KR20160033371A - Organic slow release fertilizer manufacturing methods - Google Patents

Abstract

The present invention relates to a manufacturing method of organic slow-releasing fertilizer and, more specifically, to a manufacturing method of organic slow-releasing fertilizer, capable of providing the fertilizer of proper elements per plant by using natural ingredients and forming organic fertilizers per element. The manufacturing method comprises: a crushing step for crushing as a powder by a crusher; a hydrolysis step for liquefying as a first fertilizer mixed liquid phase by inducing a hydrolysis reaction; a precipitation and separation step for separating a first fertilizer liquid phase; a first extraction step for individually extracting each of the first fertilizer liquid phases into the liquid phases of nitrogen, phosphorus, potassium, calcium, magnesium, and sulfur; a second extraction step for producing a second fertilizer mixed liquid phase by treating the same with fermented degradation, and individually extracting each of the second fertilizer liquid phases into the liquid phases of nitrogen, phosphorus, potassium, calcium, magnesium, and sulfur; an immersing step for immersing each of the nitrogen phase, the phosphorus phase, the potassium phase, the calcium phase, the magnesium phase, and the sulfur phase in a porous particle, and drying as a porous fertilizer particle; and a coating step for coating a coating member.

Description

Organic slow release fertilizer manufacturing methods

The present invention relates to a method for producing an organic slow-release fertilizer, and more particularly, to a method for producing an organic slow-release fertilizer, which comprises 12 essential nutrients necessary for plant growth, that is, N, P, K, Ca, Mg, S, Fe, B, Mo, and Zn by an element in an organic manner.

Generally, fertilizer is used to feed edible plants and ornamental plants with nutrients, and nutrients are supplied to the plants as nutrients dissolved by water or moisture.

Such fertilizers can be classified into slow-release fertilizers, chemical fertilizers or organic fertilizers. Chemical fertilizers and slow-release fertilizers are made of chemical materials such as chemical fertilizers. When they are provided as nutrients to edible plants, they acidify the soil, And the like.

In addition, there is a problem in that, if a person consumes the edible plant produced according to the soil contamination, the contamination component is absorbed by the human body and causes various diseases,

In order to solve this problem, it is possible to prevent environmental pollution by mixing organic fiber fertilizer such as plant fiber such as manure, straw, fish and sawdust into the soil.

However, since the production environment of nutrients and composts of feed varies depending on the plant, or the stock and grain, fish by-products, and sawdust depending on the condition and environment of the season and livestock, the nutrients required for each edible plant There is a problem that not only good quality edible plants can be produced but also edible plants of different quality are produced at different cultivation periods.

In addition, when pathogens are contained in the compost, there is a problem of providing a harmful environment that is lethal to edible plants.

In addition, since edible plants of different quality are produced at every cultivation time, there is a problem that reliability can not be secured for consumers since it is not possible to supply safe and high quality edible plants to consumers equally.

In addition, such conventional compost has a problem in that a bad odor is always generated and the cultivation environment is poor, and it is difficult to store and transport for a long period of time.

Disclosure of Invention Technical Problem [8] 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 and a device for preventing the above- N, P, K, Ca, Mg, S, Fe, Mn, Cu, B, B, C and D in the edible plant by a predetermined extraction process, Mo, and Zn in the form of granules by element, thereby providing fertilizer of the elements suitable for each plant. The object of the present invention is to provide a method of manufacturing an organic slow-release fertilizer.

It is another object of the present invention to provide a method for producing an organoleptically-effective slow-release fertilizer, which is capable of providing a gradually and continuously nutrient supply to a plant for a long time by treating the plant in the form of fertilizer granules by element.

It is another object of the present invention to provide a method for producing an organic slow-release fertilizer for each element, which comprises impregnating porous nutrients with essential nutrients for each element to produce an organic solid fertilizer to facilitate storage and transportation for a long period of time.

It is another object of the present invention to provide a method for producing an organic slow-release fertilizer for each element, which can safely grow and manage the pathogenic fungi according to organic farming, since essential nutrients for each element can be produced individually.

According to the above object, the present invention provides a method for producing an organic slow-release fertilizer; A disintegration step in which the shell and the dead fish or blood, the bone meal, the dead sea minerals, the egg shell and the natural gypsum or the shell shell, and the dolomite are dried for a predetermined period of time and are separately crushed into powder in a crusher in order to maximize the surface area ; Each of the pulverized powders and the hydrolysis solvent such as citric acid or acetic acid is contained in a plurality of individual mixing vessels and is sealed to induce a hydrolysis reaction at a room temperature for a certain period of time to produce nitrogen, phosphorus, potassium, calcium , A first fertilizer mixed liquid containing magnesium and sulfur; The first fertilizer mixture liquid of nitrogen, phosphorus, potassium, calcium, magnesium and sulfur liquefied in the hydrolysis step is precipitated for a predetermined period of time to remove residue and hydrolysis residues to remove the residues and residues, and then to separate the first fertilizer liquid phase A precipitate separation step; A first extraction step of separately extracting each of the first fertilizer liquid phases into liquid phase of nitrogen, phosphorus, potassium, calcium, magnesium and sulfur by separating the specific gravity using water; The residue is mixed with at least one of microorganisms and enzymes and treated with fermentation decomposition for a certain period of time to produce a second fertilizer mixed liquid phase. The second fertilizer mixed liquid phase is heated to a high temperature to be concentrated and then filtered with a high- A second extraction step of separately extracting liquid phases of nitrogen, phosphorus, potassium, calcium, magnesium and sulfur; Mixing the respective nitrogen liquid phases extracted in the first and second extraction steps, mixing the phosphorus phases extracted in the first and second extraction steps, mixing the respective phosphorus liquid phases extracted in the first and second extraction steps, Mixing the respective calcium liquid phases extracted in the first and second extraction steps, mixing the respective magnesium liquid phases extracted in the first and second extraction steps, and extracting the magnesium liquid phases extracted in the first and second extraction steps And the mixture is heated at a high temperature for a certain period of time in the form of a porous material such as zeolite, pearlite or talc in each individual container to form the nitrogen liquid phase, phosphorus phase, potassium liquid phase, calcium liquid phase, magnesium An impregnation step of impregnating each of liquid and sulfur liquid phases, and drying the porous liquid with fertilizer granules; Wherein the impregnated porous material body comprises a vegetable oil including linseed oil, soybean oil, and tung oil (flow wood oil) on the outer surface thereof, and a combination selected from at least one of clay, talc, diatomaceous earth and adsorbed silica powder And a coating step of coating the mixed coating member.

Further, it is preferable to further include repeating the step from the crushing step to the coating step in order to produce the mineral grains using the natural salt and the phyllite having the salt removed therefrom.

Here, the coating step may include mixing the exposed surface of the porous body fertilizer granules with the powdery curing agent such as starch and clay, clay, or diatomaceous earth to be coated on the exposed surface before the impregnated porous body fertilizer granules are dried.

The present invention relates to a method for preventing or treating osteoporosis, osteoporosis, osteoporosis, osteoporosis, osteoporosis, oyster shell, oyster shell, natural gypsum, dolomite, N, P, K, Ca, Mg, S, Fe, Mn, Cu, B, Mo and Zn as nutrients in the form of granules. And it is possible to produce the edible plants of the same quality anywhere, and to secure the reliability of the consumers.

In addition, since the present invention provides a progressive and continuous supply of target nutrients to plants for a long time by solid processing in the form of fertilizer granules by element, it is possible to safely mass-produce organic edible plants due to the vigorous growth utilization of edible plants .

Further, since the essential nutrients for each element are impregnated into the porous material granules to produce the organic solid fertilizer, the present invention has the effect of facilitating storage and transportation for a long time, and it is possible to accurately provide the capacity of the plant-specific fertilizer It is possible to perform target management.

In addition, since the essential nutritional components for each element can be individually produced, the present invention has an effect that the growth can be managed safely from pathogens according to organic farming.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow chart illustrating a method for producing an organic slow-release fertilizer according to the present invention.

Hereinafter, a method for producing an organic slow-release fertilizer according to the present invention will be described in detail with reference to the accompanying drawings.

The essential element of the present invention consists of N, P, K, Ca, Mg, S, Fe, Mn, Cu, B, Mo, Zn, Gallium "), the heavy elements are calcium, magnesium, and sulfur, and the trace elements are the remaining elements. To produce these, we need to produce a variety of products such as oilseed rape, blood (livestock blood, ie, livestock), dead fish or fish by-products, bone meal, dead sea minerals (mineral extracted from the Dead Sea), egg shells, Prepare phyllite and natural salt. Here, bone fragments are animal bones, Dead Sea minerals are minerals taken from the Dead Sea of Europe, and shell shells and oyster shells are all of the waste that corresponds to shellfish.

The natural fertilizer corresponding to the above-mentioned large amount of element, that is, nitrogen is a material containing nitrogen by a protein component in a large amount, and is a material containing oil, blood, and dead fish. Phosphorus contains a lot of phosphorus, (Also referred to as 'garrion') is a substance containing a lot of potassium, and is a dead sea mineral. Natural fertilizer corresponding to the heavy element, that is, calcium is a substance containing a lot of calcium. Natural gypsum, egg shell, Oyster shells, etc. Magnesium is a substance containing a lot of magnesium, and dolomite and natural rock are included, and sulfur is a substance containing a lot of sulfur. The trace element is a substance containing a large amount of the remaining elements, and is a mineral salt such as phytoncide and salt. In addition, any substance can be applied as long as the substance contains a large amount of the element.

This organic fertilizer production method is as shown in Fig.

First, in reference to the nitrogen extraction, it is preferable to prepare the oilseed rape such as soybean meal, soybean oil, rice bran oil, and the like, which contains a large amount of protein components, or a byproduct including dead fish and fish and blood Prepare. (Crumbling step). Here, when the amount of the nitrogen element (protein component) is large, the amount of the nitrogen element (protein component) is large Other materials may be used that correspond to the substance contained.

When the powder thus crushed and any one of hydrolysis solvents such as citric acid and acetic acid are contained in a separate mixing vessel at a predetermined ratio and sealed, and a hydrolysis reaction is induced for a predetermined period or time at room temperature before and after 25 ° C And is liquefied in the form of a first fertilizer mixed liquid containing a nitrogen element. (Hydrolysis step)

When the liquefied first fertilizer mixed liquid phase is maintained for a predetermined period of time, the soil impurities and the hydrolysis residue are deposited on the bottom, and then the soil impurities are removed and the first fertilizer liquid phase is separated.

Then, the first fertilizer liquid phase is accommodated in a predetermined container together with water, and the first nitrogen liquid phase, which is a liquid phase containing a large amount of nitrogen elements, is extracted using the difference in specific gravity of water. (First Extraction Step) The nitrogen liquid phase can also be extracted with a high-density filtration filter.

The hydrolysis residue separated in the precipitation separation step is mixed with any one or more of microorganisms and enzymes in a fermentation vessel to be fermented and decomposed for a predetermined period of time. The second fertilizer mixed liquid phase is heated to a temperature of 90 to 100 캜 for a predetermined period of time to concentrate and then filtered with a high-density filter to extract a second nitrogen liquid phase. (Second Extraction Step) Is a high-pressure high-density filtration filter capable of extracting pure nitrogen liquid phase only.

The first and second nitrogen liquid phases extracted in the first and second extraction steps are mixably received in the individual container for impregnation and at the same time the porous body grains having a relatively high porosity such as zeolite, Heated at high temperature for a period of time, the high-concentration nitrogen liquid phase flows into the pores of the porous body and is impregnated into the solid state (impregnation step)

In this way, the porous material particles impregnated with the nitrogen liquid phase in a solid state, that is, the organic nitrogen particles, are coated on the outer surface with vegetable oil including linseed oil, soybean oil and soybean oil (oilseed oil), clay and talc A coating material comprising a combination of a diatomaceous earth and a powder of adsorptive silica is coated and dried for a predetermined period of time.

Thus, even if the coated nitrogen particles are immersed in water, the nitrogen element is gradually and continuously supplied to the edible plant by the coating member.

The method for producing an organic slow-release fertilizer as described above can be produced by impregnating and impregnating phosphorus, potassium, calcium, magnesium, sulfur, and other elements into porous body grains. The method for producing an organic slow-release fertilizer for an element other than nitrogen according to the present invention uses the same flow as shown in Fig.

That is, bone fragments, dead sea minerals, egg shells, natural gypsum or shells, and dolomite are dried for a certain period of time and are individually pulverized into powder in a crusher in order to maximize the surface area. (Crushing step)

Each of the powders thus crushed is accommodated in a corresponding individual mixing vessel and at the same time a hydrolysis solvent such as citric acid or acetic acid is accommodated in the plurality of individual mixing vessels and the hydrolysis reaction is carried out at room temperature for a certain time When it is induced, it is liquefied into a first fertilizer mixture liquid containing a large amount of phosphorus, potassium, calcium, magnesium and sulfur (hydrolysis step).

When the first fertilizer mixed liquid phase of phosphorus, potassium, calcium, magnesium and sulfur respectively liquefied in the hydrolysis step is kept in the individual mixing vessel for a certain period of time, the residue impurities and hydrolysis residue precipitate to the bottom, After the residue and the residue are separated, the residue is removed and the first fertilizer liquid phase is separated. (Precipitation Separation Step)

Then, the first fertilizer liquid phase is contained in a predetermined container together with water, and the liquid phase of the first fertilizer element, which is a liquid phase rich in phosphorus, potassium, calcium, magnesium and sulfur, is extracted using the difference in specific gravity of water. 1 extraction step) The first fertilizer element liquid phase may also be extracted with a high-density filtration filter.

The hydrolysis residue separated in the precipitation separation step is mixed with any one or more of microorganisms and enzymes in individual fermentation vessels for each element, fermented and decomposed for a certain period of time, treated with fermentation, , A second fertilizer mixed liquid phase containing a large amount of calcium, magnesium and sulfur is produced. The individual fermentation vessels were heated to a high temperature and concentrated to maintain the second fertilizer mixed liquid phase at a temperature of 90 to 100 ° C for a predetermined time, and then filtered with a high-density filter to form a liquid phase containing phosphorus, calcium, magnesium, (Second extraction step). Here, the filtration filter is a high-pressure high-density filtration filter capable of extracting only pure element liquid phase.

The first and second element liquid phases, which are liquid phases rich in phosphorus, potassium, calcium, magnesium, and sulfur extracted in the first and second extraction steps, are mixed to be able to mix in the individual container for impregnation, and at the same time zeolite, And a high porosity high purity porous material such as talc are accommodated together and heated at a high temperature for a certain period of time to impregnate the pores of the porous material into a solid state with a high concentration of the element liquid phase.

As described above, the porous material granules, that is, the organic fertilizer element granules impregnated with the element liquid phase, which is a liquid phase containing a large amount of phosphorus, potassium, calcium, magnesium and sulfur, A coating material obtained by mixing a vegetable oil including tung oil (fluidized tree oil) and a binder selected from at least one of clay, talc, diatomaceous earth and adsorbed silica powder is coated and dried for a predetermined time (coating step)

Thus, even if the coated fertilizer element granules are immersed in water, the coating member gradually and continuously supplies phosphorus, potassium, calcium, magnesium and sulfur elements to edible plants.

Meanwhile, the trace elements except for nitrogen, phosphorus, potassium, calcium, magnesium and sulfur are impregnated with the porous element in the same manner as described above from the natural salt obtained by removing phyllosilicate or salt, The granules are produced.

Here, the coating step may further include mixing the exposed surface of the porous body fertilizer granules so that the powdered curing agent of the clay, clay, or diatomaceous earth is coated on the exposed surface before the impregnated porous body fertilizer granules are dried.

Claims (3)

A method for producing an organic slow-release fertilizer comprising:
A disintegration step in which the shell and the dead fish or blood, the bone meal, the dead sea minerals, the egg shell and the natural gypsum or the shell shell, and the dolomite are dried for a predetermined period of time and are separately crushed into powder in a crusher in order to maximize the surface area ;
Each of the pulverized powders and the hydrolysis solvent such as citric acid or acetic acid is contained in a plurality of individual mixing vessels and is sealed to induce a hydrolysis reaction at a room temperature for a certain period of time to produce nitrogen, phosphorus, potassium, calcium , A first fertilizer mixed liquid containing magnesium and sulfur;
The first fertilizer mixture liquid of nitrogen, phosphorus, potassium, calcium, magnesium and sulfur liquefied in the hydrolysis step is precipitated for a predetermined period of time to remove residue and hydrolysis residues to remove the residues and residues, and then to separate the first fertilizer liquid phase A precipitate separation step;
A first extraction step of separately extracting each of the first fertilizer liquid phases into liquid phase of nitrogen, phosphorus, potassium, calcium, magnesium and sulfur by separating the specific gravity using water;
The residue is mixed with at least one of microorganisms and enzymes and treated with fermentation decomposition for a certain period of time to produce a second fertilizer mixed liquid phase. The second fertilizer mixed liquid phase is heated to a high temperature to be concentrated and then filtered with a high- A second extraction step of separately extracting liquid phases of nitrogen, phosphorus, potassium, calcium, magnesium and sulfur;
Mixing the respective nitrogen liquid phases extracted in the first and second extraction steps, mixing the phosphorus phases extracted in the first and second extraction steps, mixing the respective phosphorus liquid phases extracted in the first and second extraction steps, Mixing the respective calcium liquid phases extracted in the first and second extraction steps, mixing the respective magnesium liquid phases extracted in the first and second extraction steps, and extracting the magnesium liquid phases extracted in the first and second extraction steps And the mixture is heated at a high temperature for a certain period of time in the form of a porous material such as zeolite, pearlite or talc in each individual container to form the nitrogen liquid phase, phosphorus phase, potassium liquid phase, calcium liquid phase, magnesium An impregnation step of impregnating each of liquid and sulfur liquid phases, and drying the porous liquid with fertilizer granules;
Wherein the impregnated porous material body comprises a vegetable oil including linseed oil, soybean oil, and tung oil (flow wood oil) on the outer surface thereof, and a combination selected from at least one of clay, talc, diatomaceous earth and adsorbed silica powder Characterized in that it comprises a coating step of coating the mixed coating material.
The method of claim 1, wherein
Further comprising the step of repeating the step from the crushing step to the coating step in order to produce the mineral grains using the natural salt and the phyllite with the desalted salt.
The method of claim 1, further comprising:
Wherein the coating step includes mixing the exposed surface of the impregnated porous material with the powdered curing agent such that at least one of starch, clay, clay, and diatomaceous earth is coated on the surface of the impregnated porous fertilizer before drying, Fertilizer manufacturing method.

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