KR100473516B1 - Manufacturing method for soil conditioner by using activated humic substances and clay minerals - Google Patents

Abstract

In the present invention, while fluoric acid (Fulvic acid) is induced in the state of glass among the corrosive substances by developing the self-oxidation function, the function of the catalyst of oxidative deodorization, the catalyst function to corrode organic material to the corrosive substance, It aims to make high quality soil improver by using active corrosive material with the function of improving soil.

To this end, acid is added to peat (peat) formed by depositing marine animals and plants such as marine diatoms, plankton, and seaweed, which have high concentrations of fulvic acid, and adjust the pH to 2.0-2.5. After induction into the glass state, hydrogen peroxide (H ₂ O ₂ ) and ferrous sulfate (FeSO ₄ ) were added to adjust the redox potential (ORP) to +350 to +400 mV, followed by reaction with peroxyfulvic acid. A mixture of powders of allophane-like minerals with high levels of activated minerals was used to produce an active corrosive, a chelate pulpate peroxide mineral complex, or Kago, Nagasaki, Japan. If necessary, the active corrosive material, which has been increased in the active wetted material from the decaying wetland, is increased by adding hydrogen peroxide and ferrous sulfate to increase the redox potential value, and then compost it as a soil improver. And supplied to the process or the soil to improve the soil.

Of particular note is that it has a superior mineral supply capacity for growing crops and soil microorganisms compared to general inorganic soil modifiers, and is widely used as a soil improver because it has excellent advantages such as improving cation exchange capacity (CEC) and enhancing metabolic activity of useful microorganisms. Expect to be.

Description

Manufacturing method for soil conditioner by using activated humic substances and clay minerals

The present invention Fulvic acid (Fulvic acid) and metal complex (金 屬 錯 ) Is induced in the free state and contains oxidase, which has its own oxidizing function, its function as a catalyst for oxidative deodorization, its catalytic function in the corrosive reaction of organic substances, and the supply of minerals to animals and plants. The present invention relates to a method for making a good soil improver using clay minerals containing a lot of activated minerals.

In Japanese Unexamined Patent Application Publication No. 5-345691, the excess corrosion sludge generated in the treatment process of organic wastewater using active corrosive substance was used as soil improving agent. Due to the loss of the activity, the activity was very low and the soil improvement effect was not practical.

In the case of corrosive material (peat, peat) mined from the Kago Recessed Wetland in Nagasaki Prefecture, Japan, the volcanic ash of the seaside discharged from the nearby Unzen active volcano Carcasses of marine animals and plants, such as marine diatoms, Plankton, and seaweeds, along with carcasses of aquatic plants, are deposited together and activated silicon (SiO ₂ ) and alumina (Al ₂ O ₃₎ ), Etc., acidified by the release of hydrogen ions (H ⁺ ) by water and hydrolysis reaction, and fulvic acid was induced into the free state, and the free state of fulvic acid was hydrogen peroxide (H ₂ O ₂ ) produced during the corrosive process of organic substances. Peroxyfulvic acid is produced by reaction with the active corrosive substance in the form of chelate fulb peroxide mineral complex by reacting with activated minerals in the coarse mineral. An active corrosive substance refers to a corrosive substance having a high reactivity among phenolic hydroxyl groups and carboxyl groups, and having excellent adsorptive substitution ability of cations or anions, and where such active corrosive substances are naturally released. Has been excavated in certain areas such as the Garago Low Wetlands in Nagasaki Prefecture in Japan, Gajio in Nagano Prefecture, Canada and Peru. The characteristics of the substances, the composition of chemical components, etc.地 人 地 館), The Latest Biowater Treatment Technology for the Food Industry, Livestock Research, and Livestock Research (畜産 の 硏 究 券 46 券 第 4 號 (1992 年) PP11-14 and (1993 pp. 72-74) and the like.

Such active corrosive has the following functions in soil.

1) It improves the breathability while improving water retention ability by developing the grain structure of soil.

2) Cation exchange capacity (CEC) capacity is increased to improve the storage capacity of nutrients.

3) Create high quality soil while improving the rate of corrosion of organic materials.

Active corrosive material has excellent mineral supply ability to soil microorganisms that corrode organic materials, and it promotes the growth of corrosive microorganisms, and has its own oxidation function to quinoneize polyphenol compounds, metabolites of corrosive microorganisms. It rapidly oxidizes to the water and improves the corrosion rate, and reacts with the minerals of the soil to become a chelate organic phosphate salt, and improves the grain structure of the soil to create high-quality soil with excellent water retention and breathability.

4) The bacteriostatic action of the soil occurs as a main apron by providing an environmental atmosphere for the growth of useful microorganisms useful for plant growth.

5) It buffers soil reactions such as soil acidification.

6) Helps carbon assimilation on green plants.

7) It has a heat insulation effect on the roots of crops to prevent cold damage.

8) Suppress phosphorus (P) fixation.

An object of the present invention is to make a good soil improving agent using the above-mentioned active corrosive material peat or carboxylic acid having high fulvic acid content and clay minerals with a lot of active minerals.

In order to achieve the above objectives, peat is produced by depositing carcasses of marine animals, plants and aquatic plants, such as marine diatoms, plankton and seaweeds, in coastal areas with high Fulvic acid content. The pH is adjusted to 2 or less by induction to induce fulvic acid to a free state, and then hydrogen peroxide (H ₂ O ₂ ) and ferrous sulfate (FeSO ₄ ) are added in equivalent weight equivalents to the redox potential ( ORP) is converted to peroxyfulvic acid in the range of + 350mV to + 400mV, and pulverized rhyolite or large volcanic ash powder or pumice of these minerals with high active minerals A powder or fly ash was heated and stirred at 90 to 100 ° C. in an acidic aqueous solution having a pH of 2.0 to 3.0 to convert it into an allophane, an clay of an amorphous function. Activated minerals Corrosive substances converted into fulbric peroxide and the like are mixed and mixed at an organic / inorganic material ratio of 0.6 to 1.2, and left to stand for at least 3 months to form artificially active corrosive substances in the form of mineral complex salts of fulbrate peroxide. The optimal mixing ratio of activated minerals and corrosive substances converted to fulb peroxide ranges from 0.8 to 1.0.

In the case of naturally active corrosive substances having a low ORP value of less than +250 mV, hydrogen peroxide (H ₂ O ₂ ) and ferrous sulfate (FeSO ₄ ) are added to reduce the ORP value from +350 mV to +400 mV. Adjust to increase activity.

The compost produced by supplying the above-mentioned mixture of active corrosive material, vermiculite, montmorillonite and cheonmaestone to the composting process is used as soil improving agent. 0.01 ~ 0.5wt% is mixed based on the total amount of inflow, and vermiculite, montmorillonite, and cheonmaeam are mixed in accordance with the purpose of use in the range that the concentration of organic substance in mature compost is 25wt% or more by-product fertilizer standard of the Ministry of Agriculture and Forestry. Determine.

Example 1

100 parts of dehydrated pig meal (water content 76%) discharged from pig farms was mixed with 25 parts of sawdust, 10 parts of peat, 10 parts of return compost, and 0.5 parts of activated corrosive soil in 1 part of natural rock. By day 25, maturity had reached 92%.

At this time, a good compost with a cation exchange capacity (CEC) of 80 meq / 100 g was produced.

Example 2

One month after sowing 150 kg of activated caustic soil per 100 pyeong, red pepper was sown, resulting in a 10-15% increase in yield compared to the general answer, and no plant diseases such as anthrax or leaf disease occurred.

As is apparent from the above description, activated corrosive soil has the effect of improving the soil and increasing the yield even by spraying a small amount on the soil, and even by supplying a small amount to the composting process, it can reduce the occurrence of odor and shorten the period of attachment. It is expected to be widely used as a composting process and soil improving agent because high quality compost can be produced with the effect of reducing the operating cost.

Claims (2)

PH is adjusted to 2.0 or less by adding acid to peat formed by depositing marine animal or plant or aquatic plants such as marine diatoms, Plankton, and seaweeds with high Fulvic acid content in peat. Induced fulvic acid to the glass state by adding hydrogen peroxide (H ₂ O ₂ ) and ferrous sulfate (FeSO ₄ ) to give a redox potential (ORP) value of + 350mV to + 400mV peroxyfulvic acid (Peroxyfulvic acid) Rhyolite or Dacite volcanic ash powder with high active minerals, or powder or fly ash obtained by pulverizing the minerals of these minerals is prepared in an acidic aqueous solution having a pH of 2.0 to 3.0. After heating and stirring at 90 ~ 100 ℃, it is converted into Allophane, an clay of amorphous function, and the minerals with activated minerals are mixed and mixed in the ratio of organic / inorganic materials in the ratio of 0.6 ~ 1.2 More than 3 months Artificially active corrosive materials prepared in the form of mineral peroxide salts of fulbrate peroxide, or naturally active corrosive materials with low ORP values, are added with hydrogen peroxide (H ₂ O ₂ ) and ferrous sulfate (FeSO ₄ ) to reduce the redox potential. A method of using an active corrosive material having an increased activity (ORP) of about +350 mV to +400 mV as a soil improver or a compost additive. The method according to claim 1, wherein the active corrosive material is mixed with about 0.01 to 0.5wt% based on the total amount of the organic material introduced into the composting process, and the vermiculite, montmorillonite, and stony rock ) Is a method of using the compost produced as a soil improver by mixing in a range of more than 25wt% organic material concentration in mature compost.