KR980009205A - COMPOSITION BASED ON INORGANIC POROUS AND ORGANIC INDUSTRIAL WASTES AND MANUFACTURING METHOD - Google Patents

Abstract

The present invention relates to an inorganic porous body and an organic industrial waste as a subject and a method for producing the same. More particularly, the present invention relates to a method for producing inorganic porous body (waste produced in the production of lightweight foamed concrete by pulverizing waste of 1 mm size or coal fly ash Is reacted with caustic soda and then heat-treated) is mixed with waste acidic white clay, organic waste or organic waste discharged from a rice bran oil manufacturing plant, mixed with livestock manure, and then composted by a composting process The present invention provides a method of manufacturing an effective compost which can be recycled and contributes to solving environmental problems, and which can compensate for the disadvantages of the uneconomical condition of sawdust used as a moisture control agent and the long compaction period.

Description

COMPOSITION BASED ON INORGANIC POROUS AND ORGANIC INDUSTRIAL WASTE AND MANUFACTURING METHOD

The present invention relates to a compost with an inorganic porous body and an organic industrial waste as a subject. More particularly, the present invention relates to a compost produced by using an Autoclaved Lightweight Concrete (ALC) waste or a fly ash as a moisture regulator And a method for producing the same. The present invention also relates to a method for producing a compost,

The compost is used for the purpose of improving the acidic soil and the physico-chemical properties of the soil, as well as supplying the ineffective material. Fermented soybeans such as sawdust and fermentation accelerator are mixed and fermented for 1 ~ 2 months, and it is most commonly used.

However, since fermented compost has a bad working environment due to bad odor during manufacturing, it has difficulty in manufacturing. Second, since it uses sawdust as a moisture regulator, it is not only high in manufacturing cost but also difficult to purchase. Also, And it has a disadvantage that the period of the composting is long.

In order to overcome this problem, it has been actively attempted to improve the economical efficiency of compost and to solve environmental problems by using industrial wastes as raw materials. For example, there has been an attempt to utilize diapers or toilet paper among the municipal wastes as a moisture regulator.

However, such an attempt can improve the economical efficiency of composting, but it is difficult to apply it practically because there are many problems such as selection of waste to be used as a raw material of compost of municipal wastes.

The present invention provides an inorganic porous body and organic industrial waste-based compost which can contribute to the solving of environmental problems by recycling the waste under these circumstances and can complement the disadvantages of the non-admixture of sawdust used as a moisture regulator and the disadvantage It has its purpose.

It is another object of the present invention to provide a method of manufacturing a compost based on inorganic porous bodies and organic industrial wastes.

In order to accomplish the object of the present invention, the compost containing the inorganic porous body and the organic industrial waste is obtained by adding manure to a mixture of two materials, wherein the inorganic porous body is a moisture control agent and the organic industrial waste is a carbon source, And 50% to 70%, respectively, and then proceeding the composting process.

As the inorganic porous body, waste produced by a lightweight foamed concrete manufacturer is crushed to 1 mm or less, or coal fly ash produced in a thermal power plant or the like is reacted with caustic soda and then heat treated to be porous. In addition, the carbon source of the mineral water-based regulator is waste acidic clay, waste paper, or gum, which is discharged from a rice bran oil manufacturing plant.

This method is very useful not only in terms of utilizing various wastes but also in supplying Si (silicon) ions or calcium (Ca) ions, which are contained in ALC waste, to plants. (Si) ion and calcium (Ca) ion as well as N, P and K which are essential elements of fertilizer are also an essential element to be supplied to the plant. Therefore, the method according to the present invention is not only economical, It is very effective, and the practical application effect is shown in a concrete embodiment.

Therefore, when producing compost according to the present invention, it is very economical to use waste incineration not only from ALC manufacturers but also from coal-fired power plants and rice bran oil manufacturers at the cost of disposal, which is economical compared with the case of using sawdust.

In addition, calcium (Ca) ions contained in a large amount in the ALC serve as an accelerator for decomposing the cellulose of sawdust, so that even when mixed with sawdust, the manufacturing process can be shortened compared to the conventional compost manufacturing method.

The present invention will now be described in more detail with reference to the following examples.

A mixture of one or more of the wastes (waste acidic clay, waste paper dust, or gum) generated from the rice bran oil manufacturer into the inorganic porous article (the porous article obtained by reacting the pulverized product of ALC waste or the fly ash with caustic soda (NaOH) Of 6.5 to 8.0.

Mixture of this mixture alone or with sawdust is mixed with manure such as flour, millet, swine, and fowl to adjust the water content to 50 to 70%, and the compost is prepared by proceeding the composted reaction. To examine the effect of compost produced by this method, it was applied to radish and Chinese cabbage.

[Example 1]

1240 g of the ALC waste crushed to 1 mm or less and 860 g of the waste acidic clay were mixed with 3520 g of the shaft fraction, and composting was carried out by introducing air from the composting apparatus (sample 1)

[Example 2]

1,773 g of the ALC waste pulverized to about 1 mm and 225 g of waste paper dust were mixed and kneaded with 2000 g of the shaft fraction to prepare a ketobyte in the same manner as in Example 1 (Sample 2)

[Example 3]

591 g of the ALC waste crushed to 1 mm or less and 85 g of the gum were mixed and then mixed with 2000 g of the starch to obtain a compost (Example 3)

[Example 4]

5 g of the fly ash and 5 g of the solid sodium hydroxide solution are heat-treated at a temperature of 90 to 130 캜 using a blower dryer. The mixture was then removed from the vessel and pulverized to serve as pretreated fly ash samples.

10 g of pretreated coal fly ash and 100 ml of 2N sodium hydroxide solution were added and hydrothermal reaction was carried out at 90 ° C for a predetermined period of time using a constant temperature bath. 1860 g of a porous material was mixed with 250 g of waste paper dispersion, and then mixed with 3000 g of a shaft mixture. (Sample-4)

[Example 5]

591 g of ALC waste crushed to 1 mm or less and 85 g of waste paper dust were mixed and then mixed with 168.8 g of sawdust and mixed with 2000 g of a starch to obtain a compost using the same method as in Example 1 (Sample 5)

In order to investigate the effect of the compost on the actual crops and soils produced by the present invention, a sample 1 was submitted to the Chungnam Rural Development Administration and the results are shown in Table 1.

A simple theory on composting and the results in Examples 1 to 5 above are as follows.

Composting can be defined as a waste disposal method that can decompose and stabilize organic matter by the action of microorganisms under aerobic conditions and re-apply it to the soil without causing any side effects to the environment.

Aerobic composting is the decomposition of organic materials in the presence of air (oxygen). The main products are stable materials and CO ₂ H ₂ O, heat, and so on.

Anaerobic composting is the decomposition of organic matter in the absence of air (oxygen), and the products of metabolism include CH ₄ CO ₂ and low molecular organic acids. However, most of the composting is carried out under aerobic conditions because this method generates odors by the intermediate products such as organic acids.

The aerobic degradation process of organic matter is briefly shown below.

Aerobic microorganism

Organics + O ₂ Stable material _{+ CO 2 + H 2 C +} N O3 + S O 2- 4 + heat

In this way, organic matter is decomposed into a relatively stable substance by aerobic microorganisms, and CO ₂ and H ₂ O are produced in the decomposition process of the fluorine, and heat is generated. Therefore, since the temperature of the compost pile is increased, the activity of microorganisms is actively promoted and decomposition is further promoted. The microorganisms involved in composting are as diverse as in sewage and wastewater treatment, with bacteria, fungi and actinomycetes predominant.

As the composting reaction progresses, the compost material becomes microbiologically stable, becoming a homogeneous material, and the color becomes dark brown. Also, the humus content is increased and no odor is generated.

The results of the respective Examples (Examples 1 to 5) are shown in Table 1.

In the initial stage where the soluble substrate is abundant in the composting process, the temperature rises due to the aerobic decomposition of the carbon source, which causes the pathogen to die due to the elevated temperature. As shown in Table 1, the maximum temperature of each experiment was 59-64 ° C, indicating that the aerobic microbial activity was favorable, and the pH tended to be slightly higher than the initial one.

The criterion for determining the degree of aging of compost is not well known, but the degree of aging can be judged by changing the C / N ratio with the temperature change and the pH. Although the C / N ratio varies depending on the type of composted raw materials, composting is considered to be completed when the initial C / N ratio (initial C / N ratio) is usually 0.75 or less. As shown in Table 1, the ratio of (C / N) (final C / N) showed a ratio of 0.66 to 0.71 on the 20th day of composting in samples 1 to 4 in which no sawdust was added, The composting time was faster than that of the sample 5, and similar results were obtained at the Δ pH, which is another criterion of maturation. The pH is measured by diluting 2.5 g of sample with 10 ml of distilled water and measuring the pH. The diluted solution is then filled in a glass bottle, and the sample is decomposed for 24 hours at 55 ° C, . In the case of samples with less decomposition, organic acid is generated due to basic decomposition for 24 hours, and pH is lowered. The degree of decomposition of the compost material, that is, the degree of aging, can be known by the pH difference between before and after 24 hours. As described above, Sample 1 to Sample 4 showed 0.56 to 0.62 on the 20th day of the production, while Sample 5 to which sawdust was added showed 0.75 after 35 days from the start to show a longer composting period.

[Table 1] Test results of compost produced in Examples 1 to 5

Sample 1 was selected from the composts prepared by the above procedure and was tested in the Chungnam Rural Development Administration. The composition of the sample-1 and the heavy metal content are shown in Tables 2, 3 and 4, the contents of the respective treatments are shown in Table 5, and the test results are shown in Tables 6, 7 and 8. As shown in Table 2 and Table 3, N and K among the three components of fertilizer were 3.67% and 0.37%, respectively.

[Table 2] Component composition of sample-1

[Table 3] Classification criteria of Higgins' compost

And the heavy metal content is measured to confirm the stability of the sample-1. Since the heavy metals accumulate in the soil or play a critical role in the human body, their content is very important. As a result, Cu, Dd, Zn, and Pb showed low values compared with Higgins' classification criteria, and they were also excellent in terms of stability (see Table 4).

[Table 4] Heavy Metal Content of Higgins' Classification and Sample-1

[Table 5] Treatment contents of radish and Chinese cabbage (sample-1)

Table 6 shows the results of application of the sample-1 produced by the present invention to Chinese cabbage. The medium growth of Chinese cabbage was not significantly different between chemical fertilizer (Sample 1) and Sample 1 (Sample 2, 3 and 4), but was the highest 19.3 cm (length) in Sample 1 And 14 sheets and 10.0㎝ in leaf number and leaf width, respectively. Growth conditions before the harvest were compared with those of chemical fertilizer (Test 1), the length (length), the number of leaves, the number of leaves, Leaf width, etc., and the weight of living body was 581 ~ 586g, which was more than 20% higher than that of other test groups.

The results of field cultivation of radish are shown in Table 7. In the case of radish, no significant difference was observed in the medium growth, and the growth condition before harvest was higher than that of chemical fertilizer test area 1 by about 3 cm in length (length) in test pieces 2, 3 and 4 of sample 1 . The length of root was also the highest at 8.6 cm in Sample 1 and 3 and 4, and there was no difference except for Sample 2 in live weight.

[Table 6] Cultivation results of Chinese cabbage

[Table 7] Cultivation results of radish

In addition to the evaluation of the ineffectiveness of chemical fertilizer and sample-1, the contents of each component before and after the treatment of the soil treated with each fertilizer were measured to analyze the improvement effect of the soil. Table 8 shows that the test phosphate phosphorus and exchangeable cations and cation exchange capacity were increased. Therefore, the target -1 seems to have the effect of improving the soil.

[Table 8] Soil characteristics before and after treatment with radish and Chinese cabbage

In the examples, only the radish and the Chinese cabbage were shown to be effective, and the compost produced by the present invention would show excellent results even when used in a watercrop, a horticultural crop, a flower, a forestry crop, Of total sales.

INDUSTRIAL APPLICABILITY As described above, the compost according to the present invention has the advantage of contributing to the solving of environmental problems by recycling the waste, and can compensate for the disadvantages of the uneconomical condition of the sawdust used as a moisture regulator and the lengthy compaction period.

Claims (5)

Wherein the composting process is carried out after adding manure to a mixture of two substances, wherein the inorganic porous body is a moisture regulator and the organic industrial waste is a carbon source, and then the water content is adjusted to 50 to 70% A method of manufacturing a de-icing subject matter of a manufacturer waste. The method according to claim 1, wherein the organic industrial waste is at least one selected from waste paper dust, waste acidic clay, and gum originating from a rice bran oil manufacturing plant. The inorganic porous body and the organic industrial waste according to claim 1, wherein the inorganic porous body is one selected from ALC waste generated from an ALC system supplier and porous body obtained by hydrolyzing a fly ash discharged from a thermal power plant by reacting with caustic soda. A method for producing a compost. The method according to claim 1, characterized in that the addition of manure to the mixture of inorganic porous material and organic industrial waste additionally mixes the material with sawdust. A compost based on inorganic porous bodies and organic industrial wastes produced according to claims 1 to 4. ※ Note: It is disclosed by the contents of the first application.