. The method of claim 1, wherein the concrete porous structure, A method of restoring an aquatic ecosystem using a porous structure, characterized in that the cylindrical shape is advantageous for dispersing the load coming from the upper portion, and the rectangular columnar shape has superior watering function than the cylindrical shape. According to claim 1, In the plant growth step 700, A method for restoring aquatic ecosystems using a porous structure, characterized in that it further comprises a process for promoting the germination of hormonal treatments and endothelial weakening treatments.

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