KR20090050663A - Afforestation structure of dry region using water battery and construction method thereof - Google Patents

Abstract

The present invention relates to a dry area greening structure using a water battery layer and a construction method thereof, and more specifically, to recording a dry area, a water battery layer embedded in the ground; A plurality of horizontal pipes installed at a predetermined interval near the upper surface of the water battery layer to supply water to the water battery layer; And a soil layer installed on the water battery layer. It relates to a dry area greening structure and a construction method using a water battery layer, characterized in that consisting of.

In the present invention, the water battery layer includes SiO ₂ , and has a specific gravity of 0.1 to 0.2, and is characterized by being made of a porous foam glass lightweight insulation having a water content of 10 to 50%.

In case of greening using water battery layer in a dry area, it is possible to supply water to plants continuously with a small amount of water, prevent erosion and collapse of slopes and secure effective soil depth of plants. It is expected.

Dry Area, Greening, Water Battery, Pipe, Fiber, Foam Glass

Description

Afforestation structure of dry region using water battery and construction method

The present invention relates to a dry area greening structure using a water battery layer and a construction method thereof, and more specifically, to recording a dry area, a water battery layer embedded in the ground; A plurality of horizontal pipes installed at a predetermined interval near the upper surface of the water battery layer to supply water to the water battery layer; And a soil layer installed on the water battery layer. It relates to a dry area greening structure and a construction method using a water battery layer, characterized in that consisting of.

Much of the earth's area is being dried every year, not only because of natural factors such as droughts and topographical features, but also due to human factors such as deforestation and global warming due to environmental pollution. Drying can cause floods and landslides due to forest deprivation, so it is necessary to green the dry areas to prevent such natural disasters.

However, in order to artificially create forests in dry areas, evaporation of moisture should be minimized so that plants can maintain moisture for a long time with a small amount of water supply. As a method for maintaining moisture over a long period of time, conventional plants employ a method of intermittently supplying water to soil and plants in a water storage tank buried underground. However, this method has a problem that not only additional air is required to install the water storage tank, but also a cost for maintaining it. In addition, when the water storage tank is corroded or deteriorated durability, it is difficult to determine whether the water supply to the plant could lead to the death of the plant.

On the other hand, in the case of a dry area consisting of slopes, in addition to the water supply problem, the problem of erosion and collapse of the slope and securing the soil enough to grow plants should be solved. In order to prevent the erosion of the slope in the prior art, there was a method of installing a net on the surface of the slope, this method was difficult to secure the stability of the soil layer structurally.

An object of the present invention created to solve the above problems is as follows.

First, in the greening of dry areas, it is intended to provide a dry area greening structure and its construction method using a water battery layer that can supply moisture to plants continuously and long term.

Secondly, in the greening of slopes, it is intended to provide a dry area greening structure and its construction method using a water battery layer that can prevent erosion and collapse of the slope and secure effective soil depth of the plant.

Third, through the formation of artificial forests through greening of dry areas, we will provide a dry area greening structure and construction method using water battery layer that can reduce the probability of natural disasters such as flood or landslide and promote pleasant environment. .

In order to solve the above problems, the following problem solving means are suggested.

1. Measures to continuously supply moisture to plants

(1) Buried a layer of water battery in the ground to provide long-term moisture to plants. Here, by using a porous foam glass lightweight insulation material as the water battery layer, the supplied moisture is stored in the pores to be maintained for a long time.

(2) A horizontal pipe for supplying water to the water battery layer is provided near the top surface of the water battery layer. At this time, since a plurality of water supply holes are installed in a horizontal pipe spaced apart at regular intervals along the length direction, water is accurately delivered to a desired position, and water loss due to evaporation is minimized.

(3) Install an automatic moisture supply system that measures the humidity and temperature in the drying zone and automatically supplies water to the horizontal pipes according to these humidity and temperatures.

2. Measures to prevent the collapse of slopes and to secure effective soil depth

(1) Under the soil layer, form a composite fiber layer in which radial fibers are mixed in sandy soil. Continuous fibers mixed three-dimensionally in the composite fibrous layer imparts cohesive force to the sandy soil structurally stabilizes the slope, and secures the roots of the plant safely.

(2) Install a cotton layer on the surface of the slope to protect the soil layer and prevent the collapse of the slope. Cotton layer promotes germination and growth of plants through warming and moisturizing.

In addition, a zinc-coated net is installed on the top of the cotton layer to stabilize the slope surface.

According to the present invention as described above is expected the following effects.

First, in the case of greening the dry area using the water battery layer, it is possible to continuously and long-term water supply to the plant with only a small amount of water.

Second, in the greening of the slope, the composite fiber layer is included, thereby preventing the erosion and collapse of the slope and securing the effective soil depth of the plant.

Third, due to the formation of artificial forests in dry areas, it is possible to lower the probability of natural disasters such as floods and landslides and to promote a pleasant environment.

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

1 is an embodiment of a dry area greening structure using the water battery layer 100 of the present invention.

The present invention is to record a dry area as shown in Figure 1, a plurality of water battery layer 100 is buried in the ground and a plurality of spaced apart at a predetermined interval near the upper surface of the water battery layer 100, the water It consists of a horizontal pipe 200 for supplying moisture to the battery layer 100, and the soil layer 400 is installed on the water battery layer 100.

Here, the water battery layer 100 may be composed of a porous foam glass lightweight insulation. When the water battery layer 100 is made of a porous material, since the bubble portion contains water and gradually evaporates it, the plant can maintain moisture for a long time. In particular, the foamed glass is excellent in workability due to the properties of the inorganic glass and light weight due to bubbles.

In this case, the foamed glass lightweight insulation includes SiO _2, and may have a specific gravity of 0.1 to 0.2 and a water content of 10 to 50%. In particular, the foamed glass is foamed by applying apatite containing calcium and magnesium to the foaming of glass powder. Porosity, pore size, specific gravity and absorption rate of glass lightweight insulation can be adjusted. Specifically, the foamed glass lightweight insulation material is calcium and magnesium hydroxide apatite (Ca) formed by the hydration reaction of calcium hydroxide (CaOH ₂ ), magnesium hydroxide (MgOH ₂ ) or dolomite (MgCO ₃ .CaCO ₃ ), phosphoric acid (H ₃ PO ₄ ). _{10 (1-x)} Mg _10x (PO ₄ ) ₆ (OH) ₂ , where X means the molar concentration of Ca and Mg), mixed and fired powder and glass powder can be used.

Here, the foam glass lightweight insulation material is ⅰ) calcium hydroxide (CaOH ₂ ) and magnesium hydroxide (MgOH ₂ ) or dolomite (MgCO ₃ .CaCO ₃ ) is diluted in water and mixed, and then in the temperature range of 50 ℃ or less than 100 ℃ Step of heating and stirring, ii) 25 to 85% by weight of phosphoric acid (H ₃ PO ₄ ) is added to the stirring process, stirred while maintaining a pH of 8 to 10, 100 ℃, dried and pulverized Filtering to obtain calcium magnesium hydroxide apatite (Ca _{10 (1-x)} Mg _10x (PO ₄ ) ₆ (OH) ₂ , where X represents the molar concentration of Ca and Mg), i) the calcium magnesium Hydroxide apatite is added and mixed in an amount corresponding to 1/50 to 1/5 of the weight of the glass powder, followed by drying, sieving, and iii) shaping the mixed powder, and then putting it in an electric furnace to raise it to 5 ° C / min. After heating up to 800 ~ 900 ℃, it is maintained at that temperature for 10 ~ 30 minutes, and then fired. It can be prepared through a natural cooling step.

When the greening of the horizontal area as shown in Figure 1, the depth of the water battery layer 100 is maintained about 10 ~ 15cm.

Next, the horizontal pipe 200 is embedded in the upper portion of the water battery layer 100 or installed on the upper surface of the water battery layer 100 to serve to supply water to the water battery layer 100.

At this time, the horizontal pipe 200 is formed in a plurality of water supply holes spaced apart at regular intervals along the length direction. The water supply port intermittently supplies the water at low flow rate and low flow rate to the water battery layer 100 according to the water penetration capability of the water battery layer 100. In addition, since the horizontal pipe 200 supplies water to the desired position of the water battery layer 100, it is possible to minimize the loss of water.

Next, Figure 2 is another embodiment of a dry area greening structure using the water battery layer 100 of the present invention.

2 shows a dry area greening structure formed on a slope.

In the case of slopes, in particular, the stability of the soil constituting the slope is a problem. In order to solve this problem, between the water battery layer 100 and the soil layer 400 is installed a composite fibrous layer 300 mixed with fibers of sandy soil and fleeting.

Here, the radial continuous fibers are injected along with the jet water from the injection nozzle through the fiber supply device, and the sandy soil is transferred to the installation nozzle by the high pressure air from the installation machine.

At this time, the composite fibrous layer 300 secures an effective depth of at least 20 cm so that the plant can be stably settled. In particular, when the inclination (the ratio of the horizontal distance to the vertical distance) is 0.7 or less, it is desirable to secure an effective depth of 30 cm or more. On the other hand, in the case of the slope, the water battery layer 100 is to maintain 20cm or more.

In addition, the greening structure of the dry area using the water battery layer 100 of the present invention includes a cotton layer 500 is installed on the soil layer 400 and the net 600 is installed along the ground surface from the cotton layer 500 top. It is characterized by.

Cotton layer 500 is in close contact with the soil layer 400 to prevent erosion or loss of the slope, to promote the germination and growth of the plant by keeping warm, moisturizing, the net 600 can be used galvanized.

Next, Figure 3 is another embodiment of a dry area greening structure using the water battery layer 100 of the present invention.

Here, the dry region greening structure using the water battery layer 100 includes a humidity measuring sensor 700 for measuring the humidity of the dry region, a temperature measuring sensor 710 for measuring the temperature of the drying region, and the horizontal pipe 200. It may be configured to include an automatic water supply device 720 for supplying water, and a desalination facility 730 for providing water to the automatic water supply device 720.

It is a component that supplies moisture to a dry area by using an automated facility. Once the humidity and temperature of the dry area are measured and the data is transmitted to the automatic water supply device 720, the amount of water required for the area is automatically displayed. Calculated by the automatic moisture supply device 720 is to supply the required water. At this time, the water provided to the automatic water supply device 720 is water in the form of the salt is removed through a separate desalination facility (730).

On the other hand, the dry region greening method using the water battery layer 100 of the present invention is made through the following process.

In the case of greening the dry area, in particular, in the case of slopes, the steps of (a) embedding the water battery layer 100 in the ground and (b) selecting the top surface of the water battery layer 100 should be preceded.

Next, (c) the plate anchor is installed vertically downward through the water battery layer 100, the plate anchor is for structural stabilization of the soil to form a slope.

And (d) installing a plurality of drain plates spaced apart from each other by a predetermined interval on the water battery layer 100, and (e) installing drain drain lines interconnecting one end of the plurality of drain plates. Drainboard and drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage drainage and drainage drainage are drainage drainage and drainage.

Next, (f) forming a composite fibrous layer 300 in which sandy soil and radial fibers are mixed on the water battery layer 100 and providing a soil layer 400 on the composite fibrous layer 300 to green the dry areas. Finish the construction related to

As described above, the cotton layer 500 and the net 600 may be added to the soil layer 400.

Meanwhile, in any one of the steps before the step (d), a plurality of horizontal pipes 200 for supplying water to the water battery layer 100 near the upper surface of the water battery layer 100 are provided to be spaced apart at regular intervals. May be further included.

While the invention has been described in connection with the preferred embodiment as mentioned above, various modifications and variations are possible without departing from the spirit of the invention. Therefore, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

1 is an embodiment of a dry area greening structure using a water battery layer of the present invention.

Figure 2 is another embodiment of a dry area greening structure using a water battery layer of the present invention.

Figure 3 is another embodiment of a dry area greening structure using the water battery layer of the present invention.

Figure 4 is a flow chart of a dry area greening method using a water battery layer of the present invention.

<Description of Major Symbols in Drawing>

100: water battery layer

200: horizontal pipe

300: composite fiber layer

400: soil layer

500: cotton layer

600: net

700: humidity sensor

710: temperature measuring sensor

720: automatic moisture supply device

730: desalination plant

Claims (9)

In recording a dry area, A water battery layer 100 embedded in the ground; A plurality of horizontal pipes 200 which are spaced apart from each other by a predetermined interval near the top surface of the water battery layer 100 and supply water to the water battery layer 100; And, A soil layer 400 installed on the water battery layer 100; to Drying area greening structure using a water battery layer 100, characterized in that made. In claim 1, It is installed between the water battery layer 100 and the soil layer 400, the composite fibrous layer 300 mixed with sandy soil and radial fibers; this Drying area greening structure using a water battery layer 100, characterized in that it is included. In claim 2, Cotton layer 500 is installed on the soil layer 400; And, A net 600 installed along the surface of the cotton layer 500 above; end Drying area recording structure using the water battery layer 100, characterized in that provided. The method according to any one of claims 1 to 3, The water battery layer 100 is a dry area greening structure using a water battery layer 100, characterized in that made of porous foam glass lightweight insulation. In claim 4, The foamed glass lightweight insulation includes SiO ₂ , specific gravity of 0.1 to 0.2, dry area greening structure using a water battery layer 100, characterized in that the water content is 10 to 50%. The method according to any one of claims 1 to 3, The horizontal pipe 200 is a plurality of water supply holes spaced apart at regular intervals along the longitudinal direction; end Drying area greening structure using a water battery layer 100, characterized in that formed. The method according to any one of claims 1 to 3, Humidity measurement sensor 700 for measuring the humidity of the dry area; A temperature measuring sensor 710 measuring a temperature of a dry region; Automatic moisture supply device 720 for supplying water to the horizontal pipe (200); And, Desalination plant 730 to provide moisture to the automatic water supply device 720; Drying area greening structure using a water battery layer 100, characterized in that provided. For greening dry areas (a) embedding the water battery layer 100 in the ground (b) selecting an upper surface of the water battery layer 100; (c) installing a plate anchor vertically downward through the water battery layer 100; (d) installing a plurality of drain plates spaced apart from each other by a predetermined interval on the water battery layer 100; (e) installing a drain drain interconnecting one end of the plurality of drain plates; And, (f) installing a composite fibrous layer (300) incorporating sandy soil and radial fibers on the water battery layer (100); in Drying area greening method using a water battery layer 100, characterized in that made. In claim 8, Before the step (d) is installed a plurality of spaced apart at a predetermined interval near the upper surface of the water battery layer 100, embedding a horizontal pipe (200) for supplying water to the water battery layer (100); end Drying area greening method using a water battery layer 100, characterized in that it further comprises.

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