KR102469214B1 - A eco-friendly artificial soil and its spraying method - Google Patents

Abstract

The present invention relates to eco-friendly green soil and a greening method using the same. More specifically, the present invention relates to green soil composed of only eco-friendly ingredients free from harmful substances and having excellent moisturizing and adhesive power, and a construction method using the same. The green soil of the present invention is produced with only eco-friendly ingredients, and thus does not contaminate a soil cut surface or surrounding soil. The present invention has excellent moisturizing power and contains a large amount of nutrients, giving good conditions for germination and growth of seeds. Due to the excellent adhesion, even if the soil cut surface is made of rock, plants easily adhere to and grow in the bedrock after construction, reducing the risk of collapse. In addition, the green soil of the present invention does not use earth powder such as decomposed granite soil, loess, living soil, and aggregate, so it is possible to prevent failure of a sprayer or compressor or blockage of a spray pipe. The green soil is finely pulverized to a diameter of 2 mm or less, so that the particles are small and it is easy to disperse and spread evenly on the soil slope. The filling rate for filling cracks, gaps or voids in the soil cut surface is improved, so that green soil can be filled without omission on the irregular curved surface of the soil cut surface. In addition, the present invention provides a construction method of green soil having excellent moisturizing power and adhesion by adjusting the thickness of green soil, the mixing ratio of green soil and water, the mixing ratio of green soil and soil stabilizer, and the amount of seeds spread according to the slope of the soil incision, growth conditions, incision conditions such as drainage facilities, and geology such as soil and rock quality.

Description

Eco-friendly green soil and its spraying method {A eco-friendly artificial soil and its spraying method}

The present invention relates to eco-friendly green soil and a greening method using the same, and more particularly, to green green soil composed only of environmentally friendly ingredients free of harmful substances and having excellent moisturizing and adhesive strength, and a construction method using the same.

In general, soil incisions in civil engineering areas such as road construction and housing development are made of rock layers such as hard rock, soft rock, and weathered rock, or soil that is difficult for plant growth.

Most of these soil incisions cannot be restored to their original state, and if they are left on a slope, there is a risk of soil or bedrock loss and ground collapse in the event of rain or typhoon.

Therefore, civil structures using concrete retaining walls or concrete blocks were mainly constructed on the soil cut surface, which can solve the problem of soil loss on the cut surface, but has a problem that the concrete structure does not match the surrounding natural environment in appearance.

For this reason, greening construction methods that artificially create an environment in which plants can grow on the incised surface of the soil have been attempted recently as an eco-friendly method. By spraying the soil on the soil incision, artificial conditions are created for plants to grow naturally.

Conventional green soil is generally prepared by mixing compost, sewage sludge, earth powder, slaked lime, etc., and then mixed with seeds and then sprayed on a slope by a spray construction method.

The green soil used at this time is manufactured so that it has good moisture retention and contains a large amount of nutrients, gives good conditions for germination and growth of plants, and gives adhesion so that even if the soil cut surface is made of rock, plants easily adhere to and grow in the bedrock after construction. catalog should be created.

However, since the conventional green soil is manufactured using papermaking sludge or sewage sludge containing heavy metals or harmful substances in order to reduce costs, there is a very high risk of contaminating the soil section where the green soil is sprayed or the soil around it.

In addition, conventional green soils account for a large proportion of earth powder such as silt, loess, living soil, and aggregate. Earth powder is generally large in hardness and particles, so it is difficult to prevent the failure of sprayers or compressors that spray green soil on cut surfaces of soil, shortening the life of equipment, etc. and clogging of the injection pipe.

Republic of Korea Patent Registration No. 10-1205575 Republic of Korea Patent Publication No. 10-2018-0075828

In order to solve the above problems, a technical task of the present invention is to provide eco-friendly green soil having excellent moisturizing power and adhesion without using papermaking sludge or sewage sludge containing heavy metals or harmful substances.

In addition, a technical problem of the present invention is to provide a method for constructing green soil by spraying the green soil in consideration of the geology or slope of the soil cut surface.

Green soil of the present invention according to an embodiment,

As a green soil containing sawdust, papermaking fiber, and compost,

10 to 30 parts by weight of sawdust, 10 to 30 parts by weight of papermaking fiber, and 40 to 70 parts by weight of compost based on 100 parts by weight of the green soil composition,

Sawdust, paper fiber, and compost are pulverized to a particle diameter of 2 mm or less before producing green soil,

The compost is characterized in that it is subjected to high heat treatment at 80 degrees Celsius in advance before preparing green soil.

In addition, the papermaking fiber of the present invention is prepared by mixing 100% of bleached chemical pulp and uncoated white paper or bleached chemical pulp with 50% or more of mechanical pulp, and using at least one of first-class heavy paper that is not coated It is characterized by

In addition, a soil stabilizer and a growth regulator are added to the green soil of the present invention,

As the soil stabilizer, one of polyacrylamide, polyvinyl alcohol, gum arabic, methylcellulose, carboxymethylcellulose, polyacrylic acid, styrene-butadiene copolymer latex or acrylic acid latex is used,

The content of the soil stabilizer is 5 to 20 parts by weight based on 100 parts by weight of the green soil composition,

The content of the soil stabilizer is changed according to the slope of the cut surface, the geology, and the thickness of green soil.

The growth regulator is at least one selected from the group consisting of cytokinin, NH4NO3, KH2PO4, H3BO3 and MnSO4,

Its content is characterized in that it is 0.5 to 3 parts by weight based on the total 100 parts by weight of the green soil composition.

In addition, the green soil of the present invention is prepared so that the soil hardness is in the range of 18 to 22 mm by adding microorganisms useful for soil aggregation,

Microorganisms useful for soil aggregation include the genus STREPTOMYCES, the genus Pseudomonas, the genus Bacillus, the genus PENICILIUM-OXALICOM, the genus FUSARIUM MONILIFORME , At least one of the genus ASPERGILLUS NIGAR is used,

It is characterized in that the microbial mass made of the above microorganisms is added in the range of 0.5 to 3 parts by weight based on the total 100 parts by weight of the green soil composition.

The incision surface construction method using the green soil of the present invention,

Green soil including sawdust, paper fiber, and compost is used,

The green soil includes 10 to 30 parts by weight of sawdust, 10 to 30 parts by weight of papermaking fiber, and 40 to 70 parts by weight of compost based on 100 parts by weight of the green soil composition,

Sawdust, paper fiber, and compost are pulverized to a particle diameter of 2 mm or less before producing green soil,

The compost is preliminarily heat-treated at 80 degrees Celsius before green soil production,

(I) surveying soil quality, rock quality, and slope conditions, and adjusting one or more of the thickness of green soil, the mixing ratio of green soil and water, the mixing ratio of green soil and soil stabilizer, and the amount of seed application according to the results of the investigation;

(II) an incision surface preparation step of evenly arranging the surface of the incision surface (S) to remove foreign substances that hinder the attachment of green soil;

(III) a greening foundation construction step of fixing and installing a green soil attachment network (N) made of nylon fiber or wire mesh with a fixing pin (P);

(IV) a spraying greening construction step of spraying rust green soil onto the green soil attachment network N to cover the cut surface with a certain thickness;

In the greening foundation construction stage of the present invention,

If the inclination of the cut surface (S) is more than 60 degrees or the surface of the cut surface (S) is a soft lipid that is easy to flow, the green soil loss prevention net installation step in which the green soil loss prevention net 100 is installed on the cut surface (S) It is a feature that is added.

In the spraying greening construction step of the present invention, green soil is sprayed according to the investigation result of the incision surface investigation step,

When the incision surface (S) is normal soil, the slope is 1:1.4 or less and the soil hardness is 24 mm or less, green soil is sprayed at a thickness of 20 mm, and the slope is in the range of 1:1.5 to 1:1.9 and the soil hardness is 24 mm or less. Spray with a thickness of 10 mm, and if the slope is 1:2.0 or more and the soil hardness is 24 mm or less, green soil is sprayed with a thickness of 20 mm,

When the incision surface (S) is strong masa or clay soil, the slope is 1:1.4 or less and the soil hardness is 25 to 28 mm, green soil is sprayed at a thickness of 20 mm, and the slope is 1:1.5 or more and the soil hardness is 25 to 28 mm. Spray at a thickness of 30 mm,

When the cutting surface (S) is a leafing rock having a soil hardness of 29 mm or more, green soil is sprayed to a thickness of 30 mm,

When the incision surface (S) is weathered rock, if the slope is 1:0.9 or less and the curvature deviation is less than 10 cm, green soil is sprayed to a thickness of 40 mm, and if the slope is 1:1.0 or more and the curvature deviation is 10 cm or more, green soil is sprayed to a thickness of 30 mm, ,

When the incision surface (S) is soft rock, the crack interval is 10 to 30 cm, the slope is 1:0.6 to 1:0.5, and the curvature deviation is less than 10 cm, green soil is sprayed to a thickness of 70 mm, the crack interval is 10 to 30 cm, and the slope is 1 : If it is more than 0.7 and the bending deviation is more than 10 cm, green soil is sprayed in a thickness of 50 mm, and if the crack interval is more than 30 cm and the slope is less than 1:0.5, green soil is sprayed in a thickness of 70 mm,

When the incision surface S is hard rock, green soil is sprayed with a thickness of 120 mm if the slope is 1:0.4 or less, and green soil is sprayed with a thickness of 100 mm if the slope is 1:0.5 or more.

As the greening soil loss prevention network 100 installed on the cut surface (S) in the installation step of the greening soil loss prevention network of the present invention,

The green soil loss prevention network 100 is composed of a top plate 110, a side plate 120 and an inclined plate 130 so that a space is formed therein,

The upper plate 110 is configured in a mesh shape so that green soil on the upper part of the cut surface flows into the inner space,

The inclined plate 130 is fixed by fixing pins or anchor bolts so as to come into close contact with the cut surface.

The side plate 120 is perpendicular to the horizontal plane and is installed to prevent outflow of green soil introduced into the interior space,

It is characterized in that the elastic plate 121 is formed in plurality by being cut in a “c” shape in which the remaining edges of the side plate 120 except for the top plate 110 side are cut.

The elastic force of the elastic plate 121 of the present invention is characterized in that the elastic plate is set to rotate when the weight of the green soil introduced into the inner space of the green soil loss prevention net 100 exceeds a certain value.

The green soil of the present invention is manufactured only with eco-friendly ingredients, does not contaminate the soil incision surface or the surrounding soil, has excellent moisture retention and contains a large amount of nutrients, provides good germination and growth conditions for seeds, and has excellent adhesion, so that the soil incision surface is bedrock. Even if it is made of, it reduces the risk of accidents such as collapse by easily growing plants in the bedrock after construction.

In addition, since the green soil of the present invention does not use earth powder such as eroded soil, loess, shoveling soil, or aggregate, it is possible to prevent failure of the injector or compressor or clogging of the spray pipe, and since the green soil is finely pulverized to a diameter of 2 mm or less, the particles are small. It is easy to disperse and spread evenly on the soil slope, and the filling rate for filling cracks, gaps or voids of the soil incision surface is improved, so that green soil can be filled without omission on the irregular curved surface of the soil incision surface.

In addition, the present invention adjusts the thickness of green soil, the mixing ratio of green soil and water, the mixing ratio of green soil and soil stabilizer, the amount of seed spraying, etc. Provided is a method of constructing green soil having excellent moisture retention and adhesion.

1 is a view showing that green soil of the present invention is applied to a cut surface.
2 is a view showing the configuration and operating state of the green soil loss prevention net 100 of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. It should be understood that the present invention can be modified in various ways and can have various forms, and includes all modifications, equivalents or substitutes included in the spirit and scope of the present invention.

Green soil according to an embodiment of the present invention does not use papermaking sludge or sewage sludge containing heavy metals or harmful substances, and does not contain earth powder such as masato, loess, activated soil, and aggregate.

The green soil of the present invention includes sawdust, papermaking fiber, and fermented compost, and the composition ratio of each component is 10 to 30 parts by weight of sawdust, 10 to 30 parts by weight of papermaking fiber, and 40 to 70 parts by weight of organic compost based on 100 parts by weight of the green soil composition. Contains parts by weight.

In addition, the green soil of the present invention may further include a growth regulator and a soil stabilizer.

It is preferable to use fermented compost as the organic compost included in the green soil composition according to the present invention. It is possible to use one prepared by mixing the mixed nitrogenous materials, adding a leavening agent and an extender, and fermenting them.

More specifically, the fermented compost is a mixture of a carbonaceous material mixed with rice straw, barley straw, weeds, rice husk and wood chips and a nitrogenous material mixed with chicken manure, pork manure, phosphorus manure and cow manure, and its moisture is 60 to 70% on average adjust to Next, it can be prepared by adding a leavening agent and an extender thereto, covering it with vinyl and fermenting it.

Of course, the fermented compost in the present invention is not limited to the above-mentioned ones, and mass-produced and commercially available ones can be used.

Fermented compost is used in the green soil composition according to the present invention, so that the essential nutrients and minerals contained in it have a synergistic effect, enabling rapid initial greening after construction and improving the plant habitat environment, so that native herbs, wildflowers, shrubs, and trees By providing conditions for germination and growth, various vegetation zones can be formed.

The amount of compost used in the present invention is preferably 40 to 70 parts by weight based on the total 100 parts by weight of the green soil composition. In this case, excessive nutrients may interfere with seed germination or growth, and also reduce the adhesion of green soil.

The fermented compost used in the present invention is preliminarily subjected to high heat treatment at 80 degrees Celsius before preparing green soil to remove various microorganisms, weed seeds, and other fungi that may exist in the fermented compost.

In addition, the fermented compost used in the present invention is pulverized by a pulverizer to have a particle size of 2 mm or less before manufacturing green soil, and the particle size is uniformly processed, thereby improving mixing with other compositions during green soil production and spraying device when green soil is sprayed. It prevents clogging of the soil and has the effect of spreading evenly on the soil slope.

Sawdust used in the green soil composition according to the present invention has strong moisturizing power and has a warming effect, plays a role in preventing loss of soil and seeds, and enables rapid greening by promoting fermentation of organic matter in compost. let it The amount of sawdust used in the present invention is preferably 10 to 30 parts by weight based on 100 parts by weight of the green soil composition. If it is less than 10 parts by weight, the fermentation of organic matter contained in the compost cannot be promoted, and if it exceeds 30 parts by weight, the adhesion of green soil may be reduced.

The sawdust according to the present invention is previously subjected to high heat treatment at 80 degrees Celsius before preparing green soil, and is pulverized by a grinder to have a particle size of 2 mm or less, so that the particle size is uniformly processed.

This has the effect of removing various fungi and microorganisms from sawdust, improving the mixability with other compositions when green soil is produced, preventing clogging of the spraying device when green soil is sprayed, and evenly spraying on the soil slope.

In addition, the paper-making fiber used in the present invention is white paper made of 100% bleached chemical pulp and not coated, or one or more of first grade heavy paper made by mixing mechanical pulp with 50% or more of bleached chemical pulp and not coated. White paper or grade 1 medium paper has more than twice the difference in moisture retention effect compared to general paper for recycling.

General recycled paper has a small pulp content and pulp fibers are cut short and hardened, so even if water is supplied, the moisture content or moisturizing power is significantly reduced. It is also long, so when it is supplied with water, it has excellent water-holding ability and moisturizing power.

The papermaking fiber used in the present invention promotes soil agglomeration, entanglement, and soil void bonding. The content thereof is preferably 10 to 30 parts by weight based on 100 parts by weight of the green soil composition. When used in less than 10 parts by weight, the grain structure of the soil and the bonding and entanglement between natural fibers are insignificant, so when spraying and attaching to rock wool, soil solidification is not achieved, and water retention or moisture retention is lowered, so the rate of seed germination or growth defects after germination is reduced. It may increase, and if it exceeds 30 parts by weight, the adhesive strength decreases, causing green soil or seeds to fall off from the cut surface.

The paper-making fiber according to the present invention is pulverized to a particle size of 2 mm or less by a grinder prior to preparation of green soil, so that the particle size becomes uniform, so that mixing with other compositions during green soil production is improved, and when green soil is sprayed, the use of a spreading device or a spraying device It prevents clogging and has the effect of evenly spreading on the soil slope.

When 1 to 3 parts by weight of acetylated cellulose ether is used together with the paper-making fiber, the hydrophilicity of green soil is increased and the fouling resistance is reduced. The acetylated cellulose ether is required in an amount of 1 part by weight or more for fouling resistance, and is preferably 3 parts by weight or less in order to prevent excessive moisture adsorption.

In the present invention, the soil hardness of green soil is managed to be around 20 mm suitable for seed germination or growth, that is, in the range of 18 to 22 mm. If the soil hardness is less than 18mm, there is a problem that the green soil flows down from the inclined incision, and if it is more than 22mm, there is a problem that the growth of plants is hindered.

Soil hardness is caused by the cohesive force between soil grains and the frictional force between particles, and is a phenomenon that appears as a result of a combination of particle size composition, void volume, bulk weight (filling density), and soil moisture. Soils with high hardness generally have a high solids fraction and a low porosity (weather fraction). Soil hardness can be controlled through soil agglomeration, and the hardness of the agglomerated soil decreases as the solidity rate decreases and the porosity (weather rate) increases. Soil aggregation is accomplished by microbial activity, and as organic matter in the soil is eroded by mineralization, it greatly helps soil aggregation. Among microorganisms, fungi are much more effective than bacteria because the role of hyphae greatly affects the formation of aggregates.

Microorganisms useful for soil aggregation include the genus STREPTOMYCES, the genus Pseudomonas, the genus Bacillus, the genus PENICILIUM-OXALICOM, the genus FUSARIUM MONILIFORME , At least one of the genus ASPERGILLUS NIGAR is used, and the microorganism is placed in an incubator and cultured at an internal temperature of 18 to 30 ° C for 10 to 30 days to make spawn. By inoculating these microorganisms together on a carrier, a microbial mass that serves to promote organic matter decomposition and soil aggregation is prepared.

The prepared microbial mass is added in the range of 0.5 to 3 parts by weight based on 100 parts by weight of the green soil composition. If it is less than 0.5 parts by weight, the soil aggregation effect is insignificant and green soil hardness may increase, and if it exceeds 3 parts by weight, the soil aggregation effect is excessive and green soil hardness is lowered and is not economical.

The growth regulator used in the present invention contains various inorganic substances so that vegetation can be stably adhered to at an early stage. The growth regulator is at least one selected from the group consisting of cytokinin, NH4NO3, KH2PO4, H3BO3 and MnSO4.

Its content is preferably 0.5 to 3 parts by weight based on 100 parts by weight of the green soil composition. If it is less than 0.5 parts by weight, the supply of inorganic nutrients to vegetation is insignificant, and if it exceeds 3 parts by weight, it is not economical.

Alternatively, the microorganism useful for soil aggregation of the present invention may be used as a growth regulator together with or separately from the inorganic growth regulator, and by adsorbing the microorganism to a porous mineral, the antiviral effect is further improved along with the various functions of the mineral. do.

For example, porous minerals such as bentonite, vermiculite, and zeolite are preferable in that they function to increase the content of air to suppress fermentation of pathogens in the soil and increase oxygen supply to plants. The porous mineral may be used in an amount of 1 to 3 parts by weight, and ceramics, clay, and the like may be used as the porous mineral.

In addition, in the present invention, a soil stabilizer is added to green soil to promote soil stabilization by preventing loss and scattering of green soil. The soil stabilizer improves the above-described natural fiber and entanglement and soil pore bonding, further increasing the adhesion of green soil or the bonding strength with soil.

Preferred soil stabilizers include polyacrylamide, polyvinyl alcohol, gum arabic, methylcellulose, carboxymethylcellulose, polyacrylic acid, styrene-butadiene copolymer latex or acrylic acid latex. The content of the soil stabilizer is changed according to the slope of the soil incision, soil quality, green soil thickness, etc.

The content of the soil stabilizer is preferably 5 to 20 parts by weight based on 100 parts by weight of the green soil composition. If the content is less than 5 parts by weight, there is a problem that the green soil is eliminated, and if it exceeds 20 parts by weight, the green soil is hardened, resulting in defects in seed germination or growth.

In addition, the content of the soil stabilizer increases as the soil incision surface is rocky ground or the slope is larger (more than 45 degrees), and the content of the soil stabilizer decreases as the soil incision surface is soil ground or the slope is smaller (less than 45 degrees).

The green soil of the present invention prepared as described above is manufactured only with eco-friendly ingredients, does not contaminate the soil cut surface or the surrounding soil, has excellent moisturizing power and contains a large amount of nutrients, provides good conditions for germination and growth of seeds, and has excellent adhesion to the soil Even if the cut surface is made of rock, the risk of accidents such as collapse is reduced as plants easily adhere to and grow in the bedrock after construction.

In addition, since the green soil of the present invention does not use earth powder such as eroded soil, loess, shoveling soil, or aggregate, it is possible to prevent failure of the injector or compressor or clogging of the spray pipe, and since the green soil is finely pulverized to a diameter of 2 mm or less, the particles are small. It is easy to disperse and spread evenly on the soil slope, and the filling rate for filling cracks, gaps or voids of the soil incision surface is improved, so that the irregular curved surface of the soil incision surface can be filled with green soil.

Next, the construction method of the green soil of the present invention, which is sprayed on the soil cut surface, will be described.

The construction method of green soil consists of ① cut surface inspection step, ② cut surface cleanup step, ③ greening foundation construction step, and ④ spraying greening construction step in this order.

First, in the incision investigation step, the slope of the soil incision, the state of the incision, such as growth conditions, drainage facilities, and geology such as soil and rock quality are investigated. Soil quality such as weathering state is investigated, and when the soil incision surface is rocky ground, rock quality such as crack, bend, joint direction, and weathering state of the incision surface is investigated.

Through the incision investigation step, the thickness of green soil, the mixing ratio of green soil and water, the mixing ratio of green soil and soil stabilizer, and the amount of seeds spread are adjusted according to the soil quality, rock quality, and slope condition.

Next, in the step of arranging the incision surface, foreign substances obstructing the attachment of green soil, such as obstacles on the incision surface, falling rocks, unstable bedrock or soil, etc. are removed, and the surface of the incision surface is evenly arranged.

Next, in the greening foundation construction stage, the green soil attachment network (rhombus network) is fixed and installed on the slope cut surface with anchor pins, landing pins, and steel wires. Wire mesh, coir net, plastic net, natural fiber net, etc. are used for the green soil attachment network (rhombus network), and the green soil attachment network (rhombus network) is installed so that it adheres to the cut surface as much as possible. It is possible not to install a green soil attachment network (rhombus network).

Next, in the spraying and greening construction step, the green soil according to the present invention is sprayed and sprayed on the soil cut surface.

Since it is difficult for seeds to green the incision to germinate if they are deeply buried, if the average thickness of the green soil sprayed on the incision is 10 mm or more, the green soil is divided into a base layer without seeds and a seed layer mixed with seeds. The thickness of the seed layer is within 10 mm, and if the average thickness of green soil is within 10 mm, only the seed layer is sprayed without distinction between the base layer and the seed layer.

The green soil may be sprayed by a dry method or a wet method depending on the soil or rock quality of the soil incision or the state of the incision.

First, the dry method is a method of transporting materials to the upper slope by the air pressure of a large compressor. The advantage is that it can form an artificial soil layer with a maximum thickness of 15 cm on a rock layer or a rough and steep slope where it is very difficult for green plants to germinate and grow. It is a construction method that can construct green soil regardless of the vegetation conditions of artificial slopes.

However, the dry method requires a large compressor (air pressure of 10 kg/cm2, discharge volume of 800 cfm or more), a generator of 60 hp (45 kw) or more, equipment for transporting and attaching green soil, and a 5-ton crane or small fork crane for supplying green soil materials, and a large compressor is used. In terms of construction, costs such as oil consumption cost, equipment transportation cost, equipment usage fee, etc. are high, and green soil installation speed is slower than wet green soil construction based on the same green soil construction thickness.

The wet method is a method in which water and green soil are mixed in a tank, made into a gel state, and then transferred to the upper slope with a high-pressure sludge pump for high concentration. It is a construction method suitable for the following conditions.

The wet method uses a spreader (tank capacity of 2500 liters or more, sludge pump capacity of 50 horsepower or more) and a 5-ton crane or grade 06 or higher fork crane for supplying green soil materials, so the cost of oil consumption is small and the cost of equipment transportation and equipment usage is low. It takes relatively less time and has the advantage of faster construction speed than dry method when considering the same green soil construction thickness.

However, the wet method can be applied only to incisions where the germination and growth conditions of green plants are relatively good and the inclination is 70 degrees or less, and the maximum thickness of green soil can be installed only up to 5cm or less, so the geological condition or vegetation conditions of the inclined incision It is a construction method that is greatly influenced by

In the case of wet method, green soil is sprayed so that the thickness is less than 10 mm per time, and in case of multiple spraying, the spraying time interval is at least 30 minutes so that green soil is smoothly adhered to the cut surface. In case of dry method, each time Spray to a thickness of up to 50 mm, and in case of spraying several times, set the spraying time interval to at least 60 minutes so that green soil adheres smoothly to the cut surface.

During the wet method, the mixing ratio of green soil and water is mixed in the range of 1:0.5 to 1:1.5. Below) the mixing ratio of green soil and water is large, and the viscosity of green soil is small.

In addition, the more the cutting surface is bedrock or the soil hardness (more than 24mm), the higher the viscosity of green soil by reducing the mixing ratio of green soil and water to prevent loss of green soil, and the smaller the interval between rock cracks or the smaller the soil hardness of soil. The more (less than 24mm), the higher the mixing ratio of green soil and water, so the viscosity of green soil is low.

When the gap between cracks in the bedrock is small (less than 3 cm) or when the hardness of the soil is small, the viscosity of the green soil is small, so it can easily permeate into cracks in the bedrock or the soil, preventing the formation of voids in the green soil.

In addition, when the cut surface is rock, only green soil can be sprayed and sprayed in a dry way without mixing water according to the state of the rock or the slope.

In the spray greening construction step, the thickness of the green soil is sprayed thinly because the thickness of the green soil is greater than that of the bedrock ground when the cut surface is the soil ground. For example, if the cut surface is soil, it is sprayed with a thickness of 5 to 30 mm, and if it is rocky ground, it is sprayed with a thickness of 30 to 150 mm (changes according to soil quality, rock quality, slope, crack condition, weathering condition, acidity, hardness, etc.).

In addition, the thickness of green soil is sprayed thinly to prevent loss due to the weight of green soil when the incision surface is steep, and thickly if the incision surface is gentle. For example, if the inclination of the incision is 1:1, that is, 45 degrees or less, it is sprayed in a thickness of 20 to 150 mm (changed according to soil quality, rock quality, crack condition, weathering condition, acidity, hardness, etc.), 1: 1 or more, That is, if the temperature is higher than 45 degrees, it is sprayed in a thickness of 5 to 100 mm (changed according to soil quality, rock quality, crack condition, weathering condition, acidity, hardness, etc.).

In this way, the thickness of the most economical green soil (within ± 10% of the average thickness) is determined to facilitate the engraftment and growth of crops according to the soil quality, rock quality, and state of the incision surface, and can be summarized as shown in Table 1 below. .

Table 1. Thickness standard of economical green soil (within ±10% average thickness)

lipids soil hardness
(mm) slope green soil
Thickness (mm) lipids crack spacing
(cm) slope deflection deviation
average (cm) green soil
Thickness (mm) normal soil 24 or less 1:2.0 or higher 5 weathered rock 1 to 10 1:1.0 or higher over 10 30 1:1.9 to 1:1.5 10 1:0.9 or less less than 10 40 1:1.4 or less 20 Yeonam 10 to 30 1:0.7 or higher over 10 50 River Ma Sa/
clayey soil 25-28 1:1.5 or greater 1:0.6 to 1:0.5 less than 10 70 1:1.4 or less 30 30 or more Less than 1:0.5 - Lee Ping Arm
(A weathered rock that can be ripped) 29 or more 1:1.0 or higher hard rock 1:0.5 or higher - 100 1:0.9 or less 1:0.4 or less - 120

In Table 1, the thickness of the green soil is managed within ± 10% of the average thickness of the green soil, and the soil hardness is measured using a conventional mountain-type soil hardness tester or an intrusive soil hardness tester, and the crack interval indicates the weathering state of the bedrock. It is a numerical value, and the bending deviation is the average value of the bending state of the rock surface.

The green soil thickness in Table 1 can be changed in the range of 10 to 30% depending on the slope of the cut surface, soil quality, rock quality, crack condition, weathering condition, acidity, hardness, growth conditions of the cut surface, etc.

For example, when the incision surface is soil, the soil acidity (PH) is increased by 10 to 30% more than the green soil thickness in Table 1 when the soil acidity (PH) is strong alkali (PH 8 or more) or strong acid (PH 4.5 or less).

In addition, in places where the growing conditions are bad, such as north-facing with a lot of shade or terrain with strong winds, the thickness of green soil in Table 1 is increased by 10 to 30%.

If the weathering of the ground surface is severe and the soil flows down severely, or if erosion and loss prevention is the top priority due to severe erosion scour, the construction thickness should be set to 3CM or more. In addition, when planning restoration by long-term growth due to very poor soil conditions (soil acidity, nutrients, etc.), the thickness should be increased by 1CM or more from the thickness standard in Table 1.

1 is an exemplary diagram illustrating a process of restoring a cut surface using green soil according to the present invention.

The incision surface construction method using green soil according to the present invention,

(I) Incision surface investigation step of examining soil quality, rock quality, and slope conditions, and adjusting the thickness of green soil, the mixing ratio of green soil and water, the mixing ratio of green soil and soil stabilizer, and the amount of seeds spread, etc. according to the results of the investigation ;

(II) an incision surface preparation step of evenly arranging the surface of the incision surface (S) to remove foreign substances that hinder the attachment of green soil;

(III) a greening foundation construction step of fixing and installing a green soil attachment network (N) made of nylon fiber or wire mesh with a fixing pin (P);

(IV) a spraying and greening construction step of spraying the green soil according to the present invention onto the green soil attachment network (N) to cover the soil cut surface with a certain thickness;

In the greening foundation construction stage, if the inclination of the cutting surface (S) is more than 60 degrees or the surface of the cutting surface (S) is a soft geological surface that is easy to flow down (weathering or brittle masato, leafing rock, severe weathering and erosion) geology such as weathered rock), and a green soil loss prevention network installation step in which the green soil loss prevention network 100 is installed on the cut surface S as shown in FIG. 2 may be added.

The green soil loss prevention network 100 of FIG. 2 (a) is composed of a top plate 110, a side plate 120, and an inclined plate 130 so that a space is formed therein, and the top plate 110, the side plate 120, and the inclined plate ( 130) may be coupled through a separate frame, or the top plate 110, the side plate 120, and the inclined plate 130 may be directly coupled to each other.

The upper plate 110 is configured in a mesh shape so that the green soil on the upper part of the cut surface flows into the inner space, the inclined plate 13 is fixed with fixing pins or anchor bolts so as to be in close contact with the surface of the cut surface, and the side plate 120 is connected to the horizontal plane. It is installed to be in a vertical state and to prevent the outflow of green soil that has flowed into the interior space.

In addition, the elastic plate 121 is formed on the side plate 120 as shown in FIG. 2 (b), and the remaining edges of the side plate 120 except for the top plate 110 side are cut in a “c” shape to cut the elastic plate ( 121) is formed.

In the side plate 120, the elastic plate 121 is formed of a material having elasticity, metal or synthetic resin may be used, and a plurality of elastic plates 121 may be formed in the side plate 120.

The elastic force of the elastic plate 121 is set so that the elastic plate can rotate as shown in FIG. For example, the elastic force of the elastic plate 121 is set such that the elastic plate 121 rotates when green soil is accumulated to 2/3 or more of the height of the side plate.

In the step of installing the green soil loss prevention net, a plurality of green soil loss prevention nets 100 may be installed according to the height of the incision surface, and the speed or amount of loss of the green soil above the incision surface to the lower part may be reduced or the loss may be prevented.

In addition, a plurality of green soil loss prevention nets 100 are installed according to the height of the incision, and the inner space of the green soil loss prevention net 100 installed at the lower part of the incision is the inner space of the green soil loss prevention net 100 installed at the upper part of the incision. It is formed to be larger, or the inner space of the green soil loss prevention net 100 increases from the top to the bottom of the cut surface.

With this configuration, green soil lost from the upper part of the cut surface flows down to the lower part of the cut surface and is distributed and stored in several green soil loss prevention nets 100, and a large amount of green soil can be stored in the green soil loss prevention net 100 at the lower part of the cut surface. It can effectively store lost green soil that increases over time.

First, the green soil loss prevention net 100 is fixed to the surface of the cut surface by fixing pins (P) or anchor bolts as a green soil attachment network (N) or separately.

Next, with the green soil loss prevention net 100 attached to the cut surface S, the green soil is sprayed through the spraying and greening construction step.

After a certain period of time has elapsed, when the green soil at the top of the incision surface flows down due to the unstable surface of the incision surface, the weight of green soil, or rainfall, the green soil flows into the inner space of the green soil loss prevention net 100 as shown in FIG. 2(c).

When the green soil in the inner space of the green soil loss prevention net 100 is introduced enough to overcome the elastic force of the elastic plate 121, the elastic plate 121 rotates due to the weight of the green soil, so that the green soil flows out.

Since the rotation angle of the elastic plate 121 is adjusted in proportion to the weight of the green soil, the green soil flowing out of the green soil loss prevention net 100 is not lost all at once, thereby reducing the loss speed and amount.

The green soil loss prevention net 100 of the present invention can reduce the speed or amount of loss of green soil at the upper part of the incision surface to the lower part, and the elastic plate 121 is the side plate material itself without a separate mechanical device such as a spring. Since it rotates by the elasticity of, there is an advantage that maintenance or repair is unnecessary.

In the spraying and greening construction step, the thickness of the green soil is adjusted according to the quality of soil, rock quality, state of the cut surface, and the like.

For example, when the incision surface (S) is normal soil, the slope is 1:1.4 or less and the soil hardness is 24 mm or less, green soil is sprayed at a thickness of 20 mm, the slope is in the range of 1:1.5 to 1:1.9, and the soil hardness is 24 mm or less. If the slope is more than 1:2.0 and the soil hardness is 24mm or less, green soil is sprayed with a thickness of 20mm.

In addition, when the incision surface (S) is strong masa or clay soil, the slope is 1: 1.4 or less and the soil hardness is 25 to 28 mm, green soil is sprayed at a thickness of 20 mm, and the slope is 1: 1.5 or more and the soil hardness is 25 to 28 mm Green soil is sprayed at a thickness of 30 mm.

In addition, when the cutting surface (S) is a leafing rock having a soil hardness of 29 mm or more, green soil is sprayed to a thickness of 30 mm.

In addition, when the incision surface S is weathered rock, if the slope is 1:0.9 or less and the curvature deviation is less than 10 cm, green soil is sprayed to a thickness of 40 mm, and if the slope is 1:1.0 or more and the curvature deviation is 10 cm or more, green soil is sprayed to a thickness of 30 mm. spray

In addition, when the incision surface (S) is soft rock, the crack interval is 10 to 30 cm, the slope is 1:0.6 to 1:0.5, and the curvature deviation is less than 10 cm, green soil is sprayed to a thickness of 70 mm, the crack interval is 10 to 30 cm, If the slope is 1:0.7 or more and the curvature deviation is 10 cm or more, green soil is sprayed with a thickness of 50 mm, and if the crack interval is 30 cm or more and the slope is less than 1:0.5, green soil is sprayed with a thickness of 70 mm.

In addition, when the incision surface S is hard rock, if the slope is 1:0.4 or less, green soil is sprayed to a thickness of 120 mm, and if the slope is 1:0.5 or more, green soil is sprayed to a thickness of 100 mm.

In addition, the green soil thickness can be changed in the range of 10 to 30% depending on the slope of the cut surface, soil quality, rock quality, crack state, weathering state, acidity, hardness, growth conditions of the cut surface, and the like.

For example, when the cut surface is soil, the soil acidity (PH) is increased by 10 to 30% more than the green soil thickness in Table 1 when the soil acidity (PH) is strong alkali (PH 8 or more) or strong acid (PH 4.5 or less).

In addition, in places where the growing conditions are bad, such as north-facing with a lot of shade or terrain with strong winds, the thickness of green soil in Table 1 is increased by 10 to 30%.

Although the present invention has been described in detail through specific examples, this is for explaining the present invention in detail, the present invention is not limited thereto, and within the technical spirit of the present invention, those skilled in the art can It is clear that modifications and improvements can be made.

C: green soil N: green soil attachment network
P: Fixing pin S: Incision
100: Green soil loss prevention network
110: top plate 120: side plate
121: elastic plate 122: incision
130: inclined plate

Claims (10)

delete delete delete delete The cutting surface construction method using green soil,
Green soil including sawdust, paper fiber, and compost is used,
The green soil includes 10 to 30 parts by weight of sawdust, 10 to 30 parts by weight of papermaking fiber, and 40 to 70 parts by weight of compost based on 100 parts by weight of the green soil composition,
Sawdust, paper fiber, and compost are pulverized to a particle diameter of 2 mm or less before producing green soil,
The compost is characterized in that it is subjected to a high heat treatment at 80 degrees Celsius in advance before preparing green soil,
(I) surveying soil quality, rock quality, and slope conditions, and adjusting one or more of the thickness of green soil, the mixing ratio of green soil and water, the mixing ratio of green soil and soil stabilizer, and the amount of seed application according to the results of the investigation;
(II) an incision surface preparation step of evenly arranging the surface of the incision surface (S) to remove foreign substances that hinder the attachment of green soil;
(III) a greening foundation construction step of fixing and installing a green soil attachment network (N) made of nylon fiber or wire mesh with a fixing pin (P);
(IV) a spraying and greening construction step of spraying rust green soil onto the green soil attachment network (N) to cover the cut surface with a certain thickness;
In the greening foundation construction stage,
If the slope of the cut surface (S) is more than 60 degrees or the surface of the cut surface (S) is a soft lipid that is easy to flow, the green soil loss prevention net installation step in which the green soil loss prevention net 100 is installed on the cut surface (S) is added,
The green soil loss prevention network 100 is composed of a top plate 110, a side plate 120 and an inclined plate 130 so that a space is formed therein,
The upper plate 110 is configured in a mesh shape so that green soil on the upper part of the cut surface flows into the inner space,
The inclined plate 130 is fixed by fixing pins or anchor bolts so as to come into close contact with the cut surface.
The side plate 120 is perpendicular to the horizontal plane and is installed to prevent outflow of green soil introduced into the internal space.
The elastic plate 121 is cut in a “c” shape in which the remaining edges of the side plate 120 except for the top plate 110 side are cut to form a plurality of them,
The elastic force of the elastic plate 121 is set so that the elastic plate can rotate when the weight of the green soil introduced into the inner space of the green soil loss prevention net 100 exceeds a certain value. delete delete The method according to claim 5, wherein green soil is sprayed according to the investigation result of the incision surface investigation step in the spraying and greening construction step,
When the incision surface (S) is normal soil, the slope is 1:1.4 or less and the soil hardness is 24 mm or less, green soil is sprayed at a thickness of 20 mm, and the slope is in the range of 1:1.5 to 1:1.9 and the soil hardness is 24 mm or less. Spray with a thickness of 10 mm, and if the slope is 1:2.0 or more and the soil hardness is 24 mm or less, green soil is sprayed with a thickness of 20 mm,
When the incision surface (S) is strong masa or clay soil, the slope is 1:1.4 or less and the soil hardness is 25 to 28 mm, green soil is sprayed at a thickness of 20 mm, and the slope is 1:1.5 or more and the soil hardness is 25 to 28 mm. Spray at a thickness of 30 mm,
When the cutting surface (S) is a leafing rock having a soil hardness of 29 mm or more, green soil is sprayed to a thickness of 30 mm,
When the incision surface (S) is weathered rock, if the slope is 1:0.9 or less and the curvature deviation is less than 10 cm, green soil is sprayed to a thickness of 40 mm, and if the slope is 1:1.0 or more and the curvature deviation is 10 cm or more, green soil is sprayed to a thickness of 30 mm, ,
When the incision surface (S) is soft rock, the crack interval is 10 to 30 cm, the slope is 1:0.6 to 1:0.5, and the curvature deviation is less than 10 cm, green soil is sprayed to a thickness of 70 mm, the crack interval is 10 to 30 cm, and the slope is 1 : If it is more than 0.7 and the bending deviation is more than 10 cm, green soil is sprayed in a thickness of 50 mm, and if the crack interval is more than 30 cm and the slope is less than 1:0.5, green soil is sprayed in a thickness of 70 mm,
When the incision surface (S) is hard rock, green soil is sprayed with a thickness of 120 mm if the slope is 1:0.4 or less, and green soil is sprayed with a thickness of 100 mm if the slope is 1:0.5 or more. As the green soil loss prevention network 100 installed on the cut surface S in the green soil loss prevention network installation step of claim 5,
The green soil loss prevention network 100 is composed of a top plate 110, a side plate 120 and an inclined plate 130 so that a space is formed therein,
The upper plate 110 is configured in a mesh shape so that green soil on the upper part of the cut surface flows into the inner space,
The inclined plate 130 is fixed by fixing pins or anchor bolts so as to come into close contact with the cut surface.
The side plate 120 is perpendicular to the horizontal plane and is installed to prevent outflow of green soil introduced into the internal space.
The elastic plate 121 is cut in a “c” shape in which the remaining edges of the side plate 120 except for the top plate 110 side are cut to form a plurality of them,
The elastic force of the elastic plate 121 is set so that the elastic plate can rotate when the weight of green soil introduced into the inner space of the green soil loss prevention net 100 exceeds a certain value.
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