KR100913268B1 - Hardening Material To Solidify Frail Ground - Google Patents

Abstract

The present invention relates to a solid foundation for reinforcing soft ground with excellent roughness and excellent effect of immobilizing heavy metals, CSA-based admixtures: 5-30% by weight, natural anhydrous gypsum: 10-20% by weight, quicklime (or slaked lime): 1 ~ 10% by weight, blast furnace slag: 20 to 50% by weight, water reducing agent: 0.1 to 10% by weight and non-sulfide salt: 0.1 to 10% by weight, the CSA-based admixture contains 30 to 38% of the Al ₂ O ₃ component The clinker is pulverized so as to have a powder degree of about 4000 to 5500 cm 2 / g, and the powder of the whale slag is 5000 cm 2 / g.

Fire, Heavy Metals

Description

Hardening material for reinforcing soft ground {Hardening Material To Solidify Frail Ground}

The present invention relates to a soft ground reinforcement solids, and more particularly, to a soft ground reinforcement solids excellent in roughness and excellent in the heavy metal immobilization effect.

Soaking areas such as coastal wetlands, rivers, lakes, adjacent ports, or dredged landfills are generally very fragile. Therefore, in order to construct buildings in such areas, the entire ground must first be firmed to prevent subsidence and support. Actions should be taken to strengthen the situation. In order to take such measures, the first necessary thing is to harden and soften the soft ground, and many kinds of solidifying materials are used for this purpose.

On the other hand, a lot of controversy has recently been caused regarding the harmfulness of heavy metals, especially hexavalent chromium, contained in cement. Hexavalent chromium may penetrate into cells and cause cancer, worsening allergic contact dermatitis or atopic constitution. This is because it is known to make. Hexavalent chromium contained in cement is eluted from the cement after construction and contaminates the surrounding soil or groundwater, resulting in adverse effects on the human body.

On the other hand, in the case of soils having high water content and containing a large amount of organic matter or heavy metal compounds, cement rapidly bonds with calcium divalent ions in the liquid phase during hydration to produce lime salts that do not contribute to solidification. By densely covering the surface of the cement particles and delaying or stopping the hydration reaction, solidification inhibition phenomenon occurs. When this solidification phenomenon occurs, even if a large amount of cement is used, it becomes difficult to express the target strength.

For these reasons, the solidified material for reinforcing soft ground should first be to solidify and soften the soft ground, and secondly to prevent the hexavalent chromium contained in cement from eluting. Soils containing large amounts of organic matter or heavy metal compounds should be prevented from inhibiting cement solidification.

Conventionally used solidifying materials include a mixture of slag and anhydrous gypsum in cement, a mixture of fly ash and anhydrous gypsum in cement, and a mixture of CSA-based mixture in cement.

The mixture of cement and slag and anhydrous gypsum, and the mixture of cement and fly ash and anhydrous gypsum can all be easily obtained at a low price, and high-strength barriers can be made according to the mixing ratio of the materials. There is an advantage. However, these mixtures take a long time to cure, have a large shrinkage phenomenon, and are therefore unsuitable for use as a solid material for grouting, and when used for soil pavement, there is a risk of cracking. In addition, there is a problem in that the effect of immobilizing it so that heavy metals contained in cement or the like is not eluted.

The mixture in which the CSA-based admixture is mixed with the cement has the advantage that the time required for condensation is improved compared to other mixtures, thereby improving workability and workability, but the price of the CSA-based admixture is high, resulting in an increase in the overall cost. In addition, this mixture also has a problem in that the shrinkage phenomenon is large, there is a problem to use as a solidifying material of the ground grouting, and also has a problem that the effect of immobilizing it so that heavy metals contained in cement, etc. do not elute.

The present invention has been proposed to solve the above-mentioned drawbacks of the prior arts, and an object of the present invention is to condense and harden the soft ground in a short time, and to prevent the hexavalent chromium contained in cement from eluting, furthermore, the water content It is to provide a solidifying material to prevent the solidification inhibition of the cement even in the case of high soil and a large amount of organic matter or heavy metal compounds.

The present invention is characterized by blending CSA-based admixture, natural anhydrous gypsum, quicklime (or slaked lime), blast furnace slag, water reducing agent and disulfide salt in the following ratio.

Material name CSA-based admixture Anhydrous gypsum Quicklime (slaked lime) Blast furnace slag Water reducing agent Disulphide Rate (wt%) 5-30 10-20 1-10 20-50 0.1-10 0.1-10

CSA-based admixtures promote the production of ettringite and serve to fix heavy metals. In the present invention, the CSA-based admixture should be used to grind the clinker containing 30 to 38% of the Al ₂ O ₃ component to a powder degree of about 4000 to 5500 cm 2 / g. When the powder level is less than 4000cm2 / g, the curing rate is slowed down, so that the formation of ettringite is not performed quickly, and the roughening performance is decreased. When the powder level is more than 5500cm2 / g, the initial setting speed is increased. The workability is poor, and the performance of the injection is poor, so that the water particles are not water-tightened and immobilized, and thus the strength may be decreased in the long term. If the CSA-based admixture is used in an amount of 5 wt% or less, the ettringite formation is not sufficient. If the CSA-based admixture is used in an amount of 30 wt% or more, the cost may be increased and the strength may be weakened.

In the present invention, anhydrous gypsum hardens the hydrate of the CSA-based admixture and prevents shrinkage of the hardened cement body. Anhydrous gypsum is suitable for reaction with CSA-based admixtures because it has a slower dissolution rate compared to hemihydrate or dihydrate gypsum. Since anhydrous gypsum reacts with CSA-based admixtures and quicklime (or slaked lime) to produce ettringite, the amount of anhydrous gypsum is determined by the amount of CSA-based admixtures or quicklime (or slaked lime). In the present invention, the amount of anhydrous gypsum is 10 to 20% by weight, the weight ratio of CSA-based admixture / anhydrous gypsum should be in the range of 1.5 to 2.5, preferably 1.6 ± 0.1. This ratio of CSA-based admixtures / anhydrous gypsum affects stability (dimension stability) and durability at long-term age, and contributes to the development of high strength.

When the present invention is used as an additive for soil concrete, anhydrous gypsum should be used as type II anhydrous gypsum, wherein the anhydrous gypsum should have a powder specific surface area of 3,500 to 5,000 cm 2 / g. If anhydrous gypsum has a powder level of 3500 cm 2 / g or less, there is a fear of long-term expansion.

Quicklime (or slaked lime) and blast furnace slag are hydrates produced by latent hydrophobicity and pozzolanic reactions to contribute to strength development. As mentioned above, quicklime (or hydrated lime) reacts with CSA-based admixtures and anhydrous gypsum to produce ettringite, so the amount of quicklime (or hydrated lime) is determined by the amount of CSA-based admixture or anhydrous gypsum. In the present invention, the amount of quicklime (or slaked lime) should be 1 to 10% by weight, and preferably used in a range of 1/5 to 1/3 by weight relative to the CSA-based admixture.

On the other hand, quicklime reacts and generates heat in the early stage, and it forms a calcium hydroxide, which reduces the water content of the soil, thereby securing the initial strength and preventing cracks caused by dry shrinkage. It is more advantageous to use.

Blast furnace slag helps to produce ettringite and contributes to immobilization and stabilization of heavy metals. In the present invention, the use amount of blast furnace slag should be 20 to 50% by weight, the use of less than 20% by weight may reduce the compressive strength, when using more than 50% by weight of the other materials are reduced The whole harmony is broken. The high slag powder should be at least 5000 cm 2 / g, but preferably at least 7000 cm 2 / g. When the blast furnace slag has a powder degree of 5000 cm 2 / g or less, the effect of increasing strength decreases and the latent hydraulic speed greatly decreases.

The disulfide salts serve to promote the hardening of the cement and CSA-based admixtures to activate the heavy metal immobilization reaction. In the present invention, the disulphide salt promotes the hydration reaction with the CSA-based admixture after the formation of the solid and promotes the dissolution rate of the silica (SiO ₂ ) and alumina (Al ₂ O ₃ ) components which are eluted from the soil for a long time. By facilitating the pozzolanic reaction, it contributes particularly to high strength at early age. In the present invention, the amount of disulfide salt should be 0.1 to 10% by weight. However, since the non-sulfide salt is used on the premise of reaction with the CSA-based admixture, the specific amount thereof will be determined by the amount of the CSA-based admixture. That is, in the present invention, any one of K ₂ SiF ₆ , MgSiF ₆ , and Na ₂ SiF ₆ may be used as the disulfide salt, but K ₂ SiF ₆ has the highest effect.

Reducing agents not only increase the fluidity of cement and other mixtures to increase workability, but also increase the penetration rate between soil particles, which helps to obtain a hardened hardened body. In the present invention, the water reducing agent should be used in an amount of 0.1 to 10% by weight, and the specific amount thereof should be determined in consideration of the total compounding ratio of other materials.

As shown above, the present invention is a CSA-based admixture: 5 to 30% by weight, natural anhydrous gypsum: 10 to 20% by weight, quicklime (or slaked lime): 1 to 10% by weight, blast furnace slag: 20 to 50% by weight, water reducing agent: It is characterized in that the mixture of 0.1 to 10% by weight and 0.1 to 10% by weight of the non-sulfide salt, it is to provide a soft ground reinforcing solidified material having excellent roughness and excellent heavy metal immobilization effect by this composition.

According to the present invention, the soft ground can be hardened and hardened in a faster time, and the hexavalent chromium contained in the cement is not eluted. Furthermore, the solidification of cement even in the case of soils having high water content and containing a large amount of organic matter or heavy metal compounds. It has the effect of preventing the occurrence of inhibition, and compared with the conventional CSA-based solidified material, the price is low and very economical is very advantageous.

Detailed Description of the Invention

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated based on an Example.

This embodiment is made in order to contrast the effects of the solidified material composition of the present invention and the conventional solidified material.

First, 30% by weight of CSA-based admixture, 20% by weight of anhydrous gypsum, 5% by weight of quicklime, 40% by weight of blast furnace slag, 3% by weight of reducing agent, and 2% by weight of siliceous salt (K ₂ SiF ₆ ) Was prepared.

In mixing the solidified material of the present invention with cement, assuming that 500 kg of cement was used, 25 kg of the cement was replaced with the solidified material of the present invention as Example 1, and 50 kg of the cement was determined. What replaced the solidified material of this invention in Example 2 was set as Example 3 which replaced 75 kg of this cement with the solidified material of this invention, and substituted 100 kg of this cement with the solidified material of this invention. This was determined as Example 4.

As a prior art for comparison with the present invention, using only 500 kg of cement is determined in Comparative Example 1, 250 kg of cement mixed with blast furnace slag 250 kg in Comparative Example 2, 250 kg of cement fly ash 250 kg The mixed thing was determined as the comparative example 3.

In order to examine the effect of using only the CSA-based admixture, 25 kg of the cement was replaced with a CSA-based admixture based on 500 kg of cement, respectively, and Comparative Example 4-1 was used. What was replaced with the admixture was determined by Comparative Example 4-2, and when 75 kg of this cement was replaced with the CSA admixture, it was determined as Comparative Example 4-3, and 100 kg of the cement was replaced with the CSA admixture. It was set to -4.

The cured product was made by mixing 1000 kg of general Masato (6% water content) and 250 kg of water in each of the Examples and Comparative Examples. The compressive strength was measured after 3 days and after 28 days for each cured product. On the other hand, each of the cured bodies was tested for dissolution of harmful heavy metals according to the waste process test method.

Table 1 shows the compressive strength measurements for each Example and each Comparative Example, Table 2 shows the measurement of the harmful heavy metal dissolution test for each Example and each Comparative Example.

Table 1

cement Slag Fly ash CSA Mixture Fire extinguisher of the present invention soil water Compressive strength (MPa) 3 days 28 days Comparative Example 1 500 1000 250 6.5 12.4 Comparative Example 2 250 250 1000 250 4.9 11.5 Comparative Example 3 250 250 1000 250 5.1 12.1 Comparative Example 4-1 475 25 1000 250 5.9 13.6 Comparative Example 4-2 450 50 1000 250 8.4 15.7 Comparative Example 4-3 425 75 1000 250 10.2 16.0 Comparative Example 4-4 400 100 1000 250 13.4 15.4 Example 1 475 25 1000 250 7.5 15.2 Example 2 450 50 1000 250 10.1 16.9 Example 3 425 75 1000 250 13.8 18.1 Example 4 400 100 1000 250 15.4 18.5

Table 2

division Heavy Metal Elution (mg / L) Hg CD Cr + 6 As Pd Cu Comparative Example 1 Not detected 0.05 0.16 0.14 0.13 0.82 Comparative Example 2 Not detected 0.02 0.14 0.11 0.10 0.22 Comparative Example 3 Not detected 0.04 0.13 0.13 0.11 0.16 Comparative Example 4-1 Not detected 0.02 0.10 0.11 0.07 0.11 Comparative Example 4-2 Not detected 0.018 0.08 0.11 Not detected 0.09 Comparative Example 4-3 Not detected 0.005 0.05 Not detected Not detected Not detected Comparative Example 4-4 Not detected Not detected 0.01 Not detected Not detected Not detected Example 1 Not detected 0.01 0.05 0.02 Not detected 0.09 Example 2 Not detected 0.005 0.01 Not detected Not detected Not detected Example 3 Not detected Not detected Not detected Not detected Not detected Not detected Example 4 Not detected Not detected Not detected Not detected Not detected Not detected

As shown in Table 1, compared with Comparative Examples 1 to 3, the compressive strength was significantly increased when the solidified material of the present invention was used. In addition, even when only the CSA-based admixture was used, the compressive strength of using the solidified material of the present invention was significantly higher when the same amount was used.

Specifically, the compressive strength when 100 kg of CSA-based admixture was used was 13.4 MPa on the 3rd day and 15.4 MPa on the 28th day, whereas the compressive strength when 75 kg of the solidified material of the present invention was used on the 3rd day was 13.8 MPa, day 28 All were high as 18.1 MPa. Considering that the price of the CSA-based admixture is very expensive compared to the price of the solidified product of the present invention, the present invention is economically very advantageous.

On the other hand, in Table 2, when more than 75 kg of the solidified material of the present invention, no harmful heavy metals were eluted at all, none of the comparative examples completely prevented the dissolution of hexavalent chromium. . Therefore, the present invention is also excellent in heavy metal elution resistance compared to the prior art. In particular, considering that the risk of hexavalent chromium is emphasized, the present invention is very advantageous only by being able to completely prevent elution of hexavalent chromium.

Claims (7)

CSA-based admixture: 5-30% by weight, natural anhydrous gypsum: 10-20% by weight, quicklime (or hydrated lime): 1-10% by weight, blast furnace slag: 20-50% by weight, water reducing agent: 0.1-10% by weight and irregular Flame: Mix 0.1-10% by weight, The CSA-based admixture is a pulverized clinker containing 30 to 38% Al ₂ O ₃ component so that the powder degree is about 4000 ~ 5500cm 2 / g, The solid slag reinforcement for soft ground, characterized in that the powder degree of the whale slag is 5000 ㎠ / g. delete The solid ground reinforcing solidified material according to claim 1, wherein the weight ratio of the CSA-based admixture to the anhydrous gypsum is in the range of 1.5 to 2.5. The solid ground reinforcing solidified material according to claim 1 or 3, wherein a weight ratio of the CSA-based admixture to the anhydrous gypsum is in the range of 1.6 ± 0.1. delete The solidified ground for reinforcing soft ground according to claim 1, wherein the powdery gypsum has a powder specific surface area of 3,500 to 5,000 cm 2 / g. The solid ground reinforcing material for reinforcing soft ground according to claim 1, wherein the disulfide salt is any one of K ₂ SiF ₆ , MgSiF ₆ , and Na ₂ SiF ₆ .