KR100272950B1 - Method of forming water-resist wall of rubbish buried place - Google Patents

Abstract

PURPOSE: A retaining wall installing method is provided to control outflow of seepage water by preventing a crack of a surface and to minimize permeable coefficient and mechanical strength. CONSTITUTION: A consolidation soil layer(2) is formed by paving the consolidation soil mixed on a floor face of a ground(1) with a specific combination. An enriched layer(3) is formed by injecting infiltration-reinforcing fluid having a specific chemical composition forming the consolidation soil. The consolidation layer is made by inserting calcium carbonate in a field generation soil after mixing cement. Then, the consolidation layer is made by diluting solidifying agent S fluid and solidifying agent F in water. The enriched layer is made by curing diluting fluid mixed the water and silica gel J after injecting from the surface of the consolidation soil layer .

Description

Order wall installation method of waste landfill

The present invention relates to a method for installing a waste wall in a waste landfill, and more particularly, to a process for installing a water barrier in a cage-type garbage landfill in which land is excavated in the ground and landfilled with waste.

Conventionally, in constructing a landfill site, most of them form a high-density polyethylene (HDPE) liner, and at the same time, a liner layer is formed by using a polyethylene sheet lining method of compacting clay or bentonite of a suitable thickness in the lower layer thereof.

However, this method places the clay with no 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 damaging the natural environment, and since most of the landfill sites are soft grounds with poor ground and soil properties, the support of the lower clay layer is insufficient, resulting in floating settlement. . Therefore, not only the joints between the polyethylene sheets are frequently 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 generated from landfill waste.

In particular, on the sloped surface of the cage-type waste landfill, clay located under the polyethylene sheet may slide due to slope slope, and clay laying itself is impossible, and in this case, a bentonite mat, which is a molded product, may be installed. However, even in this case, the above-mentioned problems frequently occurred due to the lack of support.

As an alternative to this, instead of laying the above-mentioned clays as the order layer, methods for forming a high-density soil layer having a predetermined thickness have been developed, for example.

BACKGROUND ART A waste landfill composition method is known in which an impermeable layer having a certain level of mechanical strength is formed by subjecting the surrounding soil of a landfill to a high order layer without laying additional materials such as polyethylene sheets.

This method utilizes the site soil generated by the dig during construction of the landfill site, mixes cement, solidification additives, water, etc., and mixes waste materials such as bentonite or waste foundry sand to a certain thickness. It is a method of curing after laying and compacting on the floor and the surface of landfill.

The above-described method intends to use the hardened soil layer having a certain level of compressive strength and impermeability as the order wall. In view of the effect, the hardened soil layer should be formed relatively thick. Therefore, there are disadvantages in terms of economic and construction, and the surface of the solidified soil layer, which is the order layer, may have cracks during the curing process, so that leachate may flow out through gaps generated by surface cracks during or after landfill. In addition, considering the compaction effect of the compaction construction equipment currently used, the impermeability (permeability coefficient of ten to ten million centimeters (10 ^-7 cm) is generally required through the process of laying and compacting soils. / Seconds)) is hard to get.

Therefore, the present invention is to solve the problems of the conventional method described above, the purpose of which is not only the mechanical strength but also the impermeability characteristic value of the permeability coefficient is very small and no phenomenon such as surface cracking can completely suppress the leachate outflow. It is to provide the order wall installation method of a new landfill.

1 is a cross-sectional view of the installation wall of the waste landfill site according to the present invention.

* Explanation of symbols for main parts of the drawings

1: base 2: hardened soil layer

3: reinforcement layer

According to the present invention, the method of installing the wastewater wall of the landfill site is to form a solidified soil layer having a predetermined thickness on the floor surface and the normal surface in forming a caged waste landfill in the form of a normal subsoil, and the impregnating reinforcement liquid, which is a special reinforcing material, It is characterized in that the surface layer of the high earthing layer is more densely formed by spray penetration from the surface.

In the method of the present invention, the solidified soil layer may be selectively constructed differently from the conventional method in consideration of suitability with an impregnation strengthening liquid to be used later.

With reference to Figure 1 will be described a method for installing a water barrier wall of the landfill according to the present invention.

After the landfill construction site is destroyed in the form of a Sangha River Strait, solidified soils of a specific combination are laid and compacted to a certain thickness on both the bottom surface and the normal surface of the original ground (1) to form a solidified soil layer (2). Next, the impregnating reinforcing liquid having a specific chemical composition is sprayed or applied from the surface of the solidified soil layer 2 to penetrate to a predetermined depth, and then, is formed to form a 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) optionally adds up to 30 parts of calcium carbonate to 1000 parts of field-produced soil (clay, acid soil, marine soil, sand, etc.) by weight, mixes 80-120 parts of cement, stirs sufficiently, and then 2 to 4 parts of the solidifying agent S and / or the solidifying agent F of the diluent were sprayed and blended to form and compact the solidified soil.

The reinforcing layer 3 is sprayed and sprayed with a diluent mixture of water and silica sol J stock solution in a volume ratio of 1: 1 to 2 in an amount of 0.6 to 1.2 liters per 1 m 2 of the surface layer of the solidified soil layer 2. Cured after penetrating to a certain depth from the surface of).

The above-mentioned on-site soil refers to the soil generated from the excavation work of waste landfill site such as marine soil, clay, and santo, and calcium carbonate and / or quicklime that are first mixed with the on-site soil are controlled to control the water content of the on-site soil. In addition, it is intended to provide sufficient calcium components involved in the generation of hydrated crystals with cement by pozzolanic reaction.In general, in case of soil with high water content or soil with high organic content, the amount is increased and vice versa. In the case of soils with low or low organic content and high sand content, reduce the amount.

Next, cement is usually used portland cement, but it is preferable to use blast furnace slag cement for soils with high salt content such as sea soil. Cement blending rates are controlled within the scope of the present invention depending on the structural-required strength of the ground and the characteristics of the soil to be solidified.

In the solidified soil mixture according to the present invention, a solidifying agent S and a solidifying agent F are used alone or in combination as a solidifying agent. Here, the solidifying agent S has a composition of about 80% of mixed inorganic salts such as sodium chloride, calcium chloride, potassium chloride, magnesium chloride, ammonium chloride, about 10% of a polymeric organic dispersant of naphthalene sulfonic acid soda and about 10% of caking enhancer of carboxymethylcellulose. It is a water-soluble high molecular compound formed by dissolving a solid component in water at a concentration of 30%. Solidifying agent F is a water-soluble high molecular type solidifying agent containing SBR latex, coumarone indene resin, and polyvinyl alcohol.

In the meantime, the silica sol J solution is used as the impregnating reinforcing liquid for forming the reinforcing layer 3 by spraying and impregnating the surface of the solidified soil layer 2, which is formed first, when the order wall is formed according to the present invention. This is an alkaline silica sol (fine colloidal silica) solution whose composition and properties are as follows.

Hereinafter, in the order wall installation method according to the present invention, the solidified soil used for forming the solidified soil layer 2 will be described in more detail.

Field-produced soils utilized in solidified soils for water-repellent walls are often soils, marine soils, or humus soils, and contain large amounts of organic substances, and the grain size of the soil is uneven. In general, since the on-site soil is used as it is without a separate washing or purification treatment, if the solidification treatment is performed only with quicklime or cement-based material, the solidification reaction between the granules (soil particles) and the cement of the on-site soil does not proceed smoothly. The main cause of this phenomenon is that the humic acid-based organic material, which is in the charged state on the surface of the particles, interferes with the contact between the particles and the cement-based minerals, thereby inhibiting the binding and hydration reaction between them. In addition, it is because the uniform dispersion and mixing between cements and granules having different particle sizes, specific gravity and surface properties are not well achieved. In order to solve such a problem, in the present invention, a solidifying agent S is mixed and used. As described above, the solidifying agent S is composed of an inorganic salt containing an alkali metal ion such as calcium chloride, sodium chloride and magnesium chloride, a polymeric dispersant, etc., wherein the inorganic salt is dissociated into an ionic state in an aqueous solution and is present around the granules. It lowers the charge potential of organic matter and facilitates the direct reaction between cement and granules, which are actually solidifying ingredients. In addition, the polymer dispersant suppresses the phase separation between granules and cement in the mixing of solidified soils. To get. In addition, the solidifying agent F is a solidifying agent composed of a water-soluble polymer mixture such as SBR latex, coumarone indene resin, polyvinyl alcohol, etc., and when added thereto, these components fill fine pores in the coarse clay and impart coking force between the particles. By forming a waterproof film, the strength of the hardened soil is improved as well as impermeability. Therefore, in the present invention, when the solidifying agent S and the solidifying agent F described above are used alone or in combination according to the soil to be solidified, a solidified soil having excellent impermeability and mechanical strength can be obtained.

For soils with a high clay content, only solidifying agent S can be used to obtain high-quality coarse clay. In the case of relatively large-scale soils such as masato, only solidifying agent F can be used. In other cases, good results can be obtained by mixing the two properly.

Next, the impregnating reinforcement liquid will be described in detail, which is penetrated and filled by the internal supply of the solidified soil layer 2 as described above, thereby making the internal structure of the solidified soil into a tight structure, thereby improving mechanical strength and impermeability. This impregnating reinforcement liquid is permanently formed by the fine silica colloid, the main component of which is penetrated into the pores of the clay by capillary action, and then chemically combined with the clay by performing a pozzolanic reaction with granules and cement components of the clay. It acts as an integrated void filler. Therefore, the solidified soil (reinforced layer 3) supports a tighter internal structure than when the impregnated reinforcement liquid is not treated, thereby forming a high-order barrier layer.

Hereinafter, a description will be given of the order wall installation process according to the present invention.

First, the mixture is mixed with 80 to 120 parts of calcium carbonate within 30 parts of calcium carbonate in the field-produced soil (mountain soil, marine soil, etc.) by weight ratio and stirred evenly, and the water is mixed to adjust the water content. At this time, the water is adjusted so that the compaction of the solidified soil becomes suitable. Thereafter, 2 to 4 parts of solidifying agent S and / or solidifying agent F are diluted in water (range of 3 to 10 liters of water per kg of undiluted solution) and evenly sprayed on the mixed soil and stirred at least 10 times. At this time, the appropriate stirring amount is 10ℓ20㎥, the stirring is using a separate agitator or backhoe with a capacity of about 1㎥.

Then, after stirring 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 the design thickness is reached.

After laying the solidified soil, the vibration roller or compaction plate of 1 to 6 tons is continuously compacted at about 1a per hour in the longitudinal and horizontal directions 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.

Next, dilute the silica sol J stock solution, which is an impregnating powder, to water at a volume ratio of 1: 1 to 2, and then spray with 0.6 to 1.2 L of diluent per 1 m 2 of the surface of the solidified soil layer. A reinforcement layer 3 having a certain depth is formed.

Physical properties were measured after curing for 28 days at room temperature for the ordered wall (thickness 30 ~ 40cm) constructed by the above method.In the case of the bottom surface, the permeability coefficient was less than 1cm per hundredth centimeter (1X10 ^-8 cm / s) per second, uniaxial The compressive strength ranged from 40 to 80 kg / cm 2, and the permeability coefficient was less than 1 millionth per cent (1 × 10 ^-7 cm / s) per second and the uniaxial compressive strength was 30 to 60 kg / cm 2.

Through the following examples to explain the performance and effect of the order wall according to the present invention bar of the present invention is of course not limited to this embodiment.

Example 1

1000 kg of acid soil composed of 55% water content was mixed with 20 kg of calcium carbonate and 120 kg of cement in order to stir evenly. Then, 3 kg of solidifying agent S was diluted in 12 L of water and sprayed and stirred to measure the compressive strength (15 cm in diameter x 30 cm in height). Cylindrical) and a permeability coefficient measurement mold (cylindrical of 7 cm in diameter x 14 cm in height) were placed and compacted, respectively. Next, the silica sol J liquid was sprayed, and in order to apply the same amount per unit area, the aqueous solution of silica sol J diluted in a volume ratio of 1: 1 with water was 10 ml on the sample surface of the mold for compressive strength test, and the mold for measuring the permeability coefficient. 2.5 ml was sprayed onto the surface of the sample and cured.

Comparative Example 1

The sample was prepared by the same method and conditions as Example 1 except having applied the same amount of solidifying agent F instead of the solidifying agent S.

Comparative Example 2

Samples were prepared in the same manner and in the same manner as in Example 1, except that 1.5 kg of solidifying agent S and 1.5 kg of solidifying agent F were mixed instead of the solidifying agent S.

Comparative Example 3

A sample was prepared in the same manner and in the same manner as in Example 1, except that the step of spraying the silica sol J liquid was omitted.

Example 2

1000kg of dissolved soil composed of 55% water content was mixed with 25kg of calcium carbonate and 110kg of cement, and then stirred evenly. Then, 3kg of solidifying agent S was diluted in 12ℓ of water and sprayed and stirred to measure the compressive strength (cylindrical having a diameter of 15cm x 30cm in height). ) And a permeability coefficient measuring mold (cylinder of 7 cm in diameter x 14 cm in height), respectively, and compacted, followed by spraying with a silica sol J aqueous solution. Specifically, in order to apply the same amount per unit area, 10 ml of aqueous solution of silica sol diluted in a volume ratio of 1: 1 in water was sprayed with a sprayer with 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. After curing.

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

The 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).

Referring to Table 2, as previously described, care must be taken in using the solidifying agent S and the solidifying agent F according to the soil quality of the solidified soil, and in particular, the conventional construction method in which the reinforcing layer 3 is not separately formed using the impregnating hardening liquid. It can be seen that when the uniaxial compressive strength and the coefficient of permeability are significantly lower than the present invention.

As described in detail above, according to the method for installing the secondary wall of the landfill according to the present invention, it is possible to form the secondary wall in which not only the mechanical strength but also the impermeable characteristic value of the permeability coefficient is very small and the phenomenon such as surface cracking does not occur at all. .

Claims (1)

After discharging in the subsidiary ground on the ground, form a soil layer on both the bottom surface and the sloped surface integrally connected to it (at this time, the solidified layer should be added within 30 parts of calcium carbonate to 1000 parts of the soil in weight ratio. 80-120 parts of cement are mixed and stirred, and 80% of two or more mixed inorganic salts selected from the group consisting of sodium chloride, calcium chloride, potassium chloride, magnesium chloride, and ammonium chloride, 10% of sodium naphthalene sulfonate, and 10% of carboxymethylcellulose It is formed by spraying, blending and solidifying an aqueous solution of at least one solidifying agent F, which is a water-soluble high-molecular-based solidifying agent containing at least one of S or SBR latex, coumarone indene resin, and polyvinyl alcohol, diluted in water with 2 to 4 parts), From the surface of the solidified soil layer to a certain depth to form a reinforcing layer filled more tightly than the structure of the solidified soil layer, wherein the reinforcing layer is silica sol J in water A water barrier wall installed in a waste landfill site characterized in that the aqueous solution mixed with a solution (silica colloid solution having a solid content of 10% or more) at a volume ratio of 1: 1 to 2 was sprayed to form 0.6 to 1.2 L of the surface area of the solidified soil layer to 1,2 m 2. Method.