KR101978561B1 - Soil conditioner using coal ash ball and manufacturing method thereof - Google Patents

Abstract

The method for producing a soil amendment agent using coal fly ash according to the present invention comprises: a pulverizing step of pulverizing coal ash and dredged soil separately using a crusher; feeding and mixing the coal ash and the dredged soil having been subjected to the pulverizing step to a mixing hopper; Mixing the mixed raw materials with a coal fly ash in a recirculating machine; firing the fly ash ball having passed through the forming step in a firing furnace; and applying a zero-valent iron solution to the fly ash obtained through the firing step to produce a soil improver The method comprising the steps of:

Description

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a soil improvement agent and a method for producing the same,

The present invention relates to a soil conditioner and a method of preparing the same, and more particularly, to a soil conditioner for improving soil in which salts are accumulated due to the use of chemical fertilizers and a method for producing the soil conditioner.

In general, good soil requirements for plant support, good nutrients, and water supply should have adequate permeability, water retention, and bending strength.

However, when fertilizing chemical fertilizers in crops and the like, the salt accumulation occurs rather unfavorably, and the salt accumulation (accumulation) is lower in the upper layer of the soil in the dry and semi-drying zone where the rainfall is small and the evaporation amount is large And there is a phenomenon in which salts are accumulated on the surface layer due to a large amount of salt rising due to evaporation.

The management of salt accumulation during the cultivation of the cabbage in the facility house is one of the series problems that are difficult to solve as the series becomes longer. As for the house cultivation, the crops are grown intensively in the facility compared to the non - cultivation, and the chemical fertilizer and livestock manure are many, so that most of the nutrients are left in the soil and the salt accumulation occurs. In the house condition, which is not influenced by rainfall, the movement of water from the surface to the basement is weak, and the water moves up and down in the soil layer by the irrigation water, so that the leaching of fertilizer nutrients in the soil is decreased and remains in the soil. As the water moves up and down in the soil layer, the salts contained in the soil layer accumulate on the topsoil, causing problems of salt obstruction.

In plantation cultivation areas, cropping is frequently occurred in a closed environment, and excessive use of high-concentration chemical fertilizer and composting of livestock complements cropping.

Such salt accumulation inhibits the growth of crops and causes a decrease in yield and quality. The major components involved in salt concentration increase are NO ^{3 -} , Cl ^- , and SO ₄ ^2- , and salt defects should be taken into consideration when using a large amount of a substance containing these components. Farmers continue to increase their fertilization to further absorb nutrients, which in turn causes a vicious cycle in which soil salt concentrations become higher, and nutrients can accumulate in the soil and have a detrimental effect on the environment.

The salt removal method can reduce the salt concentration by the method of flounder, the inversion of the soil surface and the soil, but it is necessary to treat the soil improvement agent appropriately in order to increase the effect. Soil modifiers are used to improve the physical and chemical properties of soils to suit plant growth. Bentonites, zeolites, and pearlites have been used to improve soil chemistry defects.

On the other hand, in the case of thermal power generation, which accounts for more than 60% of domestic electricity production, coal ash generated after coal-fired power generation is also increasing every year.

As such, coal ash generated after thermal power generation is recycled as cement raw material, concrete admixture, and light aggregate considering problems of environmental pollution and disposal cost, but a considerable number of such coal ash is still being buried.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a method for improving salt accumulation and improving a root growth environment by using coal as a byproduct generated from a thermal power plant.

The method for producing a soil amendment agent using coal fly ash according to the present invention comprises: a pulverizing step of pulverizing coal ash and dredged soil separately using a crusher; feeding and mixing the coal ash and the dredged soil having been subjected to the pulverizing step to a mixing hopper; Mixing the mixed raw materials with a coal fly ash in a recirculating machine; firing the fly ash ball having passed through the forming step in a firing furnace; and applying a zero-valent iron solution to the fly ash obtained through the firing step to produce a soil improver The method comprising the steps of:

The method may further include, after the mixing step, transferring the blended raw materials mixed in the mixing hopper to the blending mill, and then mixing and grinding the blending raw materials in the blending mill.

In the pulverizing step, coal ash and dredged soil are pulverized to a size of 1 mm to 10 mm.

Further, in the step of mixing and pulverizing the compounding materials, the coal material and the dredged soil are pulverized to 100 mu m or less.

The mixing ratio of the coal ash and the dredged soil is 80:20 (w / w,%).

In addition, in the step of preparing the soil amendment agent, a zero-valent iron solution is coated on a fly ash ball, and preferably 0.05% NaBH ₄ solution is prepared by adding 1% of zero valent iron powder of 1 μm or less.

Further, the firing step is characterized in that the firing is performed at 800 DEG C or higher.

According to the present invention, there is provided a soil improvement agent capable of improving salt accumulation and improving root growth by recycling the coal ash generated in coal-fired power generation.

1 is a view showing a process for producing a soil conditioner according to the present invention,
FIG. 2 is a photograph showing the soil conditioner prepared by the present invention,
FIGS. 3 to 5 are graphs showing the results of soil analysis after fertilizing the soil improver of the present invention and cultivating the soil,
6 to 8 are diagrams showing the heat-growing state after fertilizing the soil improver of the present invention and cultivating it,
FIGS. 9 to 11 are graphs showing the results of analyzing the components of the body after applying the soil conditioner of the present invention to the soil and cultivating the soil
FIGS. 12 and 13 are diagrams showing the change of the salt material (phosphoric acid) in the soil by treating the soil conditioner of the present invention with agrochemicals in which salts are accumulated by overdosing.

Hereinafter, a method for producing a soil conditioner using coal fly ash according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing a process for producing a soil conditioner according to the present invention, and FIG. 2 is a photograph showing a soil conditioner prepared according to the present invention.

The method for producing a soil amendment agent using coal fly ash according to the present invention comprises: a pulverizing step of pulverizing coal ash and dredged soil separately using a crusher; feeding and mixing the coal ash and the dredged soil having been subjected to the pulverizing step to a mixing hopper; A step of sintering the mixed raw material and molding the sintered coal ball into a spherical shape having a predetermined size in a recycler; firing the coal fly ball having passed through the sintering step in a sintering step; The method comprising the steps of: Hereinafter, the manufacturing process will be described in more detail.

In the manufacturing process of the soil modifying agent using the coal fly ash according to the present invention, the coal and dredged soil are individually pulverized.

The coal ash is the product that coal burns and remains in the coal-fired power plant. The bottom ash is loaded on the bottom of the boiler, and the fly ash is transported out of the boiler together with the flue gas discharged from the boiler. ).

The coal ash left after combustion in the thermal power plant is sent from the coal ash storage hopper 100 to the cutter mill 110 and crushed to a size of 1 mm to 10 mm, preferably 1 mm to 5 mm, And is pulverized to a size of about 5 mm in the actual process.

The dredged soil is obtained by draining a muddy soil or the like accumulated in a river, a lake, and the sea by a pump. The dredged soil is first dried to a water content of 5% or less, and then the dredged soil stored in the dredged soil storage hopper 200 is removed through a stone separator 210 Is first pulverized to a size of 1 mm to 10 mm, preferably 1 mm to 5 mm by using a cutter mill 220, and pulverized to a size of about 5 mm in an actual process. In the present invention, the pulverizer 220 used in the primary pulverization is not shown in the drawing, but the raw material is charged between the rotary drum cutter and the stationary cutter to be pulverized, and the particle size of the pulverized raw material is controlled by the outlet screen.

In the present invention, the pulverized coal and the dredged soil are pulverized in roughly the same roughly 5 mm in the first roughness, and the mixing ratio is improved in the mixing process to be described later.

The pulverized coal ash and the dredged soil as described above are respectively sent to separate hoppers and then conveyed to the mixing hoppers 400 by respective feeders. The coal and dredged soil are mixed at 80:20 (w / w,%) Mix. In the mixing hopper 400, coal is mixed with dredged soil using a screw in a dry state without adding water. The thus-blended raw materials are fed to a mixing and crushing machine 500 and subjected to a mixing and pulverizing process.

In the present invention, the mixed pulverizer (500) is self-pulverized by using high-speed vortex of air and vibration resulting from high-frequency pressure fluctuation to process ultrafine powder particles. The rotor having a sawtooth shape is rotated at a high speed, The raw material passing between the gaps is crushed by the high-speed vortex formed between the gaps.

As described above, in the present invention, the coal and the dredged material pulverized in the first roughness in the similar size are mixed and pulverized to less than 100 탆 in the mixed pulverizer 500. In the mixed pulverization process, the coal material serves as a sanding agent for viscous dredged soil, By crushing the dredged soil, the degree of differentiation of the dredged soil is improved and the mixing ratio is improved.

In the present invention, the blending raw material after the mixing and pulverizing process is stored in a blending raw material storage tank (not shown) and then sent to the molding storage hopper 700 for the molding process. In the present invention, The pipe is installed and pneumatically conveyed to the forming storage hopper 700. More specifically, the blend material is transported from the blend stock tank to the silo 600, and then is transported from the silo 600 to the molding storage hopper 700 using an air compressor. As described above, in the compounding material storage tank, the raw material is transferred to the pneumatic pressure through the transfer pipe rather than the open conveyer belt, thereby preventing generation of scattered dust and loss of raw materials.

Then, in the forming storage hopper 700, the raw material for forming is subjected to a molding process for molding into a sphere for firing. In the molding process, first, a certain amount of water is added to the molding mixer 750 so that the molding material is mixed with the proper viscosity while being mixed with the molding material so that the molding can be well performed. do. The compounding material is kneaded by adding water and kneaded. The kneaded material is cut into a predetermined size in an extruder and then discharged. The kneaded material is then formed into a coal fly ash having a diameter of about 5 mm or less by a pelletizer (800).

The coal fly ball formed in the circulating unit 800 is sent to a rotary kiln 900 after being dried and subjected to a firing process at a temperature of 800 ° C. or more (800 ° C. in the actual process) for about 10 minutes in the firing furnace 900 do.

Then, after the firing process, air cooling is performed, and then a step of coating zero valence iron on the coal fly ball is performed. In this step, the zero valent iron solution is coated on the coal fly ball. Specifically, the zero valent iron solution is prepared by adding 1% of zero valent iron powder (less than 1 μm) to the 0.05% NaBH ₄ solution. The zero valent iron solution thus prepared is sprayed onto coal fly balls and coated to prepare the soil conditioner of the present invention.

In order to examine the effect of the soil amendment agent of the present invention, 400 g-Fe / 10a (Ar) was applied to the soil based on the iron content, and the plant was cultivated for 30 days after fertilization.

FIGS. 3 to 5 are diagrams showing soil analysis results after experiments, respectively, showing the contents of soil-exchangeable calcium, boron and iron, respectively. As shown in the drawing, the exchangeable calcium content was slightly increased and the contents of trace element boron and iron were increased about 4 times and 0.5 times, respectively, when compared with the control. This means that the fertility of the soil is improved, and all of the increased elements are the result of providing a very beneficial environment for the soil with the materials contained in the materials used for the remediation.

FIGS. 6 to 8 are diagrams showing the growth state of the watermelon after the experiment, respectively, showing the length, weight and chlorophyll content of the watermelon.

The length of heat harvested after cultivation was compared between roots, leaves and stems. As a result, it was found that the growths of the roots were improved about 20% and 10%, respectively. Production (weight) was increased about 2 times in roots and 30% in leaf + stem compared with control. This result is attributed to the increase of chlorophyll content by 30%. As the content of boron and iron increases, the amount of chlorophyll and nutrient is increased and the production of heat is increased.

In addition, the body components of the harvested heat rice were analyzed and the results are shown in Figs. 9 to 11. Fig. 9 to 11 show the contents of macronutrients, boron and iron in the heat-treated rice, respectively. As a result of analyzing the components of the harvested heat, the contents of TN, TP and CaO were increased as compared with those of the control, and the content of boron and iron And the quality of crops was improved. This increase in body composition was provided by coal ash for T-N, T-P and CaO, and boron and iron as a beneficial environment for improvement of crop growth by the influence of liquid ferrous iron coated on coal balls.

On the other hand, Figs. 12 and 13 respectively show the effective phosphate of the soil and the phosphate of the soil solution. As shown, the initial effective phosphoric acid concentration of the soil was 1,203 mg / kg, which was reduced by about 96% (70 mg / kg) by the soil remediation agent of the present invention. Phosphate phosphorus in soil solution extracted from soil was decreased by about 90% from 0.7 mg / L at initial 7 mg / L. Therefore, the soil amendment agent according to the present invention was found to be effective in reducing the salts (phosphoric acid) in the soil when treated with agrochemicals containing salts by the overage of chemical fertilizers.

As can be seen from the above results, the soil treatment of the soil amendment agent developed in the present invention improves the fertility of the soil to improve the fertility, and proved to be an excellent material capable of promoting the growth of the soil. In addition, it has been proved to be a useful material to improve the unfavorable environment through the stabilization of phosphoric acid when it is treated with salt - accumulated soil.

Therefore, it is expected that the soil amendment agent according to the present invention will be able to replace the chemical fertilizer and win the fertilizer that can improve the growth of crops cultivated in accordance with the recycling purpose of resources.

Although the present invention has been described with reference to the preferred embodiments, the present invention is not limited to this. The low concentration of coal ash contains a large amount of nutrients such as Ca, Mg and K and a milky nutrient such as Fe, Mn and B, The present invention is not limited thereto but may be variously modified within the scope of the present invention as set forth in the following claims It will be readily understood that modifications are possible.

100: coal ash storage hopper 110: crusher
200: Dredged soil storage hopper 210: Stone separator
220: Grinder 400: Mix hopper
500: Mixing mill 600: Silo
700: forming storage hopper 750: forming mixer
800: Circulation machine 900: Firing furnace

Claims (9)

A pulverizing step of pulverizing coal ash and dredged soil separately using a pulverizer,
Transporting the coal material and the dredged soil that have been subjected to the pulverizing step to a mixing hopper and mixing them;
Mixing the mixed raw materials with each other and molding them into fly ash balls in a circulating machine,
Firing the coal fly ball having passed through the forming step in a firing furnace;
And coating the coal fly ball having been subjected to the sintering step with a zero valent iron solution to prepare a soil remediation agent,
Further comprising the step of transferring the blended raw materials mixed in the mixing hopper to the blending mill after the blending, and then mixing and grinding the blending raw materials in the blending mill,
In the pulverizing step, coal ash and dredged soil are ground to a size of 1 mm to 10 mm,
In the step of mixing and pulverizing the blended raw materials, pulverized coal and dredged soil are pulverized to 100 탆 or less,
The zero valent iron solution is prepared by adding a zero valent iron powder to a NaBH ₄ solution,
Wherein the zero valent iron solution is prepared by adding 1% of a zero valence iron powder of 1 탆 or less to a 0.05% NaBH ₄ solution. delete delete delete The method according to claim 1,
Wherein the mixing ratio of the coal ash and the dredged soil is 80:20 (w / w,%). The method for producing a soil improving agent for improving plant growth environment using coal fly ash. delete delete The method according to claim 1,
Wherein the sintering step is performed at a temperature of 800 DEG C or higher. A soil ameliorating agent for improving plant growth environment using coal fly ash produced by the manufacturing method according to any one of claims 1, 5, and 8.

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