KR20120109262A - Composite organic fertilizers using sludge and natural ore, and process of the same - Google Patents

Abstract

PURPOSE: A composite organic fertilizer by using sludge and natural ore and a manufacturing method thereof are provided to promote activity of soil microbes and to modify acid soil. CONSTITUTION: A composite organic fertilizer by using sludge and natural ore comprise 40-85 parts by weight of dried deposition sludge which includes organic compound and 15-60 parts by weight of natural ore which is formed by calcium compound as a main component. A manufacturing method of the complex organic fertilizer using sludge and natural ore comprises the following steps: preparing deposition sludge, one or more natural ore among limestone and nature polymerization apatite and a bulk-forming agent(s10); forming organic material and usable microorganism from the deposition sludge by removing moisture contained in the deposition sludge(s20); forming micro powder by pulverizing the natural ore into particles with 500-1000 micro meters particle size(s30); and mixing 40-85 parts by weight of the dried deposition sludge and 15-60 parts by weight of the pulverized natural ore with 20-50 parts by weight of the bulk-forming agent(s40). [Reference numerals] (S10) Preparing raw material; (S20) Drying sludge; (S30) Pulverizing natural ore; (S40) Mixing

Description

Composite Organic Fertilizers Using Sludge and Natural Ore, and Process of The Same}

The present invention relates to a composite organic fertilizer using sludge and natural ores and a method for manufacturing the same. More specifically, the utilization of waste resources according to the use of natural ore as a raw material with sediment sludge located in the clean area dams and streams of rivers And using sludge and natural ore to reduce the manufacturing cost through the use of natural resources, to preserve the environment as an eco-friendly raw material, and to maximize the fast-acting effect that can be absorbed easily and sustainably provide nutrients over a long period of time. It relates to a complex organic fertilizer and a method for producing the same.

In general, fertilizers are used to cultivate land and to increase the productivity of the land and to promote the growth of plants. In consultation, the fertilizer is directly put into the soil and plants for the purpose of maintaining or enhancing the productivity of the soil or growing crops well. Nutrients that are not directly available to crops, while improving the physical chemistry of soils and promoting useful microorganisms, while converting nutrients that were not available to plants from soil into usable forms. It can be defined as a material that indirectly helps the growth of crops, such as reducing the toxicity.

The classification of fertilizers is not limited to the standard and changes in various forms according to various conditions. The factors of the change include productive factors such as resources and technology, types of crops, characteristics of agriculture, soil and It is classified as changing according to the time and regional differences such as environmental factors such as weather and economic or managerial factors.

Meanwhile, according to the Korean Fertilizer Management Act, fertilizers are classified into general fertilizers and special fertilizers. Specifically, ordinary fertilizers are inorganic fertilizers based on three elements: nitrogen, phosphoric acid, and potassium, which are the main components of fertilizer. , Inorganic phosphate fertilizer, inorganic potassium fertilizer), complex fertilizer, organic fertilizer, lime fertilizer, siliceous fertilizer, magnesium fertilizer, boron fertilizer, etc. Although it does not comply with a certain standard, it is classified arbitrarily as needed.

In addition to the above classification, fertilizers are divided into various types according to the manufacturing method and properties, manufacturing raw materials, main ingredients, chemical and physiological reactions, fertilization period, ingredient content, effects, and distribution structure. Chemical fertilizers and organic fertilizers that are divided according to the most widely used and have to fertilize a large amount every year, but the amount of plants absorbed by the fertilizer component is only about 15% of the problem.

Such chemical fertilizers, also called inorganic fertilizers, have the advantages of fast-acting effects and rapid mass production and relatively easy transportation and storage, while importing various raw materials needed to manufacture fertilizers. In addition, it is expensive due to the complicated manufacturing process and the use of raw materials, and the efficiency of the fertilizer is short, so that there is a problem in that a relatively large amount of fertilizer is consumed along with the difficulty of having to periodically fertilize it.

In addition, the use of chemical fertilizers accumulate excessively as the components that are not absorbed by the plant are fixed in the soil, causing soil acidification and inhibiting the activity of microorganisms in the soil. Therefore, it causes pollution or destroys the natural ecosystem, and excessive fertilizer causes serious problems such as concentration impairment in plants and excessive use of salts for a long period of time, which may cause disorders. .

Therefore, in recent years, the use of organic fertilizers, rather than the use of chemical fertilizers to reduce the fertility of the soil and pollute the surrounding environment, as well as the destruction of beneficial microorganisms in the soil, the organic fertilizer is organic matter is caused by the microorganisms in the soil During decomposition, energy is generated and nutrients, trace elements, amino acids, organic acids, and polyphosphates are produced and supplied, thereby accelerating the growth of crops, thereby reducing the acid indigenization of the soil.

In relation to the organic fertilizer as described above, Korean Patent No. 10-0399401 includes a mixing step of mixing the raw material; A primary fermentation step of fermenting the conventional aerobic and anaerobic microorganisms to the raw material blend for about 15 days at a high temperature of 70 ℃ to 80 ℃; A second fermentation step of fermenting the blended product having undergone the first fermentation step at room temperature again for about 10 days; A tableting process of compressing, cutting and tableting the compound fermented through the fermentation process as described above in a conventional manner; A coating process for coating the tableted formulation using zeolite, ocher soil or charcoal powder; And In the method of manufacturing an organic fertilizer comprising a drying step of drying the coated formulation, by adding the nitrogenous fertilizer in the secondary fermentation process, and then added to the nitrogen-fixed microorganisms to promote crop growth There is known a method for producing an organic fertilizer, characterized in that it contains an excess of nitrogen.

On the other hand, the recent research on fertilizers is a complete fertilizer, ie fertilizer for crop formation, free from the study of raw materials of agriculture as required in crop nutrition, fertilizer fertilization, physical and chemical aspects of soil. The situation is changing to the study of fertilizers containing nitrogen, phosphoric acid and potassium, which are the main components of.

In addition, it is important to increase the fertilizer concentration so that the fertilizer can be reduced while reducing the fare and storage cost per ingredient unit of fertilizer. Among such high-concentration fertilizers, phosphate fertilizers include single fertilizers such as superphosphate lime and calcined phosphate, and high concentration complex fertilizers such as ammonium phosphate. Recently, calcium metaphosphate and metaphosphate prepared by neutralizing metaphosphoric acid with lime ammonia Ammonium and the like are being developed.

In addition, organic fertilizers have a slow release effect, but have a disadvantage of low fertilizer content and free control of ingredient ratios. Therefore, organic fertilizers have high concentrations of inorganic fertilizers, which have characteristics of organic fertilizers to compensate for them. There is a need for the production of high concentration complex fertilizers that can freely change.

On the other hand, liquid fertilizers are attracting attention because they can be made at the same time because of the high concentration of liquid fertilizers. Among these liquid fertilizers, liquid ammonium is one of the highest concentrations of liquid fertilizers. It is also used as a raw material, but it is also used as a direct fertilizer because it contains 52% to 54% by weight of phosphoric anhydride without any loss due to volatilization. In addition, the liquid superphosphoric acid is a phosphoric acid made of metaphosphoric acid and polymetaphosphoric acid, containing an phosphate anhydride 76% by weight, the high concentration of fertilizers and liquid fertilizers are required as a new type of fertilizer.

In addition, since phosphoric acid and goto have a synergistic effect on crops, studies have been conducted to add goto to phosphate fertilizers. As a result, small and medium phosphorus ratio, mixed phosphorus ratio, and goto superphosphate have been manufactured and used as fertilizers.

However, as a raw material of phosphate fertilizer, mineral apatite is used. 90% of the world's production is used for fertilizer production, which requires 1.5 million tons of apatite annually in Korea, but all of the required amount is imported. In order to use phosphoric acid of apatite as a fertilizer, a chemical treatment process such as adjusting the molar ratio of calcium and phosphorus should be preceded, but there was a difficulty in removing or preventing environmental pollution sources. .

The present invention is to solve the above problems, by utilizing the sediment sludge from the dam of the dam or river located in the clean area while applying natural ore (limestone or natural polymerized apatite) to utilize the waste resources It is an eco-friendly fertilizer using raw materials of natural resources while minimizing manufacturing cost by reducing raw material cost, and it provides a composite organic fertilizer using sludge and natural ore that can preserve natural ecology and natural environment, and its manufacturing method. have.

In addition, the present invention improves acidic soils to neutral soils by limestone used as natural ores, promotes the activity of microorganisms in soil, promotes the decomposition of organic matter, improves the effectiveness of nutrients, and has high stability in air. It is to provide a complex organic fertilizer using a sludge and natural ore that can be easily stored because there is no alteration in the fertilizer and a method for producing the same.

In addition, the present invention is configured by applying a natural polymer phosphite, which is a natural ore, by changing all the various forms of phosphate to phosphate ions to enable the qualitative and quantitative analysis of phosphorus ions shorten the fermentation time, increase the nitrogen phosphate content according to the ratio control To increase the efficiency of fertilizers to maximize safety, to provide nutrients for long-term sustainability and to shorten the production time to provide a complex organic fertilizer using sludge and natural ore that can maximize the fast-acting properties and its manufacturing method It is for.

In addition, the present invention is a high-concentration complex fertilizer in which the nutrients of the fertilizer is accumulated from the raw material in the form of powder form a solid form of liquid fertilizer and molded fertilizer, so that it is easy to transport and storage, and mass production is possible, It is possible to prevent soil nitrogen fixation of soil and fertilizer while activating, and it is possible to supply to cultivation that is difficult to prepare, and complex organic fertilizer using sludge and natural ore that can facilitate the work and its manufacture It is to provide a method.

The composite organic fertilizer using the sludge and natural ore proposed by the present invention comprises 40 to 85 parts by weight of dried sediment sludge containing organic matter, and 15 to 60 parts by weight of natural ore formed mainly of calcium compounds.

The natural ore may be composed of calcined limestone, and the natural ore may be composed of a natural polymerized apatite which contains a large amount of nitrogen, calcium, and magnesium, including phosphoric anhydride, and is formed in a complex structure.

The natural ore is made of fine powder pulverized to a particle size of 500 ~ 1000㎛.

In addition, the water absorbent 20 to 50 parts by weight is further included to control the amount of residual water even after the deposition of the sludge and natural ore.

In addition, it is also configured to achieve a liquid composite organic fertilizer formed in a liquid state by mixing and fermenting 80 to 250 parts by weight of water with respect to 100 parts by weight of the complex organic fertilizer consisting of the sediment sludge and natural ore and water absorbent. It is possible.

In addition, 5 to 40 parts by weight of a molding raw material for solidifying the fertilizer and 5 to 35 parts by weight of a biodegradable polymer, and molded to have various shapes, based on 100 parts by weight of the composite organic fertilizer composed of the sediment sludge and natural ore and a water absorbent. It is also possible to configure to form a solid composite organic fertilizer formed in a solid state.

The method for producing a composite organic fertilizer using the sludge and natural ore proposed by the present invention is to prepare a natural ore and water absorbent of at least one of limestone and natural polymer apatite, including sewage sludge collected by collecting sludge deposited in a lake or river. Raw material preparation step; A drying step of removing water contained in the sludge in an amount of about 95% to 99% to form organic materials and microorganisms usable from the deposited sludge; A pulverizing step of pulverizing the natural ore in the prepared raw material to a particle size of 500 to 1000 μm to form fine powder; 40 to 85 parts by weight of the dried sludge and 15 to 60 parts by weight of the crushed natural ore are mixed with 20 to 50 parts by weight of the water absorbent to mix the raw materials.

Limestone of the natural ore is further formed by a firing step of firing for 30 to 120 minutes at a temperature of 600 ~ 1100 ℃ through a firing furnace.

In addition, the natural polymerized apatite of the natural ore is further comprises an analysis step of qualitative and quantitative phosphate anhydride to determine whether or not the natural ore is a natural polymerized apatite.

In addition, before the qualitative and quantitative analysis of the phosphate anhydride of the natural polymerized apatite, the method further comprises a sample preparation step of converting all phosphates of various forms into phosphate ions.

In the sample preparation step, distilled water, hydrochloric acid, nitric acid, perchloric acid, and concentrated sulfuric acid are sequentially dissolved in the natural polymerized apatite, followed by heating and evaporation, and distilled water is continuously added every time white lead occurs. Heating and evaporating thereafter, followed by reheating and evaporating hydrogen peroxide and distilled water, followed by a first production step of maintaining distilled water for 2 to 5 days; A second to dry in a hardened state through a process of completely evaporating until white sulfate does not occur after putting concentrated aqua regia, sodium nitrate, and potassium nitrate on a sample of the natural polymerized apatite which has passed the first manufacturing step Manufacturing step; A third production step of drying the hydrogen peroxide and distilled water into a sample obtained from the second production step and drying and drying it in a solidified state by heating and evaporating; ; Distilled water and aqua regia were added to the sample obtained through the third manufacturing step to evaporate, followed by a drying process, followed by drying by adding distilled water and hydrochloric acid to evaporate, and then maintaining distilled water for 20 to 30 hours. It comprises; step.

In addition, the raw material is mixed through the mixing step and the fermentation step of fermenting the mixture for 5 to 40 days, and separately collected while removing the precipitated solids generated in addition to the mixture fermented in the fermentation step to obtain a liquid mixture It is also possible to provide a liquid complex organic fertilizer comprising a step of, and the step of drying the liquid mixture obtained in the obtaining step to about 30 to 70%.

In addition, a fermentation step of mixing the raw materials through the mixing step and then fermenting the mixture for 20 to 60 days, a second grinding step of drying and grinding the mixture fermented in the fermentation step, and in the second grinding step A composition step of mixing 5 to 40 parts by weight of the molding material and 5 to 35 parts by weight of the biodegradable polymer with respect to 100 parts by weight of the pulverized mixture, and a molding step of forming a solid state by applying pressure to the mixture produced in the composition step. It is also possible to be made to provide a solid compound organic fertilizer.

According to the composite organic fertilizer using the sludge and natural ore according to the present invention and a method for producing the same, waste and natural resources that are difficult to process by applying sludge and natural ore deposited from the bottom of a dam or river as a main ingredient as raw materials It is an eco-friendly fertilizer that minimizes manufacturing costs by reducing raw material costs and prevents the fertilizer from becoming fixed to the soil, even after long-term contact with soil. And the effect of preserving the natural environment.

In addition, the composite organic fertilizer using the sludge and natural ores according to the present invention and the method for producing the same are neutralized acidic soils by neutralizing the acidic soil according to the composition of limestone in natural ores, thereby improving soil buffering action, organic acid, etc. By promoting the growth of crops and reducing the toxic effects of heavy metals, by promoting the microbial activity of the soil to help organic decomposition, improve the effectiveness of the nutrients, high stability in the air does not deteriorate during storage, fertilizer There is an effect that can be easily stored.

In addition, the composite organic fertilizer using the sludge and natural ore according to the present invention and the manufacturing method thereof is composed of natural polymer phosphate in natural ore as a raw material to increase the nitrogen phosphate content according to the ratio control to improve the efficiency of the fertilizer to maximize safety In addition, there is an effect that can maximize the fast-acting effect to shorten the time-effectiveness and production time to provide nutrients continuously for a long time.

In addition, the composite organic fertilizer using the sludge and the natural ore according to the present invention and the method for producing the organic acid is produced when the organic calcium is decomposed when the organic calcium is decomposed in the crop containing natural polymer phosphite in the sludge containing a large amount of organic Soluble is dissolved in and combined with the trace elements in the soil solution, so it is recrystallized as soluble complex salts are formed, which is not water-soluble, but soluble, maximizing sustainability to continuously provide nutrition to crops, and fertilization due to high concentration production delivers nutrition quickly. There is an effect that can maximize the quickness that can shorten the production time of crops.

In addition, the complex organic fertilizer using the sludge and natural ore according to the present invention and a method for producing the same is a high-concentration complex fertilizer that can be produced directly from the raw material in the form of powder, but incorporating the nutrients of the fertilizer in the form of liquid fertilizer and molded fertilizer The solid form makes it easy to fertilize a wide variety of crops, to mass produce, to transport and store easily, and to fertilize fertilizers even in difficult to cultivate crops. It can work.

1 is a block diagram showing a manufacturing method of an embodiment according to the present invention.
Figure 2 is a block diagram showing a method for producing a fertilizer composed of limestone in the natural ore in the present invention.
Figure 3 is a block diagram showing a method for producing a fertilizer composed of natural polymerized apatite as a natural ore in the present invention.
Figure 4 is a block diagram showing a method for producing a liquid fertilizer in the present invention.
5 is a block diagram showing a method for producing a solid fertilizer in the present invention.

Next, a preferred embodiment of the composite organic fertilizer using the sludge and natural ore according to the present invention and a manufacturing method thereof will be described in detail with reference to the accompanying drawings.

However, embodiments of the present invention may be modified in many different forms, the scope of the invention is not to be construed as limited to the embodiments described below. Embodiments of the present invention are provided to explain those skilled in the art to understand the present invention, the shape of the elements shown in the drawings and the like are shown by way of example in order to emphasize more clear description.

First, one embodiment of the composite organic fertilizer using the sludge and natural ore according to the present invention, comprises a sludge and natural ore.

The sediment sludge is a sediment containing a large amount of organic matter as one of the main raw materials of the present invention. Specifically, the sediment sludge is a corrosive which is introduced by running water, such as rainwater, from a lake in a clean area or from a corrosive soil around a river, and a microbial cell that decomposes it. Is generated by

The sedimentation sludge is generally deposited in lakes or rivers and placed on the water table, but depending on the environmental conditions, the water content is about 95 to 99%, except for water, with more than 60% organic matter and more than 20% naturally fermented microbial cells. It is composed.

The organic matter contained in the sedimentation sludge may be classified into entrapped organic matter that remains after the animal's fluid is not decomposed and corrosive matter generated after the animal's fluid is decomposed by the action of microorganisms.

The corrosive is a collection of various substances that are generally adsorbed on soil particles. The corrosive substance is brown or dark brown, and is formed of a chelating colloidal material having hydrophilic property and excellent cation adsorption ability. According to the difference, it is classified as Humin, Fulvic acid and Humic acid.

Here, humic acid is the main extract component which can be extracted from humus soil as a caustic fraction that is water insoluble under acidic conditions of less than pH 2 but soluble under higher pH conditions, and the color is dark brown or black. Fulvic acid, on the other hand, is a caustic fraction that is water soluble under all pH conditions and remains in aqueous solution after removal of humic acid by acidification, and the color is yellow or yellowish brown. Humin, on the other hand, is a caustic fraction that is water insoluble under all pH conditions including alkali, the color being black.

The constituents of the corrosive are composed of polymer polymers which are closely related to each other but are not completely identical, and there are differences in molecular weight, carboxyl, number of functional groups such as phenolic hydroxy, degree of polymerization, and the like.

In the above, humic acid is a complex and heterogeneous aromatic macromolecular mixture having aliphatic compounds forming crosslinks between amino acids, amino sugars, peptides, and aromatic groups, and fulvic acid contains functional groups and is heavily substituted with oxygen for aromatic and aliphatic structures. To form a mixture.

Since the sediment sludge is an organic aggregate consisting mainly of humic and fulvic acids as described above, their decomposition products by microorganisms, and decomposing microbial cells, the sediment sludge has sufficient potential value as an effective and excellent organic fertilizer component. .

Therefore, in the specification of the present invention, the term 'sedimented sludge' in the fertilizer according to the present invention and the method for producing the same is an organic aggregate consisting of humic acid and fulvic acid, their degradation products by microorganisms, and their degraded microbial cells. It is defined as meaning.

The deposited sludge is used as a raw material after drying to remove the contained water. That is, the sedimentation sludge is collected from lakes or streams, and then the moisture contained in the sedimentation sludge is dried through a drying apparatus so as to solidify it.

In drying the sludge, the drying apparatus may be formed to dehydrate the sludge using a centrifuge or the like, and may be formed to dry the sludge by supplying a heat source such as hot air or ultrasonic waves. It is also possible to form to dry by reaction of the said sludge using microwave.

The dehydration method using a centrifugal separator or a belt feeder in the drying apparatus has a limitation in drying the sewage sludge of high moisture content, and when the heat source such as hot air or ultrasonic wave is used, the particles of the sewage sludge are thin and dense. Since it is difficult to penetrate the structure and transfer the heat source, it is preferable to form it using microwaves, but the type of the drying apparatus is not particularly limited in the present invention.

The deposited sludge is made of 40 to 85 parts by weight based on the total weight of the fertilizer as a dry weight. Preferably, the deposition sludge is preferably configured to constitute 55 to 70 parts by weight.

The natural ore is a collection of minerals that can be obtained by naturally existing and mined in nature, and specifically, a calcium compound constituting calcium carbonate (CaCO ₃ ) is formed as a main component.

The natural ore is composed of calcium carbonate as a main component and consists of limestone which is sedimentary rock.

The limestone is a natural mineral also called limestone. In more detail, the limestone is generally a fine grained, bulky, unstructured rock, composed of a layer of the case when sandwiched between a dome and a stratum forming a lump of a coral reef or the like and a rock formation. It is formed in gray, and the impurity component is formed to have a dark gray color or black color. Here, the pure components of limestone contain 56% of calcium oxide (CaO) and 44% of carbon dioxide, but usually contain impurities such as magnesium oxide (MgO), iron oxide (FeO), and manganese oxide (MnO). .

The limestone is produced by sedimentation and fixed organically by organisms that secrete carbonates of carbonate at a relatively high pH where there is little ground sulphate supplied from land, or by inorganic chemical action directly in seawater. In addition, the limestone may be formed of debris of calcite debris and fossils, and is classified into calcite ludite of 2 mm or more, calcite arenaite of 1 to 2/16 mm, and calcite rutile of 1/16 mm or less, depending on the particle size. .

The limestone is formed by calcining, specifically, when calcined limestone is converted into calcium oxide as carbon dioxide is discharged, the calcined limestone exhibits strong alkalinity, and its weight is reduced by half. That is, the calcium oxide obtained by calcining the limestone reacts with water to undergo an extreme exothermic reaction (CaO + H ₂ O → Ca (OH) ₂ ), and then calcined according to strong alkalinity as calcium hydroxide. Treated limestone will exhibit strong alkaline properties.

Firing of the limestone is to be carried out for 30 to 120 minutes at a temperature of 600 ~ 1100 ℃ in the kiln. In this case, when the firing temperature is less than 600 ° C., the desired degree of firing may not be performed. When the firing temperature exceeds 1100 ° C., it may cause physical property change due to high temperature. Do.

Since the composition of the limestone as described above, the stability in the air is greater than that of other limes (for example, quicklime and hydrated lime), there is no deterioration during storage, so it is easy to store fertilizer and neutralizes the soil while neutralizing acid soil. It is possible to enhance the buffering effect and to increase the absorption of fertilizer components with the increase of the base substitution capacity.

In addition, the natural ore may be composed of a natural polymerized apatite formed of a complex structure while containing a large amount of nitrogen, calcium, and magnesium, including phosphate anhydride.

The natural polymerized apatite was similar to the lime carbonate in appearance, but it was known to the existing limestone to date, but in the present invention, it was analyzed by a new method to confirm that it is a new mineral, and then applied to fertilizer by powdering the natural polymerized apatite. It was made possible. That is, the natural polymerized phosphate is a polymerized phosphoric acid that is an inorganic polymer in mineral form by modifying a phosphate molecule having a polymer structure into a regular phosphate molecule to form a polymerizable calcium phosphate that could not be identified and quantified by conventional analytical methods. Calcium was quantified to allow the use of the above natural polymerized apatite.

In general, apatite is a kind of phosphate mineral, an important resource mineral present in nature and a compound in which phosphorus (P), which is present as a compound, is present as a calcium salt without being calculated in elemental state. Such apatite is an amorphous crystal and has various colors such as white, brown, yellow, and earth color, and it is difficult to distinguish it from limestone, and it is strongly permeable and phosphate anhydride exuded from guano is combined with iron and alumina. Iron salts become apatite, and they form deposits.

The water solubility, or solubility and insolubility of the ore is determined by the molar ratio of calcium and phosphorus contained. Specifically, when the molar ratio of calcium and phosphorus is 3: 2, the ore content is insoluble. If the molar ratio of calcium to phosphorus is less than 1.5, the solution is dissolved in citric acid or distilled water. For example, when the molar ratio of calcium and phosphorus is 1: 1, it has a solubility to be dissolved in citric acid, and when the molar ratio of calcium and phosphorus is 1: 2, it is water-soluble. Therefore, the existing tricalcium phosphate apatite can be fertilized directly on crops only after it has been chemically treated and changed to water soluble or soluble in water or citric acid.

The natural polymerized apatite has a specific gravity of 3.0 to 3.2, a hardness of 4 to 5 degrees, and an optical crystal system as a hexagonal tetrahedron. In general, crystals are rare and microcrystalline, but sometimes also granular ingots.

In addition, the natural polymer apatite can be dissolved in natural water. In other words, the natural polymer apatite is a porous residue like sponge due to partial dissolution of the surface in a humid place, calcium salt is almost dissolved, only the silicic acid residue is changed to a weak pumice designed to soil, tens of centimeters There is also a place where it melts and erodes.

The natural polymer phosphate is formed by dissolving by adding various solvents, and then heating and evaporating the sample to form various phosphates into phosphate ions to form a quantitative analysis of the polymerized calcium phosphate.

The solvent added in the sample pretreatment of the natural polymerized apatite is made by adding at least one of distilled water, hydrochloric acid, nitric acid, perchloric acid, sulfuric acid, hydrogen peroxide, aqua regia, sodium nitrate, potassium nitrate, and potassium chloride.

The normal calcium phosphate deposit of the natural polymerized phosphate is thermally denatured and complexed into polymerized calcium phosphate, wherein the polymerized calcium phosphate is formed as a primary compound by satisfying a common valence of each component, and then the primary compound is the same molecule. Or polymerized with other molecules to form higher order compounds.

The natural polymerized apatite is an organic substance carbonated by the heat-modifying action to replace calcium ions of the phosphate ore, and due to the recrystallization of calcium phosphate as condensation and polymerized calcium phosphate, the organic material that is inevitably mixed in the apatite is rare. Will appear.

The polymerized calcium phosphate is produced by electrolytic dissociation between molecules, and isomerism occurs when the higher-order compound is dissolved in a solution, and various isomers having different properties (for example, , Optical isomers, structural isomers, polymerization isomers, etc.) are present in the solution. Therefore, since the higher order compound contained in the natural polymerized apatite becomes an anion in a solution and the anion causes an isomerization while forming another compound, phosphorus was not detected by a physical analyzer using an existing analysis method. In the present invention, the phosphate molecule of the polymer structure is transformed into a phosphate molecule to enable the quantitative analysis of the polymerized calcium phosphate to form the natural polymerized apatite.

By constituting the natural polymerized apatite as described above, the residual phosphate can be dissolved due to the need of the plant and dissolved due to organic acid or acid rain and recrystallized into a soluble complex salt by adsorbing trace element ions of the soil. Therefore, as the plant can be dissolved and absorbed again, it is possible to prevent soil fixation and protect the surrounding natural environment in an environmentally friendly manner.

The natural ore (limestone, natural polymerized apatite) is composed of 15 to 60 parts by weight based on the total weight of the fertilizer. Preferably, the natural ore is preferably configured to form 30 to 45 parts by weight.

The natural ore is made of fine powder pulverized to a particle size of 500 ~ 1000㎛. When it is out of the range of the particle size of the natural ore, since the product value of the fertilizer to be produced is not properly mixed with the deposition sludge, it is preferable to grind within the range of particle size.

It further comprises 20 to 50 parts by weight of a water absorbent so as to control the amount of residual water even after the deposition of the sludge and natural ore. It is preferable to use the water absorbent in an amount of 25 to 60 parts by weight.

The moisture absorbent serves to lower the amount of the sewage sludge by absorbing the moisture, and in addition to the function of controlling the moisture, it maintains the voids in the maturation process.

The water absorbent may be formed by applying the most widely used sawdust, and may be formed to control the water content of the initial fermentation target by replacing with mature compost or mature fermentation having a relatively low moisture content It is possible.

In addition, the fertilizer of the present invention can be configured by adding the by-products, including the sediment sludge and natural ore and water absorbent. As the by-product material, vegetable by-products are used, such as wheat bran, rye-middler, a by-product of rye milling, rice bran by-products, gluten produced during corn starch production, and confectionery from baking and confectionery. It is desirable to.

When using the by-product raw materials should be used in an amount of 5 to 20 parts by weight based on the total weight of the fertilizer.

The sedimentation sludge is used as a main raw material, but as a main raw material, it is also possible to form a separate microbial fermentation agent by adding and adding a biotin having fermentation spawn.

When using the above-mentioned homeostasis, it is preferable that the amount used is formed using an amount of 3 to 8 parts by weight based on the total weight of the fertilizer.

The composite organic fertilizer of the present invention can not only form a composite organic fertilizer in powder form, but also form a liquid composite organic fertilizer in a liquid state, and form a solid composite organic fertilizer in a solid state. It is also possible.

The liquid composite organic fertilizer is mixed and fermented with 80 to 250 parts by weight of water with respect to 100 parts by weight of the composite organic fertilizer composed of the sediment sludge, natural ore and water absorbent, and is concentrated to a liquid state.

When the liquid composite organic fertilizer is used, since a large amount of organic matter is concentrated, it is possible to exhibit fast-acting effect in which a fertilization effect appears quickly.

The solid composite organic fertilizer is composed of 5 to 40 parts by weight of a molding material for solidifying the fertilizer and 5 to 35 parts by weight of a biodegradable polymer based on 100 parts by weight of the composite organic fertilizer composed of the sediment sludge and natural ore and a water absorbent. Molded to have a solid state.

The solid composite organic fertilizer may be formed of a round fertilizer having a small grain shape, and may be formed of a rod fertilizer formed to have a long diameter of 10 to 40 mm, and other useful forms of use. It is possible to mold to form a variety of shapes.

The molding material is used to form the fertilizer or rod fertilizer in the solid composite organic fertilizer, specifically, any ceramic material suitable for imparting moldability such as ocher, bentonite, clay, white clay, etc. may be used. Although inexpensive ocher and bentonite are preferred.

The biodegradable polymer plays a role of slowing down the effect of fertilizer, ie, providing sustained release of the active fertilizer component.

The biodegradable polymers are formed using degradable plastics that can be disintegrated or decomposed upon use and absorbed into a natural circulation cycle, thereby eliminating the problem of environmental pollution.

The degradable plastics include biodegradable plastics, biodegradable plastics and photodegradable plastics, but biodegradable plastics have a problem of being decomposed over an excessively long time. Since there is a problem of heavy metal contamination, it is preferable to form by applying biodegradable plastics.

The biodegradable plastics include polyhydroxy butyric acid, polysaccharide, polycaprolactone, polylactic acid, polyglycolic acid, natural polysaccharide, chitin, oil, and the like. do.

Biodegradable polymers that can be used in the present invention include natural polymers derived from plants such as cellulose, hemicellulose, pectin, lignin, and stored carbohydrates, such as starch, and chitin-based animals including shells of shrimp and crabs. It has a tensile strength of about 1,000 kg / cm 2 obtained by drying or heat-treating a highly viscous material obtained by mixing a chitosan acetic acid aqueous solution obtained by hydrolyzing one of the fine fibers or chitin and the like, and having sufficient strength even in a wet state. Translucent sheets, and the like, and biopolymers produced by microorganisms include polyβ-hydroxybutyrate, polyhydroxyalkanoate, D-gullufuronic acid and N-acetyl glucosamine, and hyaluronic acid, pullulan, Extracellular embryos such as xanthan gum, alginate, curdlan, dextran, levane, etc. May be mentioned polysaccharides, it can be given a variety of biological polymers such as poly-caprolactone, polyglycolic acid, polylactic acid, polydioxanone, poly anha deurayideu, poly ortho esters, phosphazenium, polypeptide.

In consideration of cost, meltability, and moldability among the types of the biodegradable polymers as described above, it is preferable to use polymers of polycaprolactone, thermoplastic starch, hyperline, diols and aliphatic dicarboxylic acids. Do.

Next, a manufacturing method for producing a composite organic fertilizer using the sludge and natural ore according to the present invention constituted as described above.

First, one embodiment of the composite organic fertilizer manufacturing method using the sludge and natural ore according to the present invention is a raw material preparation step (S10), sludge drying step (S20), and natural ore grinding step ( S30), and comprises a raw material mixing step (S40).

In the raw material preparation step (S10) to prepare a natural ore and water absorbent, including the sediment sludge as the main raw material, specifically collected and collected sediment sludge accumulated on the cutlery in the place of the lake or river in a clean area, the natural ore (Limestone, natural polymerized apatite) are collected and prepared, and a moisture absorbent is prepared as the sawdust or mature compost and fermented products are collected.

In the sludge drying step (S20) to remove the water contained in the sludge to about 95 to 99% to form organic and microorganisms available from the sludge as the main raw material from the raw material prepared in the raw material preparation step (S10), a separate Heat is applied through a drying device (for example, hot air, ultrasonic waves, microwaves, etc.) to dry for a sufficient time until solidified to remove the contained moisture.

In the natural ore grinding step (S30) to powder the natural ore forming a lump among the raw materials prepared in the raw material preparation step (S10), to form a fine powder with a particle size of 500 ~ 1000㎛ through a separate grinding device Grind until done.

In addition, in the case of applying the limestone as the natural ore, as shown in Figure 2, the calcining step of charging for 30 to 120 minutes at a temperature of 600 ~ 1100 ℃ through a firing furnace after charging the limestone, which is the natural ore into a firing furnace It further comprises (S35).

The calcining step S35 may be calcined before the limestone is crushed from the crushing step S30, or may be calcined after the limestone is crushed through the crushing step S30.

In the firing step (S35), the limestone is charged and calcined after raising the temperature of the calcining furnace to 600 ° C, rather than charging the limestone in advance before firing and heating it.

In addition, in the case of applying the natural polymerized apatite of the natural ore, as shown in Figure 3, by analyzing the natural polymerized apatite prepared in the raw material preparation step (S10) qualitative phosphate anhydride to determine whether the natural polymerized apatite. And it further comprises an analysis step (S28) to quantify.

The qualitative and quantitative analysis of phosphate anhydride in the step of analyzing the natural polymerized apatite (S28) is generally a physical method and a chemical method are used, and as a quantitative analysis of apatite containing 10% or more of phosphorus, It is preferable to analyze using analysis.

Here, the chemical analysis quantitative methods include magnesium pyrophosphate precipitation weight method, quinoline weight method, capacity method, in molybdenum furnace method, invanad molybdate method, etc. Among the above methods, the most accurate method is the magnesium pyrophosphate weight method, and thus the natural polymerization. It is desirable to use this method to identify apatite.

In addition, before the qualitative and quantitative analysis of the phosphate anhydride of the natural polymerized apatite, a sample preparation step (S21) for converting all the phosphates of various forms into phosphate ions is further made.

In the sample production step (S21) to produce the samples of the natural polymerized apatite sequentially four times, the first production step (S22), the second production step (S23), and the third production step (S24) And a fourth production step (S25).

In the first production step (S22), the natural polymerized apatite powder is dried and reduced, and dried at a sufficient time (about 3 hours) at about 110 ° C., followed by distilled water, hydrochloric acid (HCl), nitric acid (HNO ₃ ), and perchloric acid (HClO). ₄ ), Concentrated sulfuric acid (H ₂ SO ₄ ) is dissolved sequentially and then evaporated while heating, while heating and evaporation is repeated 3-7 times while continuously adding distilled water whenever white sulfate occurs in the process of evaporation by heating.

Then, while adding hydrogen peroxide and distilled water and reheating and evaporating until white sulfate occurs, distilled water is added and maintained for 2 to 5 days.

In the second production step (S23), a concentrated aqua regia, sodium nitrate (NaNO ₃ ), potassium oxalate (KClO ₃ ) is added to the sample of the natural polymerized apatite passed through the first production step (S22), and then sulfuric acid The product is evaporated to dryness until white smoke does not occur.

When the dark aqua regia, sodium nitrate, and potassium nitrate are added to the sample of the natural polymerized apatite and heated, it is dried while rotating with a tool (for example, a magnetic stir bar).

In the third manufacturing step (S24), the hydrogen peroxide and distilled water are added to the sample obtained from the second manufacturing step (S23) and dried in a solidified state while heating and evaporating.

After drying, as described above, distilled water, potassium chloride and aqua regia are added, and then dried to solidify again by evaporation.

In the fourth production step (S25), the sample obtained through the third production step (S24) is evaporated by putting distilled water and aqua regia, followed by a drying process, and then evaporated by adding distilled water and hydrochloric acid again. After that, the sample is prepared by maintaining it for 20 to 30 hours in a state of distilled water.

The magnesium pyrophosphate gravimetric method is a qualitative analysis of magnesium pyrophosphate powder from the natural polymerized phosphate with an X-ray diffractometer to determine whether it is a phosphate. Specifically, distilled water and concentrated nitric acid are added to a sample prepared from the natural polymerized phosphate. The sample was completely dissolved by heating, the solution was cooled, and the stock solution of ammonia was added to the solution until it became alkaline and turbid. Then, concentrated nitric acid was added and acidified, followed by addition of aqueous ammonia nitrate solution. When the yellow precipitate occurs by adding a settling to leave the day.

Discard the supernatant of the sample precipitated above, add the prepared ammonium nitrate solution, and leave it. After reprecipitation is completed, filter it with filter paper, wash it several times with ammonium nitrate solution, and completely filter. The yellow sample was dissolved and discharged under the filter paper. Thereafter, magnesium mixture was added to the test solution according to the alkali concentration, and when the precipitate was completely precipitated, the mixture was filtered and washed with an ammonia washing solution and then burned. The calcined sample was cooled and weighed to calculate the amount of phosphorus detection.

In the mixing step (S40), 40 to 85 parts by weight of the dried sludge and 15 to 60 parts by weight of the natural ore are mixed with 20 to 50 parts by weight of the water absorbent to mix the raw materials, thereby forming a fertilizer.

It is possible to provide a fertilizer which can be fertilized directly on crops by powdering without additional chemical treatment by providing a fertilizer comprising the sediment sludge and the natural ore (limestone, natural polymerized apatite) powder as an active ingredient as described above. .

In addition, the method for preparing a liquid complex organic fertilizer according to the complex organic fertilizer of the present invention includes a fermentation step (S50), an obtaining step (S60), and a concentration step (S70), as shown in FIG.

In the fermentation step (S50), the raw materials are mixed through the mixing step (S40), and then the mixture is fermented for 5 to 40 days. That is, in the fermentation step, the mixture is fermented for 5 to 40 days after mixing 80 to 250 parts by weight of water with respect to 100 parts by weight of the mixed organic fertilizer mixed with the sediment sludge and the natural ore and the water absorbent.

When fermentation of the mixture in the fermentation step (S50) is preferably fermented by mixing again 1-10 parts by weight of by-products (eg, bran, rye middleling, rice bran, gluten, confectionary, etc.).

In the obtaining step (S60) is obtained by obtaining a mixture fermented through the fermentation step (S50), that is, a liquid mixture, specifically, the mixture is fermented and divided into a precipitate solid and a liquid mixture, which is dehydrated The precipitated solids generated in addition to the mixture are removed and collected separately, so that they are used as compost and only a liquid mixture is obtained.

In the concentration step (S70) it is concentrated because the mixture of the liquid obtained in the obtaining step (S60). That is, in the concentration step (S70), the mixture in the liquid state is dried and concentrated until it becomes an amount of about 30 to 70%, and it is preferable to dry and concentrate until it becomes an amount of about 50%, after concentration Is packaged and used as a liquid complex organic fertilizer.

In addition, the method for producing a solid composite organic fertilizer according to the composite organic fertilizer of the present invention, as shown in Figure 5, the fermentation step (S55), the second grinding step (S65), the composition step (S75), and the molding step It includes (S85).

In the fermentation step (S55) is to mix the various raw materials in the mixing step (S40) and then ferment the mixture, 20 ~ mixture mixture of the sediment sludge and natural ore and water absorbent constituting the complex organic fertilizer Ferment for 60 days.

In the second grinding step (S65), the fermented mixture is dried and pulverized after the fermentation step (S55), and the pulverized mixture is dried again and then pulverized.

In the composition step (S75), 5 to 40 parts by weight of the molding material and 5 to 35 parts by weight of the biodegradable polymer are mixed with respect to 100 parts by weight of the mixture ground in the second grinding step (S65). More specifically, the blended raw material and the biodegradable polymer and 10 parts by weight of water are added to the ground mixture and mixed thoroughly. The biodegradable polymer is supplied in a period of continuous supply of nutrients after fertilization, that is, during the intended sustained shelf life. Therefore, it is preferable to select and apply the quantity and type suitably suitably.

The molding step is to form a solid state by applying pressure to the mixture produced through the molding composition step, by pressing a separate molding machine (for example, a high-pressure press, etc.) to form a round or rod shaped product and then packaged It is used as a solid compound organic fertilizer.

That is, according to the composite organic fertilizer using the sludge and natural ore according to the present invention configured as described above and a method for producing the same, by applying the sludge and natural ore deposited from the bottom of the dam or river as a main component to use as a raw material It is an environment-friendly fertilizer that minimizes manufacturing costs due to the reduction of raw material costs by utilizing difficult and unprocessed waste and natural resources, so that fertilizer does not adhere to soil even after long-term contact with soil. It is possible to preserve the natural ecology and natural environment, such as to prevent the disease.

In addition, the present invention by neutralizing the acidic soil by the composition of limestone in the natural ore to improve the neutral soil, so as to improve the soil buffer action, while promoting the growth of crops under the influence of organic acids, such as toxic effects by heavy metals It is possible to store fertilizer easily because it reduces the weight, promotes microbial activity of soil, helps organic decomposition and improves the effectiveness of nutrients, and does not deteriorate during storage due to high stability in air.

In addition, the present invention is to improve the efficiency of the fertilizer by increasing the nitrogen phosphate content according to the ratio control according to the composition of natural polymerized apatite of natural ore to maximize the safety, and to provide nutrients over a long period of time and production time It is possible to maximize the quickness to shorten.

In addition, the present invention is a natural sludge containing sedimentary sludge containing natural polymerized phosphate in the agricultural crops dissolve in organic acid produced when organic matter is decomposed to combine with the trace elements in the soil solution, so soluble complex salts are formed It is re-crystallized, and it is soluble, not water-soluble, so it maximizes the sustainability of continuously providing nutrition to crops. Do.

In addition, the present invention is a high-concentration complex fertilizer that can be produced directly from the raw material in the form of powder, but also concentrated in the fertilizer nutrients form a solid form of liquid fertilizer and molded complex fertilizer, so that it is possible to smooth fertilization on various kinds of crops In addition, it is possible to mass-produce, easy to transport and store, to fertilize the fertilizer smoothly even in difficult cultivation, as well as to facilitate the operation of fertilization.

In the above, a preferred embodiment of the composite organic fertilizer using the clean sludge and the polymerized calcium phosphate according to the present invention and a method for producing the same is described, but the present invention is not limited thereto. Various modifications can be made within the scope of the invention, which also belongs to the scope of the present invention.

Claims (14)

A composite organic fertilizer using sludge and natural ores, comprising 40 to 85 parts by weight of dried sediment sludge containing organic matter, and 15 to 60 parts by weight of natural ore formed mainly of calcium compounds.
The method according to claim 1,
The natural ore is a composite organic fertilizer using sludge and natural ore, characterized in that the calcined limestone.
The method according to claim 1,
The natural ore is a complex organic fertilizer using sludge and natural ore, characterized in that it comprises a natural polymeric apatite containing a large amount of nitrogen, calcium, magnesium, including phosphate anhydride and formed in a complex structure.
The method according to claim 1,
The natural ore is a composite organic fertilizer using sludge and natural ore, characterized in that the fine powder is composed of a pulverized to 500 ~ 1000㎛ particle size.
The method according to claim 1,
Complex organic fertilizer using sludge and natural ore, characterized in that it further comprises 20 to 50 parts by weight of a water absorbent so as to control the residual amount of water even after the deposition of the sludge and natural ore.
The method according to claim 5,
80 to 250 parts by weight of water is mixed and fermented to 100 parts by weight of the composite organic fertilizer consisting of the sedimented sludge and natural ore and a water absorbent, and then concentrated and formed in a liquid state. Fertilizer.
The method according to claim 5,
100 parts by weight of the composite organic fertilizer composed of the sediment sludge and natural ore and water absorbent 5 to 40 parts by weight of the raw material for solidifying the fertilizer, 5 to 35 parts by weight of the biodegradable polymer and molded to have a variety of shapes in a solid state Solid composite organic fertilizer using sludge and natural ore, characterized in that formed by.
A raw material preparation step of preparing a natural ore and a water absorbent of at least one of limestone and natural polymerized apatite, including sediment sludge collected by collecting sludge deposited in a lake or river;
A drying step of removing water contained in the sludge in an amount of about 95% to 99% to form organic materials and microorganisms usable from the deposited sludge;
A pulverizing step of pulverizing the natural ore in the prepared raw material to a particle size of 500 to 1000 μm to form fine powder;
40 to 85 parts by weight of the dried sludge and 15 to 60 parts by weight of the pulverized natural ore mixed with 20 to 50 parts by weight of the water absorbent to mix the raw material; sludge and natural comprising a Method for producing complex organic fertilizer using ore.
The method according to claim 8,
Limestone of the natural ore, the composite organic fertilizer manufacturing method using a sludge and natural ore, characterized in that it further comprises a calcining step for 30 to 120 minutes at a temperature of 600 ~ 1100 ℃ through a firing furnace.
The method according to claim 8,
The natural polymerized apatite of the natural ore, using a sludge and natural ore, characterized in that it further comprises an analysis step of qualitative and quantitative phosphate anhydride to determine whether or not the natural ore is a natural polymerized apatite. Compound organic fertilizer manufacturing method.
The method of claim 10,
A method for producing a composite organic fertilizer using sludge and natural ore, further comprising a sample preparation step of converting all of the phosphates in various forms into phosphate ions before qualitative and quantitative analysis of the phosphate anhydride of the natural polymerized apatite.
The method of claim 11,
The sample preparation step is to dissolve distilled water, hydrochloric acid, nitric acid, perchloric acid, concentrated sulfuric acid in the natural polymerized apatite in order to dissolve and then heated and evaporated, while continuously adding distilled water whenever white sulfate occurs. Repeatedly heating and evaporating, and then adding hydrogen peroxide and distilled water, followed by reheating and evaporating, followed by a first production step of maintaining distilled water for 2 to 5 days;
A second to dry in a hardened state through a process of completely evaporating until white sulfate does not occur after putting concentrated aqua regia, sodium nitrate, and potassium nitrate on a sample of the natural polymerized apatite which has passed the first manufacturing step Manufacturing step;
A third production step of drying the hydrogen peroxide and distilled water into a sample obtained from the second production step and drying and drying it in a solidified state by heating and evaporating; ;
Distilled water and aqua regia were added to the sample obtained through the third manufacturing step to evaporate, followed by a drying process, followed by drying by adding distilled water and hydrochloric acid to evaporate, and then maintaining distilled water for 20 to 30 hours. Composite organic fertilizer manufacturing method using the sludge and natural ore, characterized in that comprises a.
The method according to claim 8,
A fermentation step of mixing the raw materials through the mixing step and then fermenting the mixture for 5 to 40 days;
Obtaining step of separately collecting while removing the precipitated solids generated in addition to the mixture fermented in the fermentation step to obtain a liquid mixture,
Method for producing a liquid composite organic fertilizer using sludge and natural ores, characterized in that it comprises a concentration step of drying the liquid mixture obtained in the obtaining step to about 30 ~ 70%.
The method according to claim 8,
A fermentation step of mixing the raw materials through the mixing step and then fermenting the mixture for 20 to 60 days;
A second milling step of drying and grinding the mixture fermented in the fermentation step;
A composition step of mixing 5 to 40 parts by weight of the molding material and 5 to 35 parts by weight of the biodegradable polymer with respect to 100 parts by weight of the mixture ground in the second grinding step;
Method for producing a solid composite organic fertilizer using sludge and natural ore, characterized in that it comprises a molding step of forming a solid state by applying pressure to the mixture produced in the composition step.

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