KR20120006269A - Omlitted - Google Patents

Abstract

PURPOSE: A method for stabilizing heavy metal polluted soil using the waste of bone china or oyster shells is provided to stabilize the heavy metal concentration of heavy metal polluted soil to become lower than a pre-set value by grinding the waste and mixing the ground powder with the heavy metal polluted soil. CONSTITUTION: The waste of oyster shells or bone china is ground. The heavy metal concentration of heavy metal polluted soil is measured. The concentration of the ground powder is determined in a range between 1 and 10 weight%. The ground powder is mixed with the heavy metal polluted soil in order to reduce the heavy metal concentration of the heavy metal polluted soil.

Description

Stabilization of Heavy Metal-Contaminated Soils Using Oyster Shells or Bone Waste Treatments

The present invention relates to a method for stabilizing heavy metal contaminated soil using the waste shells of oysters or the waste treatment of bone china, in particular, the waste shells of oysters or bone china crushed to a certain size of powder and soil contaminated with heavy metals The present invention relates to a method for stabilizing heavy metal concentrations in soil contaminated with heavy metals below a predetermined reference value by mixing with.

In general, the soil is a major component of the ecosystem, which, together with air and water, plays an absolute role in the survival of plants and animals, including humans. Soil can be contaminated in a variety of ways for a variety of reasons. Soil pollution is indirect and chronic and difficult to improve or restore. In other words, soil pollution causes indirect effects that damage human beings by contaminating soil organisms and groundwater, and has a chronic effect of accumulating for a long time rather than acute damage. In addition, soil pollution, like most environmental pollution, is difficult to improve once it is characterized by much longer time and much economic investment than air pollution or water pollution.

There are many sources of pollution that contaminate the soil, of which heavy metals are important sources of health. Heavy metals have low solubility and mobility, so they remain long term once they enter the soil. In addition, heavy metals eluted from soil can accumulate in plants and damage humans and livestock directly or indirectly through the food chain.

Heavy metal pollution in Korea is mainly caused by the loss of mineral residues generated from the mining, beneficiation and smelting of metal mines and the outflow of acid mine drainage. In particular, in the case of the abandoned mines, most of the mineral wastes discharged from past mine activities are left without pollution prevention facilities, and they contaminate farmland and water systems under the mines. Agricultural products grown in contaminated farmland or grown with contaminated water contain a large amount of heavy metals, and there is a possibility of causing heavy adverse effects on health by accumulating heavy metals in the body of a person who consumed it.

Conventional techniques for treating soil contaminated with heavy metals include pollutant sequestration methods to temporarily isolate contaminated soils, contaminated soil purification techniques for fundamental treatment, and methods of transporting to a separate landfill or filling the mines. In Korea, pollutant sequestration methods are mainly used in consideration of mine location, economic feasibility, and technological feasibility. In foreign countries, pollutant sequestration method and polluted soil purification technology are used simultaneously. However, the source isolation method in the prior art is difficult to secure a disposal site to isolate the contaminated soil and there is a costly problem because it is based on the replacement of new soil. Soil purification technology has a problem that can be re-dissolved depending on the conditions such as pH after chemical treatment by the drug.

In addition, these conventional purification methods are very complicated and perform the purification from a civil engineering point of view, thus focusing only on reducing the concentration of pollutants in the soil, and losing the inherent physicochemical and biological functions of plants. May adversely affect growth and microbial ecology. Therefore, it is urgent to develop a heavy metal contaminated soil purification method that is less expensive than the conventional purification method and can recycle the waste resources discarded in Korea.

An object of the present invention for solving the above-mentioned problems is a method for stabilizing heavy metal contaminated soil using waste disposal of oysters or shells. A method for stabilization of heavy metal contaminated soil using waste angles of oysters or bone china to stabilize the heavy metal concentration of heavy metal contaminated soil below a certain level by pulverizing it into powder and mixing it with heavy metal contaminated soil will be.

The characteristics of the method for stabilizing heavy metal contaminated soil using the waste shell of the oyster or the main China according to the present invention for achieving the above object, the first step of pulverizing the waste shell of the oyster or waste Wow; Measuring a heavy metal concentration of soil to be stabilized; A third step of determining a concentration of the powder obtained through the first step required to reduce the heavy metal concentration to a reference value in a concentration range of 1 to 10% by weight; And a fourth step of mixing with the heavy metal contaminated soil in accordance with the concentration determined through the third step.

As expected effects due to the above-described features of the present invention, the method of stabilizing heavy metal contaminated soil not only lowers the concentration of heavy metals in the soil, but also improves the pH of the soil and increases the substitutional calcium ions to improve soil quality. Has In addition, the use of domestic waste resources such as oyster scrap or waste treatment of the main China is low in the stabilization cost of the soil, and has an advantageous economic effect in terms of waste resources.

1 to 4 is an exemplary view showing the experimental method and the experimental passage used during the application process of stabilization of heavy metal contaminated soil using the waste shell of the oyster or the waste treatment of the main China according to the present invention

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: FIG.

First, briefly look at the technical background applied to the present invention, Korea is the world's third largest oyster farming country, and most of them sell only the contents after removing the shell of the oyster, a huge oyster obstruction angle remains as a waste around the bottom of the cave It is being buried.

At this time, since the main component of the oyster shell is CaCO ₃ , there is no need for a separate process for pH control because it has a neutralizing ability in treating acid soil and tailings in the contaminated waste mine area.

Phosphorus contained in bones in ceramics also makes heavy metals a new mineral of morphite family with very low solubility (Table 1), which can significantly reduce environmental pollution due to the leaching of heavy metals.

Therefore, prior to applying the method for stabilizing heavy metal contaminated soil using the waste shell of the oyster or the waste treatment of the present invention according to the present invention through the experiment for this to demonstrate the effect according to the present invention.

In this experiment, the oyster waste shells collected from the oyster farm and the waste bone china or porcelain debris collected from Korea Ceramics Co., Ltd. were crushed to find out the potential as a reactant material for stabilizing heavy metals.

The amount of phosphorus elution increased with time, but the amount of elution with the initial time increased significantly.

Phosphorus was eluted at about 0.033 mg per gram in oyster obstruction and 0.018 mg per gram in pottery.

In the case of Experiment 1 in which the same amount of distilled water was passed every day after adding the reactant in the lower layer and the contaminated soil in the upper layer, the heavy metal in the test results according to the TCLP test method shown in FIG. In case of Experiment 2, the concentration of polluted water was passed through the contaminated water around the abandoned mine after filling the reactant, and the outflowed contaminated water showed lower heavy metal concentration than the initial concentration of contaminated water.

Guar gum or waste porcelain sludge was added to waste porcelain and oyster shells to make reactants, and applied to soil around Hamchang mine for 6 months. Soil was 31% lead and 18% cadmium compared to the non-applied area. , 17% less zinc was eluted.

This reactant is applicable alone to stabilize heavy metals, and if contaminants other than heavy metals are present, it is expected that the reaction wall technique will be a more complete anti-pollution measure.

In the following, the mechanism of lowering the concentration of heavy metals in the soil by calcium carbonate (CaCO ₃ ), which is the main component of the closed shell of oysters, will be described.

As a first step, is the CaCO ₃ incorporated into the soil by the water separated ions Ca ^{2 +} cations and CO ₃ ^{2 -} anions is produced. The produced CO ₃ ^{2 -} reacts with water (H ₂ O) to produce HCO ₃ ^- and OH ^- to raise the pH of the soil.

This is summarized in Scheme 1 below.

Scheme 1

Subsequently, in the next step, the anions of HCO ₃ ⁻ and OH ⁻ generated in the first step are combined with the heavy metal in the cation state to change the eluted heavy metal into a stable compound as shown in Scheme 2 below.

Scheme 2

At higher pH conditions of the number of the anion OH ^{- -} OH by reaction with the anion of the heavy metal cations Mn ⁺ are summarized by the reaction formula 3 that can be generated even with the sorbent product of the M (OH) n.

Scheme 3

In addition, due to the nature of heavy metals (except molybdenum), the solubility of heavy metals is reduced at high pH, thereby reducing the plant effectiveness.

The experimental conditions and experimental results for the heavy metal contaminated soil stabilization method according to the present invention will be described below. The experimental conditions are described in terms of sample preparation method, soil stabilization method, and method of measuring heavy metal concentration of soil, and the experimental results are explained in terms of change of heavy metal concentration of soil treated and changes in physicochemical properties of soil.

Stabilization Experiment: Field Experiment

In order to verify the long-term effects, stabilizing materials were applied directly to the actual contaminated area. The site test area was Hamchang mine in Jeongseon-gun, Gangwon-do. In June 2009, two adjacent 1m × 1m areas were marked, one was conducted for stabilization experiments, and the other was used as a control variable area for comparison of stabilization efficiency.

Soil samples were taken from each zone and the initial heavy metal concentrations were analyzed. The stabilizing zone was sprayed with stabilizing material on the surface, and the control variable area was sprayed with sand of the same particle size and weight as the stabilizing material. After leaving for 6 months, soil was collected within 10 cm depth from the surface and analyzed for heavy metal concentration.

First of all, the characteristics of stabilizing materials using the waste shells of oysters or the waste treatment of bone china are shown in Table 3 below that the results of full-content analysis and TCLP test indicate that the waste bones and the shells of the oysters could be used as materials for stabilizing heavy metals. As summarized through it was known.

Also, as shown in FIG. 2, the concentration of P eluted from the waste shells of the oysters or the waste treatments of the main china was shown as a potential reactant for stabilizing heavy metals in the dissolution environment.

Stabilization Experiment: Batch Experiment

Samples from both contaminated areas were used for the batch experiments. The initial total content and TCLP dissolution test results before the stabilization test are shown in Table 4 below.

After 24 hours of stabilization, TCLP concentrations decreased by 33% and 46%, cadmium 35% and 50%, zinc 40% and 60%, and copper 52% and 51%. As shown in the attached FIG. 3, respectively.

3 is a graph of TCLP elution concentration of heavy metals before and after stabilization of contaminated areas A and B: batch test.

Application to actual site contaminated area contaminated with various heavy metals: field experiment

After six months, the stabilization zones showed 35% of lead, 47% of cadmium, 46% of zinc, and 34% of copper at TCLP concentrations, as shown in Figure 4 attached to the control zone, The characteristics and characteristics are summarized in the table below.

1. The waste bone china and the digging angles to be treated can be used as sources of P for stabilization of heavy metals.

2. The amount of heavy metals eluted from the soil decreases significantly as the reaction time with the reaction material increases.

3. In the batch and column experiments, the waste bone difference and the digging angle reduced the amount of heavy metals eluted by 33 ~ 69% depending on the type of heavy metals. This suggests that waste bone china and oyster shell angles will be effective as heavy metal pollution treatment methods such as lowering the concentration of heavy metals eluted in the heavy metal contaminated area in the dissolution environment, preventing secondary pollution such as groundwater contamination and contributing to neutralization of pH. .

4. Based on the batch and column experiments, the reaction materials were mixed with guar gum and solidified to a diameter of about 0.5 cm and sprinkled on site soil and applied for 6 months in natural conditions. 35% of lead, 47% of cadmium, 46% of zinc and copper TCLP elution was reduced by 34%. (Why mix with guar gum: Powdered crushed crushed angle and sprinkled bone china powder are easily swept away by rain and weighed more for 6 months, considering that they will not be applied continuously to the area of 1m ^{2 that} is zoned. Powders were applied together using guar gum to give a proper weight.)

5. This result is considered to be very environmentally friendly in that it not only prevents the health of residents related to heavy metals in the contaminated area and the pollution of nearby groundwater due to the leached heavy metals, but also makes this effect possible with waste bone China and digging angle.

While the invention has been shown and described with respect to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone with it will know easily.

Claims (1)

A first step of pulverizing the waste shell of the oyster or the waste treatment product of the main china;
Measuring a heavy metal concentration of soil to be stabilized;
A third step of determining a concentration of the powder obtained through the first step required to reduce the heavy metal concentration to a reference value in a concentration range of 1 to 10% by weight; And
A method of stabilizing heavy metal-contaminated soil using a waste shell of an oyster or a waste china, characterized in that it comprises a fourth step of mixing with the heavy metal-contaminated soil in accordance with the concentration determined through the third step.

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