KR200266823Y1 - Layer structure of waste reclamation land by permeative waterproof agents - Google Patents

Abstract

The present invention relates to an impervious waste landfill containment wall layer structure and its construction method using a permeable waterproof agent. The purpose of the present invention is to develop a new landfill site that can significantly suppress leachate leakage due to its low permeability coefficient as well as its mechanical strength. It is to provide the order wall structure and its installation method.

The structure of the present invention is a waste landfill order wall layer structure formed in the excavation of the subsidiary floor on the ground (1), a high-strength impermeable soil layer formed on the bottom surface of the ground (1) and the sloped surface integrally connected thereto (2) and an impermeable waste landfill with a permeable waterproofing agent, characterized in that it is formed of a siliceous-based permeable reinforcement layer (3) which penetrates and cures to a certain depth from the surface of the solidified soil layer (2) and is densely packed than the structure of the solidified soil layer. The order wall layer structure and its construction method are the subject of devising.

Description

Layer structure of waste reclamation land by permeative waterproof agents}

The present invention relates to an impervious waste landfill containment wall layer structure and a construction method thereof, and more particularly, to a containment wall layer structure of a cage-type garbage landfill, which burrows on the ground and burys the waste in the excavated place. .

Conventionally, when installing landfills, most of them use a method of solidifying with high density polyethylene (HDPE) liner, ie, polyethylene sheet lining, and soil mortar and soil cement, which together with other additives such as clay or bentonite of appropriate thickness on the lower layer thereof. To form the order layer.

However, this method places clays with a very high strength as the lower support layer of the polyethylene liner, which places great restrictions on the topography, soil and natural environment of the landfill site.

In addition, since most of the clay is collected and used in a separate place, there is a risk of damage to the natural environment, and most of new domestic landfill sites are limited by the available space that can be constructed. Because it is located on the back and the soil and soil properties are poor because the support capacity of the lower clay layer is not enough floating settlement occurs.

Therefore, not only the joints between the polyethylene sheets are damaged, but also the sheet itself is damaged by the construction equipment during and after construction, and there are many problems in stability, such as leachate leaking out of landfill waste.

In particular, in the case of caged landfills, the clay located under the polyethylene sheet may slide due to the high water pressure acting on the sloped slope in the inclined slope, and thus clay laying itself is impossible. Bentonite mat, which is a molded article, may be laid, but even in this case, it is difficult to secure the bearing force, which causes the above-described problems.

An object of the present invention for solving the above problems is to provide a new waste landfill wall structure that can significantly suppress the leachate outflow as well as mechanical strength as well as impermeable water permeability coefficient.

Figure 1 is an illustration of the installation of the order wall of the waste landfill according to the present invention.

<Description of the symbols for the main parts of the drawings>

(1): base (2): high strength impermeable soil layer

(3): impervious reinforcement layer

The present invention to achieve the object as described above and to perform the problem for eliminating the conventional defects in the waste landfill liner wall layer structure is formed in the excavated in the normal ground down to the ground (1),

A high-strength impermeable soil layer (2) formed on the bottom surface of the base plate (1) and a sloped surface integrally connected thereto;

It is characterized in that it is formed of a siliceous-based permeability reinforcing layer (3) which penetrates and cures from the surface of the solidified soil layer 2 to 15 to 25 mm and is densely packed than the structure of the solidified soil layer.

The solidified soil layer (2) is mixed with the high-strength siliceous-based permeable waterproofing agent composition in a ratio of 100 to 120 parts with respect to 900 parts of spot soil (clay, masato, loess) by weight ratio, and then thoroughly mixed and stirred for 30 minutes to 60 minutes, and then the optimum water content ratio. It is characterized by a layer that is sufficiently stirred for 30 minutes to 60 minutes after the addition of water corresponding thereto, and then cures and compacts the solidified soil.

The reinforcing layer (3) is characterized by a layer in which the dilute liquid mixed with the siliceous permeable waterproofing agent composition and water in a weight ratio of 102 to 136: 20 to 30 is sprayed onto the surface of the solidified soil layer 2 to penetrate and form.

1㎡ of surface area of hardened soil layer when spraying the reinforcement layer It sprays and sprays in the quantity of 0.6-1.2L per sugar, permeates from the surface of the solidified soil layer 2 to 15-25 mm, and makes it cure.

The high strength siliceous-based permeable waterproofing agent composition includes 70 to 80 parts of portant cement, 5 to 10 parts of SiO ₂ , Al ₂ O ₃ , MgO, _{2 to 3} parts of Al ₂ (SiO ₃ ) _{3, and} Na ₂ O.nSiO _2, respectively. And a mixture composed of 3 to 5 parts of acrylic powder.

The optimum water content ratio of the field soil (masato, loess) and the high-strength siliceous permeable waterproofing agent is 10 to 15%, and the maximum dry density is characterized in that it is formulated to maintain 1.7 to 2.0.

The siliceous-based permeable waterproofing agent composition includes 70 to 80 parts of portant cement, 5 to 10 parts of SiO ₂ , Al ₂ O ₃ , MgO, _{2 to 3} parts of Al ₂ (SiO ₃ ) _3, Na ₂ O · nSiO ₂ , After the composition of the acrylic powder in a ratio of 3 to 5 parts, it is characterized in that it is composed by adding 10 to 15 parts of acrylic emulsion (acrylic emulsion usable for mixed siliceous systems) and water to 20 to 30 parts.

Hereinafter, the configuration and the operation of the embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows an exemplary view of the installation wall of the waste landfill according to the present invention, based on this will be described the method of installing the waste wall of the landfill.

First, the landfill construction ground was destroyed in the form of the Sanggwang Strait, and the solidified soil of a specific compound was laid and compacted at a certain thickness of 40-50 cm on both the bottom surface and the normal surface of the original ground (1). Soil layer) 2.

Next, by spraying or applying a waterproofing liquid having a specific chemical composition from the surface of the solidified soil layer 2 to penetrate to a certain depth, and curing to form an impermeable reinforcing layer (hereinafter reinforcing layer) (3).

At this time, the respective materials and compositions for forming the solidified soil layer 2 and the reinforcement layer 3 are as follows.

The solidified soil layer (2) is mixed by mixing the high-strength siliceous-based permeable waterproofing agent composition in a ratio of 100 to 120 parts with respect to 900 parts of on-site soil (clay, masato, loess, etc.) by weight ratio, and then sufficiently stirred, and then sufficiently stirred again. After laying and solidifying the solidified soil to cure.

The reinforcing layer 3 comprises a diluent obtained by mixing water, a siliceous permeable waterproofing agent composition, and water at a weight ratio of 102 to 136: 20 to 30. The surface area of the solidified soil layer 2 is 1 m 2. It sprays and sprays in the quantity of 0.6-1.2L per sugar, permeates to the predetermined depth from the surface of the solidified soil layer 2, and is cured.

The above-mentioned on-site generated soil refers to soil generated in the excavation work of waste landfill site such as clay, masato and loess, and a certain amount of high-strength siliceous-based permeable waterproofing agent is used for the optimum water content corresponding to the maximum dry density. It is mixed and stirred to form a solidified soil layer.

The optimum water content ratio of Masato, loess and high-strength siliceous permeable waterproofing agent composition of the present invention is 10 to 15%, and the maximum dry density is maintained at 1.7 to 2.0. At this time, the uniaxial compressive strength required for the solidified soil layer is also maximum. It can be seen.

In the hardened soil mixture according to the present invention, a high-strength siliceous permeable waterproofing agent composition is used alone as a solidifying component. The components are described in 70 to 80 parts of portant cement, 5 to 10 SiO ₂ , Al ₂ O ₃ , and MgO, respectively. _{part, Al 2 (SiO 3) 3} , is the composition of a mixture ratio of 3-5 parts of Na ₂ O · nSiO _2, respectively 2 to 3 parts of acrylic powder.

On the other hand, when forming the water barrier wall according to the present invention, a siliceous-based permeable waterproofing liquid is formed by spraying and applying the surface of the solidified soil layer 2 formed first to densely fill voids to form the reinforcing layer 3, the composition of which is inorganic and 70 to 80 parts of portant cement, 5 to 10 parts each of SiO ₂ , Al ₂ O ₃ , MgO, _{2 to 3} parts of Al ₂ (SiO ₃ ) ₃ , Na ₂ O · nSiO ₂ , After composition in the ratio of the acrylic powder 3-5, it adds and uses it in the ratio of 10-15 parts of acrylic emulsion (acrylic emulsion which can be used for a mixed-type siliceous system), and 20-30 parts of water.

Field-produced soil utilized in the order wall and the following solidified components are mixed to form a high-strength impermeable solidified soil layer, and each of the components will be described in detail as follows.

Aluminum oxide (Al ₂ O ₃ ) is the most commonly used inorganic coagulant.

The mechanism in the case of use as a flocculant is an effect of crosslinking and uniting these interparticles by crosslinking them with soil material (-) by aluminum polyvalent ions (+).

It is used in anticipation of the same effect as the solidified component.

At the same time, many pozzolan effects also depend on the reaction effect of Al ₂ O ₃ .

In addition, it has the effect of strengthening the solidification reaction, and also contributes to the prevention of alkali elution, since it also acts as a neutralizer for alkali and also promotes oxidation of alkali powder after solidification.

The structure of silicon dioxide (SiO ₂ ) varies from amorphous to stable under high pressure.

Every angle of a Si-O tetrahedral structural unit is a unique three-dimensional network.

Excellent in adsorption of water (→ silica gel), reacts with various other chemicals, contributes to the effect of pojoran egg and greatly contributes to the strength of solidified body.

Portland cement has a good coagulation role in cement hydration.

The solidified soil of the present invention constitutes a mechanism by the action of materials classified into the above forms, but it is an effect achieved by complex interactions as well as a one-shot effect.

Pozoran reaction occurs between the in situ mixture and the cement hydrate coating layer, so that the ettringgate calcium silicate crystals grow in the form of needles.

Ettring gate hydrates are also evident in this chemical structure, and are effective in lowering the water content as a stabilizing effect in fixing a lot of water as crystal water.

At the same time, since various complex salt compounds are produced, their properties are particularly important for fixing heavy metals.

The crystal structure of the Ettling gate has numerous acicular crystals of 1 ~ 10 ~ 10㎛ each, and forms a three-dimensionally combined skeleton structure in the treated soil. Incorporation into the hydrate layer to be integrated, on the other hand, the volume change accompanying crystal growth densifies the hydrate, strengthens the structure of the solid body, contributes to strength development, and significantly lowers the coefficient of permeability to form an impermeable layer.

Next, the siliceous-based powder-permeable waterproofing agent of the reinforcing layer 3 will be described in detail. As described above, it penetrates and fills the internal pores of the solidified soil layer 2 to solidify the internal structure of the solidified soil. In addition to the soil layer, the mechanical strength and impermeability of the order walls are further improved because the chemical reaction of activated silica forms insoluble crystals of calcium silicate hydrate and etring gate.

In addition, the acrylic emulsion is used to improve adhesion strength with the primary solidified soil layer and increase water resistance. Long-term waterproofing effect is maintained by repeated hydration reaction and action of unhydrated while water remains in the capillary pores after application. .

Hereinafter will be described the order wall installation process according to the present invention.

First, by mixing in a ratio of 100 to 120 parts of the high-strength siliceous permeable waterproofing agent composition in 900 parts of the field-produced soil in a weight ratio, the mixture is stirred evenly, and the water is mixed and adjusted according to the optimum function ratio corresponding to the maximum dry density.

At this time, the appropriate stirring amount is 10 ~ 20㎥, the stirring is using a separate agitator or backhoe of 1㎥ capacity.

When the agitation and mixing of the solidified soil compounding agent is completed, it is installed on both the bottom surface and the normal surface of the base plate 1 on which the trench is completed.

At this time, the ground stops so that there is no unevenness of the ground by using manpower or equipment. If groundwater occurs, install a drainage channel or drain it with a water pump.

Laying thickness is 15 ~ 20cm at one time, and after completion of the first laying, compaction is done and laminated until reaching the design thickness of 40 ~ 50cm.

After laying the solidified soil, 1 ~ 6 ton vibratory roller or compaction plate is used for voltage compaction continuously about 1a per hour in the longitudinal and horizontal direction simultaneously.

At this time, with the instrument, the ground level is checked and the planned ground height and construction thickness are maintained. By this process, the solidified soil layer 2 is formed.

After the above step, the siliceous permeable waterproof liquid is diluted in water at a weight ratio of 102 to 136: 20 to 30, and sprayed evenly with diluent 0.6 to 1.2 L per 1 m 2 of the surface of the solidified soil layer 2 using a sprayer. The reinforcement layer 3 reinforced to a certain depth is formed.

The physical properties were measured after curing for 28 days at room temperature for the order wall thickness 40 ~ 50㎝ constructed by the above method, and in the case of the bottom surface, the permeability coefficient was 1 centimeter per cent 1 cm (1 × 10)^-8㎝ / s) or less, uniaxial compressive strength is 100 ~ 150㎏f / ㎠ In the case of the law, the permeability coefficient was 1 / 10th of a centimeter (1 × 10) per second.^-7Cm / s) or less, uniaxial compressive strength was 80-100 kgf / cm <2>.

Referring to the performance and effect of the order wall according to the present invention through the following examples.

(Example 1)

The high strength siliceous permeable waterproofing agent was mixed with 100 kg of Masato 900 kg, which had a water content of 10%, and then stirred evenly. Then, 50 L of water was further mixed and stirred to put into a mold for compressive strength measurement and a mold for measuring permeability, respectively.

The following siliceous permeable waterproofing solution was applied, and in order to apply the same amount per unit area, it was diluted with water and weight ratio of 120: 30, 10 ml on the sample surface of the compressive strength test mold and 2.5 ml on the surface of the mold sample for permeability coefficient measurement. Was sprayed with a nebulizer and cured.

(Comparative Example 1)

Samples were prepared in the same manner and in the same manner as in Example 1 except that the same amount of cement was applied in place of the high-strength siliceous permeable waterproofing agent.

(Comparative Example 2)

Samples were prepared in the same manner and in the same manner as in Example 1 except that the process of spraying the siliceous-based permeable waterproof liquid was omitted.

(Example 2)

900 kg of yellow clay, which had a water content of 9%, was mixed with 100 kg of a high-strength inorganic permeable waterproofing agent and evenly mixed. Then, 80 L of water was mixed and stirred to put into a mold for measuring the compressive strength and a mold for measuring the coefficient of permeability, respectively.

The following siliceous permeable waterproofing solution was applied, and in order to apply the same amount per unit area, it was diluted with water and weight ratio of 120: 30, 10 ml on the sample surface of the compressive strength test mold and 2.5 ml on the surface of the mold sample for permeability coefficient measurement. Was sprayed with a nebulizer and cured.

(Comparative Example 3)

Samples were prepared in the same manner and in the same manner as in Example 2 except that the same amount of cement was applied in place of the high-strength siliceous permeable waterproofing agent.

(Comparative Example 4)

Samples were prepared in the same manner and in the same manner as in Example 2 except that the process of spraying the siliceous-based permeable waterproof liquid was omitted.

The samples produced in Examples 1 and 2 and Comparative Examples 1, 2, 3, and 4 were subjected to performance tests in the following manner, and the results are shown in Table 1.

Compressive strength was measured by uniaxial compressive strength test method of ordinary concrete after 28 days of curing at room temperature, and the permeability coefficient was cured at room temperature for 28 days and after curing in water for 7 days before the test (KS F 2322 test) Method).

TABLE 1

Example 1 Comparative Example 1 Comparative Example 2 Example 2 Comparative Example 3 Comparative Example 4 Uniaxial compressive strength (㎏ / ㎠) 127 148 114 103 124 89 Permeability coefficient (cm / s) 1.2 × 10 ^-8 2.4 × 10 ^-5 1.9 × 10 ^-7 0.9 × 10 ^-8 1.9 × 10 ^-5 1.2 × 10 ^-7

Referring to Table 1, it can be seen that significantly less in terms of uniaxial compressive strength or permeability coefficient compared to those used without the high-strength siliceous permeable waterproofing agent or siliceous permeable waterproofing agent.

The present invention is not limited to the above-described specific preferred embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

The present invention as described above has the advantage that the mechanical strength is also strong, and the impermeable property of the water permeability coefficient can be formed with a very small water barrier wall, the industrial effect is expected when constructing the landfill of this method.

Claims (7)

In the landfill layer wall structure of the waste landfill which is formed on the base ground (1), which is formed in the burrow in the upper and lower straits, A high-strength impermeable soil layer (2) formed on the bottom surface of the base plate (1) and a sloped surface integrally connected thereto; An impermeable waste landfill with a permeable waterproofing agent, characterized in that it is formed of a siliceous-based permeable reinforcement layer 3 which penetrates and cures from the surface of the solidified soil layer 2 to a predetermined depth of 15 to 25 mm and is densely packed than the structure of the solidified soil layer. Order wall structure. The method of claim 1, The solidified soil layer (2) is mixed with the high-strength siliceous-based permeable waterproofing agent composition in a ratio of 100 to 120 parts with respect to 900 parts of spot soil (clay, masato, loess) by weight ratio, and then thoroughly mixed and stirred for 30 minutes to 60 minutes, and then the optimum water content ratio. The water-permeable waste landfill containment wall layer structure of the impervious waterproofing agent, characterized in that the layer is formed by stirring and then hardening for 30 minutes to 60 minutes after adding water corresponding thereto. The method of claim 1, The reinforcing layer (3) is characterized by a layer in which the dilute solution mixed with the siliceous-based permeable waterproofing agent composition and water at a weight ratio of 103 to 136: 20 to 30 is sprayed and formed on the surface of the solidified soil layer (2). Impermeable Waste Landfill Line Wall Structure. The method of claim 3, wherein 1㎡ of surface area of hardened soil layer when spraying the reinforcement layer An impermeable waste landfill containment wall layer structure by means of a permeable waterproofing agent, which is sprayed and sprayed in an amount of 0.6 to 1.2 L per sugar to infiltrate the surface of the solidified soil layer 2 to a predetermined depth of 15 to 25 mm. The method of claim 2, The high strength siliceous-based permeable waterproofing agent composition includes 70 to 80 parts of portant cement, 5 to 10 parts of SiO ₂ , Al ₂ O ₃ , MgO, _{2 to 3} parts of Al ₂ (SiO ₃ ) _{3, and} Na ₂ O.nSiO _2, respectively. An impermeable waste landfill containment wall layer structure with a permeable waterproofing agent, characterized by a mixture composed of a ratio of 3 to 5 parts of acrylic powder. The method of claim 2, The impermeable waste landfill by the permeable waterproofing agent, characterized in that the optimum ratio of the soil (masato, loess) and the high strength siliceous-based permeable waterproofing agent composition is 10 to 15%, and the maximum dry density is maintained at about 1.7 to 2.0. Order wall structure. The method of claim 3, wherein The siliceous-based permeable waterproofing agent composition includes 70 to 80 parts of portant cement, 5 to 10 parts of SiO ₂ , Al ₂ O ₃ , MgO, _{2 to 3} parts of Al ₂ (SiO ₃ ) _3, Na ₂ O · nSiO ₂ , An impermeable waste landfill containment wall layer structure made of a permeable waterproofing agent, which is formed by adding 3 to 5 parts of acrylic powder and then adding it to a ratio of 10 to 15 parts of an acrylic emulsion (acrylic emulsion usable for mixed siliceous systems).