KR20130079594A - Method for manufacturing artificial paving that help improving grobal warming - Google Patents

Abstract

Methods of making artificial pavements are provided to help improve global warming. A drainage layer containing gravel or sand is selectively formed under the permeable pavement layer, and an interface layer is formed below the drainage layer. An ecological gradient layer is installed. The ecological gradient layer on the underside provides a supporting effect and, due to the ecological gradient layer containing the hollow bodies, can be embodied as a disaster-resistant low hollow body or a soil improving hollow body or a microbial cultured hollow body or a repaired hollow body as needed. Due to the ecological gradient layer containing the hollow body, the rainwater falling on the surface of the earth rapidly penetrates underground, so that the ecological gradient layer effectively conserves water at high water content and promotes the growth of microorganisms, so that when the air temperature is high, Underground moisture may be released through the drain pipe forming the permeable pavement surface.

Description

Method for Manufacturing Artificial Paving That Help Improving Grobal Warming}

BACKGROUND OF THE INVENTION Field of the Invention The present invention generally relates to a method for producing artificial pavement surfaces that help improve global warming, and more particularly, to underground ecological gradation layers and artificial permeable surface pavements. It relates to an artificial pavement consisting of microorganism strains and soils in the soil of the ecological gradient layer for rainwater to be stored effectively and effectively guided to the underground gradient layer to save rainwater and reduce surface flooding. It is possible to create an excellent breeding environment for protozoa, whereby the soil remains wet, thereby achieving temperature and humidity control of the surrounding soil and improving soil quality.

In general, the conventional manufacture of concrete pavement surfaces is carried out by pouring a sufficient amount of cement grout into the ground, leveling the cement grout, and then installing brick tiles on it to form artificial concrete pavement surfaces.

Typical pavement is made of concrete, or a combination of concrete and brick, and concrete is generally impermeable. Although the concrete is permeable concrete, the pores of the concrete are easily blocked. In addition, concrete can produce calcium oxide that can clog pores and remove it, making it impossible to clean, so permeability can be much lower than precipitation. When rainwater collects on the ground, flooding can easily occur due to large amounts of precipitation if rainwater does not flow efficiently into the underground soil.

In the construction of public roads or in urban areas, the pavement surface of the construction site is sometimes made integrally as an impermeable surface pavement layer. This prevents underground soils from contacting the atmosphere above the pavement and prevents groundwater replenishment with rainwater. This damages the environment. It is clear that pavement structures made of impermeable concrete are not ideal. In cities, when it rains, the surface is poorly permeable, so most rainwater must be drained through the city's sewage drainage system. Finally, rainwater is collected from underground main ducts in sewage discharge systems and discharged into the ocean or ocean. This is just a natural source of rainwater. In addition, rainwater can cause flooding once it flows to areas of low altitude.

When the soil absorbs water and comes into contact with the atmosphere in a dry or hot environment, it can evaporate moisture to create a heat exchange effect with the atmosphere, and automatically adjust the humidity to heat island effect. Can be avoided.

If water permeability is not efficient, it is known that the drainage of rainwater to the surface becomes poor. Therefore, it is important to construct a gradient layer that is effective in maintaining water permeability and conserving water. In addition, in order to improve the soil environment and the ecological environment on the earth, a favorable environment is needed for the microorganisms in the soil and the soil protozoa. In general, microorganisms inhabiting soil include bacteria (eubacteria and fungi), fungi (fungus and yeast) and algae. Soil protozoa include, for example, amoeba and ciliary worms. A huge number of ciliates are present in the soil, which contributes greatly to the decomposition of organic matter. Insects, including ants, centipedes, aphids, and ticks, help to transport soil or to digest the debris of an organism, thus helping to provide organic matter. Earthworms can help form soil pellets that are good for ventilation and drainage. Nematodes help the digestion of organic matter or other small creatures. There are also vertebrates (such as rats) that live in the soil, which excavate the soil and provide excreta to fertilize the soil. In addition, they are a number of underground food chains.

Soil microbes play an important role in preserving soil quality. The presence of soil microorganisms is an important factor in the change and quality of the soil environment.

Important microbial studies of soils include:

(1) performing mineralization by decomposition of organic matter and complete decomposition of organic matter into nutrients;

(2) fixation of nitrogen (N ₂ ) in the atmosphere, and conversion to NH ₃ , which serves as a useful source of nitrogen for the organism;

(3) promotion of nitrification, which converts NH ₄ ⁺ into nitrite nitrogen (NO ₂ ⁻ ) and then converts it to nitrate nitrogen (NO ₃ ⁻ ) which is readily adsorbed by the plant;

(4) performing de-nitrification to convert NO ₃ ⁻ to N ₂ O and N ₂ ;

(5) promoting dissolution of bound or immobilized chemical compounds (eg phosphorus, sulfur, iron and magnesium); And

(6) Interaction with other soil microorganisms, which plays an important role in the survival of other soil microorganisms.

Thus, establishing a good environment for mass propagation of soil microorganisms is beneficial for soil improvement. In addition, a low gradation layer is formed below the artificial pavement layer to make mutual contact between the water-permeable pavement layer and the top surface. Through mutual contact with soil and air, heat exchange due to temperature and humidity is performed like a breath, helps to realize efficient drainage, and eliminates the potential risk of water gathering on the surface, thus providing a practical effect.

Accordingly, it is an object of the present invention to provide a method of manufacturing artificial pavement surface which helps to improve global warming by quickly guiding rainwater falling on the ground to the underground soil, and by forming an artificial pavement surface with high permeability Reduces the risk of potential flooding in the country, collects and stores water and helps to recycle precipitation sources.

It is another object of the present invention to provide a method for producing artificial pavement surface which helps to improve global warming, by converting an underground gradient layer into an ecological gradient layer to increase the water content, so that the external temperature increases, the artificial pavement Due to the cotton drainage pipe, the water contained underground is converted to steam and released into the atmosphere to control the ambient temperature and humidity, thus eliminating or reducing the heat island effect.

It is still another object of the present invention to provide a method of manufacturing artificial pavement to help improve global warming. The present invention provides a drainage pipe capable of enhancing absorption and draining and storing water underground and a drainage pipe capable of draining and condensing. As it includes an underground ecological gradient layer that uses a permeable surface pavement layer to provide, the water permeable surface pavement layer is guided through the enormous number of drainage pipes installed in this way to direct the surface storms to the underground gradient layer and allow water to penetrate into the groundwater layer. Enhancing the formation of an excellent environment for the microbes and soil protozoa inhabiting the surrounding soil, and the gradient layer is formed as an ecological gradient layer, thus improving global warming effect between the soil and the air above the earth's surface.

In order to achieve the above object, the present invention provides a permeable artificial pavement structure, wherein a drainage layer comprising gravel or sand is optionally formed under the surface pavement layer, or alternatively, an interfacial layer is formed below the drainage layer. It is. Subsequently, an ecological gradation layer is provided and put. The bottom ecological gradient layer provides a supportive effect and, if necessary, a disaster-prevention water-storage hollow body or earth-improvement hollow body or microorganism- Due to the ecological gradient layer containing the hollow body, which can be embodied as a culture hollow body or water-keeping hollow body, the ecological gradient layer has a high water content so that rainwater falling on the ground surface can quickly penetrate into the underground location. It effectively preserves water and promotes the growth of microorganisms, which can provide an effective way to improve the environmental warming by releasing moisture from the underground through the drain pipe forming the permeable pavement when the air temperature is high. The permeable pavement surface may include a framework that pours cement grout to form multiple drainage pipes for drainage, and similarly fabricates artificial pavement structures that help improve global warming, drainage and air storage As a water impermeable pavement structure using hard pavement concrete with a large number of drainage holes formed using a hole drilling tool for receiving and maintaining a plurality of functioning condensate tubes and / or a plurality of drainage and reservoir reservoirs. It may be formed.

1 is a schematic diagram illustrating an artificial strata constructed in accordance with the present invention.
2 is an enlarged view of the drainage structure of the permeable pavement surface according to the present invention.
3 is a perspective view of the drainage structure of the permeable pavement surface of the assembled form according to the present invention.
Figure 4 is an enlarged view of an air storage drain pipe according to the present invention.
5 is an enlarged view of a reservoir according to the present invention.
6 is a schematic view showing a gradient layer mixed with a hollow body according to the present invention.
7 is an enlarged view showing various structures of the hollow bodies providing different functions according to the present invention.
8 is a cross-sectional view showing the drain and condensation tube included in the permeable pavement surface according to the present invention.
9 is a cross-sectional view showing the drain and reservoir included in the permeable pavement surface according to the present invention.
10 is a cross-sectional view showing another embodiment according to the present invention in which the drain is drilled in the concrete pavement surface.
11 is an enlarged view of a condensation tube capable of drainage and air storage, in accordance with another embodiment of the present invention.
12 is a perspective view of the pipe of FIG. 11 in assembled form;
13 is a cross-sectional view of the pipe of FIG. 11 embedded in a concrete pavement surface, in accordance with the present invention.
14 is an enlarged view of a reservoir capable of drainage and storage, in accordance with another embodiment of the present invention.
15 is a perspective view of the pipe of FIG. 14 in an assembled form.
16 is a cross-sectional view of the pipe of FIG. 14 embedded in a concrete pavement surface, in accordance with the present invention.
It is sectional drawing which shows the alternative form of the water storage pipe of this invention shown in FIG.
18 is a cross-sectional view illustrating an ecological gradient layer in accordance with another embodiment of the present invention.

Referring to FIG. 1, the present invention provides a method of manufacturing an artificial pavement surface, which helps to improve global warming, including providing an ecological gradient layer 10 after leveling the ground surface. The ecological gradient layer 10 may comprise on-site soil and / or gradient materials commonly used in road construction, including mixtures of aggregates, sand, gravel, and moisture-permeable concrete, as well as unique hollow bodies 11 that are of additional importance. Can be. All components are mixed and laid on the floor, pressed to ramming, and then optionally further provided with an interfacial layer 20 thereon. The interfacial layer 20 may comprise a portion of a nonwoven or net, or a sand layer. The drainage layer 30 is provided on the interface layer 20. Drainage layer consists of gravel (or crushed stone) or sand or a combination thereof. Finally, a permeable pavement layer 40 is installed over the drainage layer 30. Through this arrangement, the rainwater falling to the ground reaches the groundwater layer 60 located below the underground soil layer 50 by allowing it to penetrate all artificially placed strata, so that the groundwater is delivered deep below the ground to further Acts as a groundwater source, and when the gradient layer is used in combination with the permeable pavement layer 40, it can be modified to serve as an ecological gradient layer 10 that provides a versatile function, and also provides soil microorganisms. And a good survival environment for soil protozoa.

The interfacial layer 20 and the drainage layer 30 may be used alone or in combination. As an alternative, the permeable pavement layer 40 can be installed directly over the ecological gradient layer 10 and the interface layer 20 and drainage layer 30 can be optionally added according to the actual drainage of the construction site, thereby providing similar effects of drainage and the earth. Realize protection against warming.

2 and 3, the water-permeable packaging layer 40 (as shown in FIG. 1) includes a plurality of drain pipes 41, an upper connecting frame 42, a lower connecting frame 43, And a framework consisting of a sealing lid moldboard 44, a condensation tube 45 and a reservoir 46 for air storage. The condensation tube 45 provides the function of air storage and preservation, so that when filled in large quantities, a living space for providing air to underground microorganisms is maintained. Each drain pipe 41 has a top end portion forming a diameter reducing portion 411 and a bottom end portion forming a retaining ring 412 and a retaining wedge 413 (see FIG. 4). The diameter reducing portion 411 located at the upper end of the drain pipe 41 can be fitted directly into the barrel 421 formed in the upper connecting frame 42, while the lower end of the drain pipe is connected to the lower connecting frame 43. It fits into the formed collar 431 such that the collar 431 is received and held between the retaining ring 412 and the retaining wedge 413. The drain pipe 41 is a hollow member. While pouring the cement slurry or grout, a plurality of seal covers 441 are provided to hold the seal cover earth plate 44 firmly in place and to prevent the cement formulation from filling the drain pipe undesirably. Formed on the underside of the earth plate 44, the sealing lid 441 fitted into the top opening of the drain pipe 41 while pouring the cement compound prevents the cement mixture from filling up the pipe and clogging it ( Note: Figure 3). The earth plate and cover can then be removed after the poured cement has hardened to a solid to form a permeable pavement layer of concrete structure.

Referring to FIG. 4, as shown in the preferred embodiment illustrated in the figure, a condensation tube 45 with an air storage function is made such that the outer tube 414 fits into and is coupled to the drain pipe 41. Since the outer pipe 414 forms a circumferential gap 4414 therein, by combining the drain pipe 41 and the outer pipe 414, a drain pipe structure capable of draining, exhausting, and condensing and collecting water is formed. In other embodiments, the circumferential gap 4414 may be formed limited by the inner surface of the outer pipe and the outer surface of the drain pipe when the outer pipe and the drain pipe are combined with each other.

Referring to FIG. 5, the reservoir 46 is coupled to the end of the drain pipe 41, in particular the bottom end. Structurally, the reservoir 46 includes a top cover 461 and a base box 462. The top cover 461 has a hole 4611 formed in the top, and the rim 4612 is formed along the circumference of the top cover. The top cover 4611 has an outer diameter that is greater than the outer diameter of the base box 462, thereby preventing cement grout or slurry from entering the base box during grouting or preventing sand in the drainage layer from entering the base box. . Base box 4462 includes a central tube 4462 and a circumferential gap 4462 around the central tube. The base box has spot protrusions 4403 formed spaced apart from the top. The central tube 4462 has an inner surface to which the protruding rib 4624 is formed to assist the holding of the base box 462 when the base box is fitted to the lower end of the drain pipe, and thus the drain pipe 41 and the reservoir ( 46 join together to form a drainage structure that allows drainage, exhaust, and storage / storage of water. The spot protrusion 4603 functions to provide a gap for the water inlet passage between the top cover 461 and the base box 462 when the top cover and the base box are fitted to each other. In another embodiment, the central tube 4462 is formed such that the top end of the central tube is higher than the top of the outer circumferential wall of the base box 462, so that the top cover 461 and the base box 462 fit together. In this case, a gap is formed to serve as a water polo passage.

6 and 7, the ecological gradient layer 10 may include soil on site, including aggregates of agglomerates, sand, gravel, and moisture-permeable concrete, and other gradient materials that do not optionally harm the environment. Example: ceramic particles), and is generally formed into a hollow body (11). The hollow body 11 exhibiting a unique function is preferably in the form of a sphere, and in the case of a sphere structure, it is more resistant to compressive stress from any direction and provides voids in the gradient layer. However, other forms may be employed which can be easily manufactured. The hollow bodies 11 are each composed of bisectors constituting the shell member 111, or alternatively, the hollow bodies 11 are preferably integrally formed of a single hollow body manufactured by blow molding or perfusion molding. . The hollow body is preferably made of plastic, but can be made of other traditionally used materials. The shell member of the hollow body is made of a thick wall, and each shell member 111 is formed with a plurality of through apertures 112. The hollow bodies 11 used in the present invention are engineering hollow bodies for different uses (e.g., disaster-resistant water hollow bodies, soil-improving hollow bodies, microbial cultured hollow bodies or repair hollow bodies), or others that meet the needs of field use. It can be produced as a tangible hollow body.

As shown in the embodiment illustrated in the figure, the disaster-resistant water saving hollow body includes two shell members 111, which combine with each other to form one hollow body, which has a through hole 112. ) Is formed. Therefore, when the hollow body is compounded in the gradient layer during extreme precipitation, when the permeable pavement layer 40 needs to effectively deliver the rainwater, the gradient layer 10 reaches the instantaneous saturation water content, and the water The silver is guided to the interior space of the hollow body by the through holes 112 of the shell, so that the chance of surface overflow in the relevant area can be prevented. As sufficient time elapses, the water slowly penetrates into the groundwater layer, and then the water contained in the disaster prevention reservoir is gradually released. This ensures the effect of effective drainage on the earth's surface.

The soil reforming hollow body is composed of two shell members 111, which are bonded together and filled with carbonaceous material 113 (e.g. activated carbon or binchotan) or soil modifiers necessary for the improvement of local soil. When the soil-improving hollow body is mixed in the gradient layer, thereby forming a space, the carbon-containing material 113 penetrates downward to pass through the soil-reforming hollow body or to carry the number of oxidizing substances or harmful substances contained in the surrounding soil. It absorbs and activates to realize improvement of soil quality.

The microbial culture hollow body consists of two shell members 111, which combine to form an interior that serves to attach the selected microbial strain 114 to serve as an excellent culture site for a large amount of microorganisms. As the microbial culture hollow bodies are mixed in the gradient layer, the microorganisms can be effectively cultured, providing an improved environment for growth. The microorganisms thus cultured can help to decompose the organic substances contained in the soil, promote nitrification, perform de-nitrification, and improve the ecological environment of the soil.

The maintenance hollow consists of two shell members 111, which combine to form an interior filled with absorbent material 115 (e.g., a sponge or other absorbent material that is not degraded by microorganisms), Therefore, when the repairing hollow body is mixed in the gradation layer, the absorbing material 115 assists the absorption of the water when the water flows out of the hollow body so that the water does not overflow from the soil, thereby supplying the survival and growth of the microorganisms. This becomes sufficient and can improve water retention and increase water content in dry areas. When the surface temperature is high, the high water content in the soil converts the water into steam, thereby releasing it into the surrounding environment during heat exchange, so that the heat island effect can be eliminated or reduced.

Referring to FIG. 8, the water-permeable packaging layer 40 includes a plurality of condensation tubes 45 which serve as an air storage function in the structure thereof, an upper connecting frame 42 attached to upper and lower ends of the condensation tubes, respectively. And a lower connection frame 43. Each condensation tube 45 is formed with a circumferential gap 4414 therein. In cold regions, when ambient temperature is low, steam or moisture from underground drainage layer 30 where the soil temperature is above ambient temperature above the earth's surface may be converted into condensate 4143 at the wall of circumferential gap 4414. Therefore, natural replenishment of soil water can be realized by extracting water from the atmosphere. In the case of precipitation, rainwater falling on the surface pavement layer is guided to the barrel 421 by a water conduction groove 401, flows down the drain pipe 41, and then enters the drainage layer 30. Water can be collected effectively and water can be avoided flowing directly along the sewage treatment system into the sea, which represents a waste of water resources. In addition, in the case of severe precipitation causing flooding, the condensation tube 45, which functions as a water reservoir, forms a sealed air reservoir due to the closed upper end of the circumferential gap 4414, thus conserving air and preventing microbial or soil proliferation. In order to provide air to the animals, emergency evacuation areas are provided, which, in flood areas, can survive drowning by taking the air preserved in the evacuation area. As microorganisms or protozoa survive, short-term rapid recovery is possible, and organic matter contained in the soil can be provided.

3, 5 and 9, the water-permeable packaging layer 40 is between the plurality of tanks 46 and the upper connection frame 42 and the lower frame 43 to store and collect water therein. It includes structurally a drain pipe 41 fixed to the. At least one or each drain pipe 41 has a bottom end to which each water tank 46 is attached (see FIG. 3). The reservoir 46 is composed of a top cover 461 and a base box 462. The base box has a central tube 4651 having a top end provided with a spot protrusion 4603 located at a higher position or spaced apart to form a water polo passage (see FIGS. 5 and 9). When the drainage layer 30 is saturated with water, the water penetrating downwards is guided through the air inlet passage into the circumferential gap 4462 formed in the tank where the water is stored and collected. Such stored water becomes a beverage for microorganisms or soil protozoa that live in the surrounding soil during a drought so that the microorganisms or soil protozoa survive. It also affects the regulation of groundwater temperature and humidity to maintain plant survival and prevent desertification.

Referring to Figures 10, 11, and 14, another embodiment of the present invention is illustrated, wherein the water-permeable pavement layer is selected after the pavement layer 40a is even after the ground is selected and the ecological gradient layer 10 is installed. It is constructed in such a way that it is formed on the ecological gradient layer 10. The pavement layer 40a preferably includes a reinforcing bar 402, which may be arranged in the form of a tessellate or may be added together with other reinforcing materials. Subsequently, the cement grout is poured onto the reinforcing material and the grout is cured to form a hard concrete pavement surface. As an alternative, the pavement layer 40a is formed without concrete and reinforcement, instead the pavement layer is made of asphalt. The hole drilling tool 47 is then used to form a plurality of drains 403 on the hard pavement surface. The condensation pipe 45a (see FIG. 11) capable of drainage and air storage [see FIG. 11] or the reservoir and drainage water reservoir 46a [ref. Use separately or individually. At least one of these two pipes is selected and fitted to a previously formed drain 403. In this way, artificial pavements are made similar that help to improve global warming.

11, 12, and 13, the condensation tube 45a capable of drainage and air storage in the form of individual tubes shown in FIG. 10 structurally includes an inner tube 41a and an outer tube 414a. The inner tube 41a is a hollow tube having a diameter expanding columnar flange 415 formed at the top. The outer tube 414a has a hole 4141 formed in the top portion. The outer tube 414a has an inner wall forming the inner inclined surface 4144. The outer tube 414a has an outer wall forming the protruding structure 4145. The packaging layer 40a forms a water-permeable packaging layer through the condensation tube 45a appropriately fitted to the drain hole 403 formed in the packaging layer 40a (as shown in FIG. 13). When the water-permeable pavement layer 40a overflows, the ecological gradation layer 10 is completely saturated with water, and excess water is led to the circumferential gap 4142 (see FIG. 13). However, the amount of air is preserved at the top of the circumferential gap, so in the event of a flood, there is room for aeration and survival for microorganisms and soil protozoans standing in the surrounding soil. In addition, the wall surface of the circumferential gap between the outer tube 414a and the inner tube 41a may constitute a structure for condensing water.

Referring to FIGS. 14, 15, and 16, the water storage pipe 46a capable of storing individual water in the form of individual pipes and air storage shown in FIG. 10 includes a water discharge pipe 41b to which a water storage tank 46 is attached. . The reservoir 46 is composed of a top cover 461 and a base box 462. The top cover 461 has a hole 4611 formed in the top, and the rim 4612 is formed along the circumference of the top cover. Top cover 461 has an outer diameter that is greater than the outer diameter of base box 462. Base box 4462 includes a central tube 4651 and a circumferential gap 4462 around the central tube. The base box preferably has spot protrusions 4403 formed spaced apart from the top. The central tube 4641 has an inner surface on which the protruding ribs 4624 are formed, so that when the base box 462 is fitted to the distal end of the drain pipe 41b, the interference fit made by the protruding ribs 4424 is provided. fitting) to maintain the base box, so that the drain pipe 41b and the reservoir 46 combine together to form a reservoir pipe 46a where both drainage and storage are possible. In the illustrated embodiment, the top of the base box 462 is provided with a spot protrusion 4603 to form a water polo passage. In another embodiment, the central tube 4462 is arranged to have a top portion A positioned higher than the top portion B of the outer wall of the base box 462 (see FIG. 16), so that the water polo passage covers the top portion. When the 461 and the base box 462 are fitted to each other, it may be formed between the top cover 461 and the base box 462.

As illustrated in the embodiment of FIG. 16, when the reservoir 46a fits into the drain 403 already formed in the paving layer 40a (see FIG. 16), the paving layer 40a It is comprised as a water permeable packaging layer. The rainwater that falls into the pavement layer 40a and is permeated is guided to the bottom ecological gradient layer 10, and once the bottom ecological gradient layer 10 is saturated with water, excess water is passed through the circumferential passage through the circumferential gap 4462. Are stored and stored there. This stored water can serve as a water source for microbes and protozoa that live in the surrounding soil during drought. It also affects the regulation of groundwater temperature and humidity to maintain plant survival and prevent desertification.

If desired, an interfacial layer, drainage layer, or both may optionally be added between the ecological gradient layer 10 and the permeable pavement layer 40a, depending on local soil quality.

Referring to Figure 17, another type of reservoir is shown in accordance with the present invention, which is made in the form of a separate reservoir 46b capable of drainage and reservoir. The reservoir pipe 46b structurally includes a drain pipe 41c and a base box 462 attached thereto. The drain pipe 41c has a top portion having an outer circumference in which the rim 416 is formed such that the rim 416 has an outer diameter larger than the outer diameter of the base box 462. The base box 462 includes a central tube 4651 and a circumferential gap 4462. The base box preferably has spot protrusions 4403 formed spaced apart from the top. The central tube 4641 has an inner surface on which the protruding ribs 4624 are formed, so that when the base box 462 is fitted to the distal end of the drain pipe 41c, the base is formed by the clamp fitting made by the protruding ribs 4624. A water reservoir 46b is provided, which helps to maintain the box, so that both drainage and water storage are possible.

In the illustrated embodiment, the top of the base box 462 is provided with a spot protrusion 4603 to form a water polo passage. In another embodiment, the central tube 4651 is arranged to have a top portion A positioned higher than the top portion B of the outer wall of the base box 462, so that the water polo passage is a top cover 461 and a base box. When the 462 is fitted to each other, it may be formed between the top cover 461 and the base box 462.

Referring to FIG. 18, in the illustrated embodiment, the ecological gradient layer 10 may be formed of on-site soil or gradient material commonly used in road construction, which is a mixture of aggregates, sand, gravel, and concrete. It may include, and may further include other gradient material that does not harm the environment. The gradient layer may comprise a hollow body 11 which has a unique function. The hollow body 11 may be arranged such that a plurality of hollow bodies are received and held in a net bag to form the hollow body containing bag unit 12. The hollow body containing bag unit 12 may be disposed directly as a gradient layer, or the hollow body containing bag unit 12 may be combined with soil to form a gradient layer. This also provides the same effect as discussed above.

10: ecological gradient layer 11: hollow body
111: shell member 112: through hole
113: carbon-containing substance 114: microbial strain
115: absorbent material 12: hollow-containing bag unit
20: interfacial layer
30: drainage layer
40: permeable pavement layer 40a: permeable pavement layer
401: frequency groove 402: reinforcing bar
403: drain 41
41a: inner pipe 41b: drain pipe 41c: drain pipe
411: diameter reducing portion 412: retaining ring
413: retaining wedge 414: outer tube 414a: outer tube
415: circumferential flange 416: rim
4141: hole formed on top 4142: circumferential gap
4143: condensate 4144: internal slope
4145: protrusion structure
42: upper connecting frame 421: barrel
43: lower connecting frame 431: collar
44: airtight cover earth plate 441: airtight cover
45: condensation tube 45a: condensation tube
46: reservoir 46a: reservoir 46b: reservoir
461: top cover 4611: hole formed in the top
4612: Rim
462: base box 4621: central tube
4622: circumferential gap 4623: spot protrusion
4624: extruded rib
47: hole drilling tools
50: underground soil layer
60: groundwater layer

Claims (24)

After leveling, the ecological gradient layer is installed first, where the ecological gradient layer is formed of road construction gradient material or site soil, the hollow body is mixed in the soil, the hollow body has a through hole, Sieve and gradient soils are mixed and placed together, then pressurized for ramming,
The permeable pavement layer is installed on an ecological gradient, whereby rainwater falling on the ground effectively penetrates the artificially placed layer, reaching the groundwater layer below the underground soil layer, thus guiding the groundwater to a deeper location on the ground. It consists mainly of the ecological gradient layer and permeable pavement layer, which replenishes the groundwater layer and provides an excellent environment for the microorganisms and soil protozoa inhabiting the soil and helps to improve global warming. Manufacturing method of artificial packaging cotton. The method of claim 1, wherein the interfacial layer is further provided above the ecological gradient layer and below the permeable pavement layer. The method of claim 1, wherein the drainage layer is further installed above the ecological gradient layer and below the permeable pavement layer. The manufacturing method of the artificial pavement surface of Claim 2 provided with the improvement of global warming in which a drainage layer is provided on an interface layer. The method for producing an artificial pavement surface according to claim 1, wherein the hollow body is configured as a disaster-prevention water storage hollow body including a hollow shell in which an opening is formed, and the hollow body is blended in a gradient soil. The method for producing an artificial pavement surface according to claim 1, wherein the hollow body is configured as a soil-improving hollow body having a hollow internal space to which a carbon-containing material or a soil improving agent is attached. The method for producing an artificial pavement surface according to claim 1, wherein the hollow body is constituted as a microbial culture hollow body having a hollow internal space containing microbial cells. The artificial pavement surface of claim 1, wherein the hollow body is configured as an absorbent material including a sponge which is not decomposed by microorganisms or a low water hollow body having a hollow inner space to which the absorbent material is attached. Method of preparation. The method for producing an artificial pavement surface according to claim 1, wherein each of the hollow bodies is composed of a bisecting shell member paired with each other, or integrally formed as a single body manufactured by blow molding or irrigation molding. . The method for producing an artificial pavement surface according to claim 2, wherein the interface layer comprises one of a nonwoven fabric, a net, and a sand layer. The method for producing an artificial pavement surface according to claim 3 or 4, wherein the drainage layer is composed of gravel, sand, or a combination thereof, or a sand-based gradient material. The method according to claim 1, wherein the permeable packaging layer includes a plurality of drain pipes, an upper connection frame, a lower connection frame, and a condensation tube functioning as an air storage, each condensation tube including an outer tube installed in the drain pipe, the outer tube is Artificial packaging to improve global warming, which has a hole formed in the top, and the outer tube is formed with a circumferential gap to form a drainage pipe structure capable of draining and collecting condensate by combining the drainage pipe and the outer pipe. Cotton manufacturing method. The system of claim 1 wherein the permeable packaging layer comprises a plurality of drain pipes, an upper connecting frame, a lower connecting frame, and a reservoir, each reservoir attached to an end of one drain pipe, each reservoir having an upper cover and a base. A box, the top cover having holes formed in the top, the top cover having an outer circumference with a rim formed, the top cover having an outer diameter greater than the outer diameter of the base box, the base box having a central tube and a circumference The base box including a gap, the center tube having a top portion positioned at a high position, and having a spot projection formed spaced apart from the top portion, may be provided with a water polo passage when the top cover and the base box are fitted with each other. water inlet passage, and the central tube has an inner surface forming a protruding rib, whereby the drain and reservoir Is the sum of forming a drainage and low number of free drainage pipe structure, method of artificial pavement to help improve global warming. After leveling, the ecological gradient layer is installed first, where the ecological gradient layer is formed of road construction gradient material or site soil, the hollow body is mixed in the soil, the hollow body has a through hole, Sieve and gradient soils are mixed and placed together, then pressurized to push,
The pavement layer is installed on the ecological gradient layer, the pavement layer is formed with a number of drains using a hole drilling tool,
The condensation tube, which functions as drainage and air storage, fits into the drain hole so that the packaging layer becomes the drainage packaging layer.
This allows the rainwater falling to the ground to effectively penetrate the artificially placed layer to reach the groundwater layer located beneath the underground soil layer, thus groundwater is guided deeper into the ground to replenish the groundwater layer and the ecological gradient layer is A method for producing artificial pavement, which is mainly composed of an ecological gradient layer and a permeable pavement layer, which provide an excellent environment for microorganisms and protozoa inhabiting the inside. The method of claim 14, wherein the pavement layer is made of cured concrete grout to form a hard pavement surface. The method for producing an artificial pavement surface according to claim 14, wherein the pavement layer includes an asphalt pavement surface. The manufacturing method of the artificial pavement surface of Claim 14 which improves global warming of which the condensation tube is replaced with the water storage and drainage reservoir. The manufacturing method of the artificial pavement surface of Claim 14 which improves global warming of which the drain hole accommodates the condensation pipe which can drain and store air, and the storage pipe which can drain and store water. 15. The condensation tube of claim 14, wherein each condensation tube capable of drainage and air storage comprises an inner tube and an outer tube, the inner tube being a hollow tube with a diameter expanding columnar flange formed at the top, and the outer tube having a hole formed at the top. And the outer tube has an inner wall defining an inner inclined surface, and the outer tube has an outer wall forming a protruding structure. The water reservoir according to claim 17, wherein each of the reservoir pipes capable of drainage and water storage includes a drain pipe to which the reservoir is attached, the reservoir includes a top cover and a base box, and the top cover has a hole formed in the top portion, and the top cover. Has an outer circumference in which a rim is formed, the upper cover having an outer diameter greater than the outer diameter of the base box, the base box comprising a central tube and a circumferential gap, and the upper cover and the base box, if combined, between The manufacturing method of the artificial pavement which helps the improvement of global warming to form a waterway passage. 18. The drainage pipe of claim 17, wherein each of the reservoir pipes capable of drainage and storage includes a drainage pipe and a base box attached thereto, the drainage pipe having a top portion having an outer diameter greater than the outer diameter of the base box and having a rim formed along the outer circumference thereof. And wherein the base box includes a central tube and a circumferential gap, and the water polo passage is formed between the upper end of the base box and the drain pipe. The manufacturing method of the artificial pavement surface of Claim 14 which improves global warming of which an interface layer is installed on an ecological gradient layer and under a permeable pavement layer. The method of claim 14, wherein the drainage layer is provided above the ecological gradient layer and below the permeable pavement layer. The method for producing an artificial pavement surface according to claim 22, wherein the drainage layer is provided on the interface layer.

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