KR20050034270A - Method for preparing urea-clay mineral hybrid fertilizer - Google Patents

Abstract

The present invention significantly improves the deterioration of the fertilizer efficiency of urea by physicochemical and biochemical decomposition of urea applied to soil as fertilizer, and at the same time, the water environment of air pollution and nitrate nitrogen by NOx gas generation by rapid urea decomposition. Stabilizing urea between layers of stratified clay minerals at the molecular level in order to reduce the water pollution caused by the inflow to the water, maintain urea fastness and minimize physicochemical and biochemical decomposition to maximize urea fertilizer effect. It is to provide a method for producing a urea-clay mineral hybrid fertilizer which can be.

The method for preparing the urea-layered clay mineral of the present invention is a plate-shaped clay mineral: (inorganic salt + urea) in a weight ratio of 1: 0.5 to 2, and an inorganic salt: urea in a urea ratio of 1: 2 to 6 by mixing 30 Heat treatment, cooling and shaping for 0.5 to 4 hours at a temperature of from -120 [deg.] C.

Description

Method for preparing urea-clay mineral fertilizer {Method for preparing urea-clay mineral hybrid fertilizer}

The present invention relates to a process for the preparation of urea-clay mineral fertilizers. More specifically, the present invention significantly improves the deterioration of fertilizer efficiency of urea by physicochemical and biochemical decomposition of urea applied to soil as fertilizer, and at the same time air pollution and nitrates by NOx gas generation due to rapid urea decomposition. In order to reduce water pollution caused by the inflow of nitrogen into the water environment, urea is stabilized between layers of layered clay minerals at the molecular level to maintain urea fastness and minimize physicochemical and biochemical decomposition, The present invention relates to a method for producing urea-clay mineral hybrid fertilizer capable of maximization.

In general, urea (尿 素, Urea) is a representative chemical nitrogen fertilizer has a fast effect to supply the nitrogen components necessary for crops quickly. However, urea has a low physicochemical stability and is rapidly degraded by urease, urease, which is highly active in soil.

That is, most of the urea used in the soil is decomposed into ammonia or oxidized NOx, volatilized into the atmosphere as gas, or lost to nitric acid by soil water. Early efforts to reduce urea loss were directed at inhibiting urease activity in soil. Although various inhibitors of urease activity have been developed, most of them are pollutants of soil environment or low inhibitory efficiency.

Since then, a number of attempts have been made to overcome such problems through developing urea substitute fertilizer, chemical modification or coating of urea. As a result, a few practical nitrogen fertilizers have been practically used by urea derivative synthesis or polymer coating technique. to be.

On the other hand, the utilization of clay minerals adsorbed with ammonium is a situation that is not practical because of the low nitrogen content. Eco-friendly high-functional fertilizers using clay minerals containing recently developed salts have high nitrogen content and are easy to prepare, and have high potential for practical use. And high temperature treatment may be required.

Therefore, it is very urgent to develop a technology that can solve problems related to the improvement of fertilizer efficiency and the environmental pollution caused by the loss of fertilizer components. Moreover, urea is a fast-acting nitrogen fertilizer that currently accounts for more than 50% of total nitrogen fertilizer consumption worldwide, so the above-mentioned problems remain a priority for agriculture, industry and the environment.

Therefore, the present invention is to protect the physicochemical degradation of the urea, to inhibit the degradation by urease, and the soil of the decomposition product in order to maximize the absorption of the crops by maximizing the absorption of the crop by minimizing the loss to the atmosphere or water environment while maintaining the fastness of the urea The technical task is to achieve increased sustainability at the same time, and to realize practical use only when the content of urea is high, eco-friendly and economical.

Therefore, in the present invention, a neutral low molecular urea having a polarity between nano-layers of negatively charged layered clay minerals used as a soil modifier is stabilized through nanohybridization technology, so that the physicochemical and biological decomposition of urea is stabilized. The purpose of the present invention is to provide a method for preparing urea-layered clay mineral hybrid fertilizers that exhibits soil-friendly properties by maximizing resistance to soil.

The present invention is a plate-shaped clay mineral: (inorganic salt + urea) in a weight ratio of 1: 0.5 to 2, wherein the inorganic salt: urea molar ratio of 1: 2 to 6 by mixing at a temperature of 30 to 120 ℃ 0.5 to 4 hours The urea-cationic complex, which is subjected to heat treatment, cooling and shaping during the process, is a method for producing a stabilized urea-layered clay mineral hybrid fertilizer between layers.

In the present invention, when the reaction molar ratio of inorganic salts and urea or the weight ratio of clay minerals is out of the ranges indicated, the content of inorganic nutrients including nitrogen is reduced or the eutectic of urea and inorganic salts is incomplete, and the hybrid material content is significantly reduced. Not formed.

The urea-layered clay mineral hybrid fertilizer of the present invention is composed of a step of synthesizing a stable urea-cation complex in the eutectic state, an intercalation step and a forming step of the complex, and swellable layered clay mineral, that is, montmorillonite (Montmorillonite) Ionic salts containing ionic, cation with urea and coordination compounds, ie alkaline earth metals or transition metals, eg magnesium (Mg), bentonite-based, smectite-based and vermiculite-based clay minerals Chloride or nitrates such as calcium (Ca), zinc (Zn) and copper (Cu) are used.

The principle of the present invention is that when urea is poorly thermally decomposed with various salts, the urea inhibits the binding force of the salts and combines with the salt cations to form the urea-cationic complex, which greatly reduces the melting point of the salts and at the same time the thermal stability of the urea. It is based on the fact that this improves and becomes a stable eutectic state.

The eutectic state is fluid as a solution, so that the cationic urea-cationic complex is intercalated into a cation form by layer ionization reaction with a layered clay mineral, and at the same time, the neutral urea-cationic complex is replaced with water by high temperature and concentration difference. The reaction is intercalated and stabilized.

In addition, the eutectic state is solidified by cooling so that the urea-cation complex inserted between the layers can be solidified in a very stable state. Stabilized urea-cation complexes between layers of sub-nano minerals can be protected from light or heat due to the protection of the inorganic layer and also from urease, which is significantly larger than nano units.

In addition, since the urea-cationic complex is formed by coordination bonds between cations and urea, the ligand is easily exchanged by other ligands, especially water, so that the urea-cationic complex is readily released and decomposed by water molecules, which are natural ligands, and used in crops. Furthermore, since the released urea is likely to decompose in the vicinity of the nano-unit of the anionic layered clay mineral as a carrier, ammonium that has not been absorbed by the crop can be adsorbed to the carrier, thereby minimizing loss in the soil.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention in more detail as follows.

1 of the accompanying drawings is a diagram illustrating a preparation process based on the synthesis principle of urea-clay mineral fertilizer. Since urea has poor thermal stability, a polymerization reaction or the like occurs during heating, so that stable melting is not possible. Thus, as described above, the urea-cation complex is formed by heating with urea and ionic salts, and then reacts with a layered clay mineral having anions such as montmorillonite, for example, urea-cation complex through ion exchange and substitution reactions. The insertion of is in progress.

These reactions proceed rapidly and complete within 4 hours. As the reaction proceeds, the fluidity of the reactants in the gel state becomes lower, and when the insertion reaction is completed, the viscosity becomes very high, and solidification occurs upon cooling. For molding, it is possible to mold easily by injecting the reaction product in the form of a gel with fluidity into a specific shape and solidifying while cooling.

FIG. 2 shows the representative X-ray diffraction patterns of reaction products obtained by reacting MgCl ₂ with 4 or 6 moles of urea at the same weight of bentonite or montmorillonite at 105 ° C. for 0.5 to 4 hours. FIG. The dried composition ratio was 50% for swellable clay mineral, 33% for urea, and 17% for MgCl ₂ .

The clay mineral used as an inorganic carrier was 0.3 nm between layers as the main peak near 1.25 nm, but after the reaction, the main peak appeared around 1.7 nm due to the insertion of the (urea) x-Mg complex. It can be seen that greatly expanded. This interlayer 0.7 nm is found to be equal to the estimated (element) ₆ -Mg complex size, which is one critical clue regarding the intercalation of this complex.

In FIG. 2, (A) is the X-ray diffraction result of montmorillonite, a representative plate-like clay mineral, (B) is a hybrid fertilizer prepared by setting the molar ratio of urea / inorganic salt to 6, and (C) is the molar ratio of urea / inorganic salt. It is a hybrid fertilizer prepared with 4.

FIG. 3 shows the results of infrared spectroscopy analysis of the reaction product of (C) in FIG. _2. The heat treatment products of urea and MgCl _{2 show} the same pattern as the (urea) _x -MgCl ₂ complex synthesized in a known organic solvent. In addition, the characteristic absorption bands are apparent even after the reaction with bentonite.

In addition, the characteristic absorption band disappears after washing with excess water, showing that urea is easily released by ligand exchange with water molecules.

In FIG. 3, (A) is urea, (B) is a urea-salt complex obtained by cooling the eutectic solution with a molar ratio of urea / inorganic salt of 6, and (C) is prepared with a molar ratio of urea / inorganic salt of 6 It is a hybrid fertilizer, and (D) refers to a hybrid fertilizer dried after washing with (C).

Figure 4 shows the change in the concentration of urea and related reaction products in the soil when mixing the reaction product as shown in Figure 2 (C) in the soil so that the absolute amount of urea 10kg per 10a soil after mixing with the soil at 30 ℃ hourly The trend of generation of N ₂ O gas in soil is the relative amount of urea treatment 100%. According to FIG. 4, the elements inserted between the layers of bentonite in the form of complexes are very delayed at the surface of the soil and are easily eluted by water, but have high concentrations of ammonium or nitric acid remaining in the soil and generation of nitrate nitrogen. It shows that the speed is slow. As a result, the amount of volatilized to N ₂ O was also found to be 20 to 30% less than the control.

FIG. 5 is a result of analyzing the decomposition of urea at 40 ° C. and mixing it with the soil at a rate similar to that of the reaction product as shown in FIG. As a result of comparing the pattern of N ₂ O volatilized over time with urea, the hybrid fertilizer of the present invention was found to be significantly prevented from decomposition at the soil surface compared to the general urea, and the nitrogen fertilizer efficiency of urea when sprayed on actual plantation. It is clearly shown that due to the increase of, the generation of NO _x , the main cause of air pollution, is significantly suppressed by 50% compared to the control.

In FIG. 5, (A) shows the change in urea content over time at 40 ° C. after treatment with 0.5 g of urea absolute amount in 10 g of soil, and (B) after spraying on the soil surface so that the absolute amount of urea becomes 10 kg per 10 a of soil. The generation amount trend of N ₂ O (relative generation amount of 100% of the urea treatment tool) is shown.

As described above, the urea-clay mineral fertilizer according to the present invention is a clean fertilizer, and can significantly compensate for the high loss rate of urea, thereby reducing the fertilizer application. In other words, it is possible to maximize the fertilizer efficiency by increasing the absorption rate of the fertilizer components, as well as to minimize the environmental pollution due to the loss of fertilizer components.

In addition, by increasing the utilization of natural swellable clay minerals with a large amount of domestic reserves, functionalizing various swellable clay mineral materials and developing them into high value-added fertilizers can contribute to the maximization of resource utilization.

The urea-layered clay mineral hybrid fertilizer of the present invention is suitable for use as nitrogenous fertilizer, fertilizer-containing soil modifier, fertilizer or soil modifier in home garden or pollen.

1 is a view showing a manufacturing process of urea-clay mineral fertilizer.

2 is a diagram showing the results of X-ray diffraction analysis of urea-clay mineral fertilizer.

3 is a diagram showing an infrared analysis spectrum of urea-clay mineral fertilizer.

Figure 4 is a graph showing the change pattern of urea and urea-clay mineral fertilizer mixed and used in the soil.

5 is a graph showing the change of urea in the soil when spraying urea and hybrid fertilizer with nitrogen in the lettuce plantation

Claims (5)

Plate-shaped clay minerals: (inorganic salt + urea) in a weight ratio of 1: 0.5 to 2, wherein the inorganic salt: urea molar ratio of urea 1: 1: 2 to 6 by heating, cooling and forming the urea-cationic complex Method for preparing urea-layered clay mineral hybrid fertilizer stabilized between layers. The method according to claim 1, wherein the plate-like clay mineral is montmorillonite, bentonite, smectite, and vermiculite-based clay mineral, and is used as a pure article or a substance containing a crystalline phase thereof. The method for producing urea-layered clay mineral fertilizer according to claim 1, wherein the inorganic salt is a chloride or nitrate containing a cation having a coordinating ability, and the cation is selected from at least one of alkaline earth metal and transition metal. [4] The urea-layered clay mineral hybrid fertilizer of claim 3, wherein the inorganic salt is chloride or nitrate such as magnesium (Mg), calcium (Ca), zinc (Zn), copper (Cu), or the like. Way. The method for producing urea-layered clay mineral hybrid fertilizer according to claim 1, wherein the heat treatment is performed at a temperature of 30 to 120 캜 for 0.5 to 4 hours.