KR20150103913A - Liquid Compound Fertilizer Using Sericite and Microalgae and Method of Manufacturing the Same - Google Patents

Abstract

The present invention provides a mixed liquid fertilizer and a method for manufacturing the same. The present invention manufactures the mixed liquid fertilizer by the method comprising: a step (S110) for preparing fine particles of sericite by pulverizing the sericite into fine particles and collecting the same of 300-400 mesh; an aqueous solution treating step (S120) for mixing 10 parts by weight of the fine particles of the sericite and 20-40 parts by weight of water and stirring the same for 2-3 hours, and then collecting a supernatant; a sericite aqueous solution concentrating step (S130) for primarily filtering the supernatant and then secondarily filtering and concentrating the same; and a concentrate post-processing step (S140) for collecting a final liquid fertilizer by putting 0.5-5 parts by weight of microalgae with respect to 100 parts by weight of the concentrated sericite aqueous solution. The microalgae is cultured using various kinds of domestic sewage created from civilized and industrialized regions as a nutrition source, and using the microalgae obtained through a photobioreactor is desirable. The present invention can provide a plant with various minerals, especially calcium, sodium, iron, etc which are insufficiently contained in soil, and provide the plant with organic nutrients such as proteins and lipids from the microalgae, which could not be supplied by the conventional liquid fertilizers, and vitamins at the same time.

Description

TECHNICAL FIELD [0001] The present invention relates to a liquid fertilizer using sericite and microalgae and a method for producing the same,

The present invention relates to a liquid-phase complex fertilizer capable of simultaneously supplying minerals and organic matters necessary for plant growth, and a method for producing the same, more specifically, to a soil- The present invention relates to a liquid fertilizer using a sericite and microalgae which can directly supply an organic matter rich in lipid and protein components and having a direct correlation with the growth of minerals, will be.

Today, rapid industrial development promotes urbanization and shifts manpower in rural areas to urbanization industrialization. This leads to changes in the economic location of cities and farming and fishing villages, resulting in a drastic decrease in the rural population.

The decline of the rural population inevitably led to the mechanization of agricultural technology and the problem of significantly increasing the yield or yield per unit area of cropland in order to meet the food demand due to the increase of the population.

As a solution to these problems, the use of chemical fertilizers to increase the use and production of pesticides to prevent pests and diseases. Chemical fertilizers are mainly used to supply insufficient nitrogen in soil, and are also used to supply phosphoric acid and potassium compounds. However, excessive use of chemical fertilizers has been reported to contribute to acidification of the soil, and when the soil is acidified, it interferes with the propagation of the microorganisms in the soil, so that the degradation of the organic material by the microorganisms is lowered, Is known to bring limitations to the growth of plants. At this point, it can be concluded that the use of chemical fertilizers over a long period of time may rather impair crop growth.

To solve these problems, the introduction of organic fertilizer by fermentation of microorganisms has been introduced. Organic fertilizer has mainly used compost and the like, but it takes a long time and accompanies a lot of odor, so it is not used much today. Today, it is mostly the use of sawdust, herbal medicine wastes, fish meal or livestock and natural organic materials mixed with them. However, since these organic materials must be fermented for a long time by using microorganisms, it is necessary to provide a place having a certain space and a fermentation facility, and manpower to manage and supervise them is required. As a result of the production of such organic fertilizer, And the like.

On the other hand, under the recognition that the crops that grow in the soil today are not only required to contain only nitrogen, phosphoric, or potassium components supplied through chemical fertilizers or organic fertilizers, but also components of trace elements such as magnesium and iron components , Sericulture, and various types of liquid fertilizer.

Korean Patent Laid-Open Publication No. 2009-3581 "Liquid fertilizer and its production method" is considered to be the first method of producing liquid fertilizer using sericite in Korea. This method introduces a very simple and simple technique to extract minerals in the sericite particles by adding predetermined sericite particles to water and stirring for a certain period of time. However, since this method uses water heated to 60 ° C to 70 ° C in advance by a water heater or heated to 70 ° C to 90 ° C in a mixing vessel in order to extract minerals from the above-mentioned sericite particles, It is economically disadvantageous in that it imposes a considerable burden on the manufacture of the device. In addition, the final liquid fertilizer is characterized by strong alkali (pH 12.75), and it can not be doubted whether it can be used as it is in general soil.

Korean Patent Registration No. 10-1014330 "Cultivation method of phragmophyllum using fertilizer or nutrient containing at least one of sericite and pegmatite" refers to a method of cultivating sericite or granite in powder form and spraying it first on the soil, Is sprayed secondarily on the plant, and the other third and fourth is continuously sprayed on the plant. However, this technique has a disadvantage in that it is unclear how to manufacture a large number of trace elements by metering and continuously supplying the fertilizer at each stage in accordance with the growth of the plant.

Korean Patent Laid-Open Publication No. 2013-84550 "A method for producing a safflower containing a sericite component and a saffron prepared therefrom" is a method for producing safflower which is obtained by pulverizing sericite and then introducing it into a hot aqueous solution and stirring in an alkaline region to extract mineral components, And introduces the technique of collecting the supernatant and using the liquid fertilizer ingredient. However, since this method requires heating the aqueous solution to 70 to 90 캜, it consumes too much energy in the manufacturing process, which is not preferable in terms of economy.

In addition, in this method, a separate alkaline component is added for extracting a large amount of mineral components from the sericite. This results in that the finally obtained liquid fertilizer component has a too high pH value and can not be used as a strong alkaline liquid fertilizer none. It is questionable whether the plants growing in the soil will actually be able to cope with such high alkaline fertilizer when it is actually applied to the soil.

In conclusion, the liquid fertilizer until now only supplied only a small amount of minerals to the soil, and supply the minerals, lipids and proteins as nutrients necessary for the actual growth of the plants, The complex liquid fertilizer that can be obtained inexpensively in view of the reality and the production method thereof have not been introduced at all.

Korean Patent Publication No. 2009-3581 "Liquid fertilizer and its production method" (2009. 10. 20.); Korean Patent Registration No. 10-1014330 entitled "Cultivation Method of Phragmites Using Fertilizers or Nutrients Containing at least One of Sericite and Pegmatite" (Feb. 7, 2011); Korean Patent Laid-Open Publication No. 2013-84550 entitled " Method for producing a safflower containing a sericite component and a saffron prepared therefrom "(Feb.

Disclosure of Invention Technical Problem [8] The present invention has been made in order to solve all the problems of the prior art described above, and it is an object of the present invention to provide a microorganism which is insufficient in soil, And a method for producing the same.

In order to achieve the above object, the present invention provides a method for preparing a composite liquid fertilizer and a method for producing the same, which comprises finely crushing sericite, separating the same using a sieve vibrator, collecting the granular material to a size of 300 to 400 mesh to prepare fine- S 110); An aqueous solution treatment step (S 120) of mixing the monolithic sericite with 10 parts by weight of water and 20 parts by weight to 40 parts by weight of water and stirring the mixture for 2 hours to 3 hours and taking a supernatant; A step (S 130) of concentrating the aqueous solution of the sericite to neutralize the acidity by primary filtration of the supernatant, and then secondary filtration and concentration of the neutralized solution; A post-treatment step (S 140) of concentrating the final liquid fertilizer by adding 0.5 to 5 parts by weight of microalgae to 100 parts by weight of the concentrated aqueous solution of the sericite; And the like.

In the present invention, it is preferable that the microalgae are those cultured using various domestic sewage generated in an urbanized industrialized area as a nutrient source, and obtained through a photobioreactor.

The complex liquid fertilizer according to the present invention not only can supply various kinds of minerals, especially calcium, sodium, iron and the like, which are insufficient in the soil to plants, but also plants such as proteins and lipids due to microalgae, Of organic nutrients and vitamins can be supplied to the soil is fertile.

In addition, since the complex liquid fertilizer according to the present invention can proceed at the normal room temperature without adopting the high temperature heating method of the aqueous solution which has conventionally been advanced in the conventional method for producing the sericite, It is advantageous in that the liquid fertilizer can be produced economically at a low cost.

Further, since the complex liquid fertilizer according to the present invention can be manufactured by adjusting the final concentration thereof in accordance with the target plant to be finally used, it is also advantageous as a method for producing customized liquid fertilizer.

1 is a schematic block diagram showing a step of producing a complex liquid fertilizer according to the present invention,
2 is a schematic view showing a process for producing a composite liquid fertilizer according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be noted that the accompanying drawings are only for explaining the technical idea of the present invention in detail and that the technical idea of the present invention is not limited thereto and that various modifications are possible. In the specification of the present invention, the same reference numerals are used for the same parts, and parts that can be easily created by those having ordinary skill in the art are omitted in the description of the present invention. .

The method for producing a complex liquid fertilizer according to the present invention includes finely pulverizing the sericite, separating the same using a sieve vibrator, and collecting the granite to a size of 300 to 400 mesh to prepare fine-grain sericite (S 110).

The present invention uses sericite to produce a complex liquid fertilizer that can be used in soil or plants. The sericite has been widely used in ceramics industry due to its high plasticity, drying strength and green strength, and has been used in various fields such as paints, electric insulators, active agents, and cosmetics. It has recently been known to be used in some cases to produce liquid fertilizers.

The present invention uses finely pulverized conventional sericite. By finely grinding, the surface area can be further expanded. The finely ground sericite is separated using a sieve vibrator and collected at a size of approximately 300 to 400 mesh.

In the method for producing a complex liquid fertilizer according to the present invention, 10 parts by weight of the above-mentioned fine-grain sericite and 20 parts by weight to 40 parts by weight of water are mixed and stirred at room temperature for 2 hours to 3 hours and then treated with an aqueous solution of a sericite S 120).

In the present invention, the fine-grained sericite is injected into water to extract various minerals present in the internal structure of the sericite. It is preferable to mix 20 parts by weight to 40 parts by weight of water with respect to 10 parts by weight of the sericite. When 10 parts by weight of the sericite is used in an amount of 20 parts by weight or less, the water content is so small that the mineral component is not sufficiently extracted. On the other hand, in the case of 10 parts by weight of the sericite, It is not suitable because there is a relatively large amount of water and there is a burden of concentration at a high concentration later.

In the present invention, the above-mentioned fine-grain sericite is put into water and then stirred at a room temperature for 2 hours to 3 hours. The present invention does not heat the water to a high temperature at all during stirring. This point is very different from the conventional art in that many prior art processes are performed by heating the water to a high temperature.

In many prior arts, in order to extract a larger amount of mineral components in water, the water is heated to a temperature of 60 ° C or higher and stirred. However, in the case of performing the heat treatment in this way, since water is previously supplied from the outside by heating at a high temperature, or electric heat is supplied to the mixing vessel by means of an electric heating coil or the like, a large amount of money I could not help it.

On the other hand, in the present invention, the water is not heated at all, but the stirring operation is carried out at room temperature. Therefore, the present invention is advantageous in that the liquid fertilizer can be produced at a much lower cost than the prior art.

Further, unlike the prior art, the present invention does not use any separate extraction aid such as sodium hydroxide or calcium carbonate at all. In the case of using sodium hydroxide or calcium carbonate as in the conventional techniques, even if the concentration of the extracted mineral component increases, it is possible to cause a side effect of the plant due to excessive sodium component in the final liquid fertilizer Therefore, the present invention does not use a separate extraction auxiliary agent at all.

This is explained more by the relationship with plants.

Soils must have low salinity for plants to absorb nutrients from the soil. If the soil's salinity is low, plants can absorb water from soil with low osmotic pressure using the high osmotic pressure of the roots. In this case, the principle of water movement into the root of the soil moves from the soil with high water potential to the root with low water potential. If the fertilizer is sprayed with a high content of sodium hydroxide, the content of hydroxide ion and sodium in the soil increases, and the osmotic pressure of the soil becomes large, which lowers the water potential. If this happens, the roots of the plant will not be able to absorb water from the soil, or vice versa, the water will escape from the roots of the plant to the soil and eventually the plant will die.

On the other hand, the fertility of the soil is determined by the amount of minerals attached to the surface of the soil particles. The surfaces of the soil and organic particles are negatively charged with molecules such as -OH and -COOH, which are negatively charged. On the negatively charged surface, hydrogen ions and minerals (ammonium, calcium, potassium, magnesium, sodium, iron and manganese , Copper, etc.) are attached. If only hydrogen ion is attached, the soil becomes acidic, and there is no mineral, and it becomes a barren soil. However, when hydrogen ions are replaced by positively charged minerals, they become fertile soil, and plants can easily absorb the minerals, so that plant growth is improved. However, when the soil surface is replaced by calcium and sodium only, it becomes an alkaline soil, but when it is replaced with ammonium, iron, magnesium, manganese, etc., it can become a fertile soil.

Sodium hydroxide is a typical compound that promotes the alkalinity of the soil. Normal soil surfaces have negatively charged particles. In acidic soil, hydrogen ions are attached to this negative charge, but if calcium or sodium is present in the surroundings, it is replaced by ions having such a positive charge. Eventually, the soil is alkalized. The alkalization of the soil in the desert is due to the continuous uptake of sodium and calcium ions to the surface of the soil. Therefore, adding a separate extraction aid such as sodium hydroxide to a liquid fertilizer that aids plant growth is not desirable because it alkalises the soil.

In fact, if the sericite is put in water and stirred for a certain period of time, the mixed solution containing the sericite fine particles exhibits a higher acidity than the initial acidity (pH), resulting in a substantially alkaline aqueous solution. After the stirring operation is completed, it has been confirmed that the mixture of the aqueous solution of the sericite fine particles has an acidity of about pH 9.

The present invention performs a stirring operation in a mixing vessel for a certain period of time, and when the stirring operation is stopped in the mixing vessel, the particulate sericite sinks on the bottom of the mixing vessel and is separated into a supernatant on the upper side of the mixing vessel.

The method for producing a complex liquid fertilizer according to the present invention includes a step (S 130) of concentrating the aqueous solution of the sericite to neutralize the acidity of the solution by primary filtration of the supernatant, and then secondary filtration and concentration of the neutralized solution have.

After completion of the aqueous solution treatment step of the sericite, the stirring of the mixing vessel is stopped and the supernatant in the mixing vessel is primarily filtered. The filter used in the primary filtration step may be a membrane filter, a microfilter, or an ultrafiltration filter.

In the present invention, the membrane filter, the microfilter or the ultrafiltration filter is used in the primary filtration step in order to remove particulate insoluble substances (including sericite) contained in the supernatant. When the above-mentioned sericite powder is produced without removing it from the liquid fertilizer, there is no problem when the liquid fertilizer is applied to the soil. However, when the liquid fertilizer containing the above-mentioned insoluble matter is directly fertilized on the leaf flies of leaf vegetables (spinach, Chinese cabbage, lettuce, etc.), a somewhat unsuitable situation may arise. When the above liquid fertilizer is directly applied to the leaves and leaves, the leaves of the sericite are left on the leaves, and the value of the product is lowered, and not only the taste is not good, but also the buyers eat directly, This is because the granitic sericite particles along with leafy vegetables may enter the body along with food.

In this respect, the liquid fertilizer according to the present invention, in addition to the fine-grained sericite, is previously removed from the aqueous solution in the form of other particulate insoluble matters, so that the liquid fertilizer according to the present invention is also different from the conventional liquid fertilizers .

The present invention has the function of dropping the acidity (about pH 9) of the supernatant from the initial alkali region to the neutral region (about pH 7.1 to 7.7) by using the membrane filter or the ultrafilter in the primary filtration step At the same time. When the supernatant is to be used directly as a liquid fertilizer component without filtration, it is known that the acidity usually increases, and it is usually changed to an alkaline region (about pH 9). However, according to the present invention, by passing through the primary filtration step, the high acidity is lowered and converted into the neutral region.

In the present invention, the first filtered solution is subjected to a second filtration step through a reverse osmosis process. The secondary filtration step serves to concentrate the primary filtered solution to an extent suitable for the use of the final liquid fertilizer. The concentration ratio can be adjusted depending on the content of the mineral component contained in the liquid fertilizer.

The present invention concentrates the aqueous solution of the sericite through the secondary filtration step. The concentration ratio of the sericite aqueous solution is preferably 1.2 to 3 times the initial aqueous solution, depending on the content of the mineral component contained in the liquid fertilizer. In general, when the content of the mineral component of the initial aqueous solution is high, the proportion of relatively concentrated is low, whereas when the content of the mineral component of the initial aqueous solution is low, the proportion of relatively concentrated is high. Preferably, the filter used in the secondary filtration step is a reverse osmosis filter.

The concentrated aqueous solution obtained through the secondary filtration process may be used as it is to proceed to the next step or a part of the concentrated aqueous solution may be returned to the previous stage to perform the recirculation process.

The method for producing a complex liquid fertilizer according to the present invention includes a post-treatment step (S 140) of concentrating a final liquid fertilizer by adding 0.5 to 5 parts by weight of microalgae to 100 parts by weight of the concentrated aqueous solution of the sericite .

According to the present invention, 0.5 to 5 parts by weight of microalgae are added to and mixed with 100 parts by weight of the aqueous solution of the sericite passing through the secondary filter to complete the final liquid feedstock. The microalgae means a single cell organism that has a photosynthetic pigment and performs a photosynthesis action. Chlorella vulgaris can be exemplified as a typical microalgae. The microalgae are a necessary nutrient for the final liquid fertilizer to grow and grow in the soil, and make a decisive contribution to the supply of protein and lipid components as organic components. Organic fertilizers such as compost which have been conventionally used are re-fermented by microorganisms and used as a final nutrient source. Since the microalgae are composed of protein components, lipid components and other vitamins as single cell organisms, It has the advantage of being easily absorbed as a substance.

In the present invention, when the amount of the microalgae is less than 0.5 part by weight, the amount of the protein and the like supplied to the plant is insufficient. On the other hand, when 100 parts by weight of the aqueous solution of the sericite is less than 5 parts by weight There are a lot of components such as proteins supplied to plants, but it is not desirable because the cost is high in terms of economy.

In the case of using the microalgae of the present invention, it is preferable to use the microalgae cultured in a variety of municipal and industrialized areas as a nutrient source, and obtained through a photobioreactor.

The present invention uses fine algae mixed with the above-mentioned concentrated aqueous solution of the sericite, which can easily and inexpensively procure protein components required by plants through microalgae, Because it can make a significant contribution to the treatment of sewage.

First, we examine the mass propagation of microalgae. Unlike ordinary microorganisms, the microalgae absorb carbon dioxide (CO ₂ ) from the atmosphere and act as photosyntheses like plants with the help of light energy. Therefore, when such fine algae are used, carbon dioxide (CO ₂ ) in the atmosphere can be absorbed and removed, while when light energy is supplied to the microalgae, the photosynthetic action is performed to grow them. Equipment that proliferates microalgae by photosynthesis can be defined as a photobioreactor in a broad sense, and these photobioreactors are widely introduced today.

Next, we will look at how to handle sewage by using microalgae. The microalgae are cultivated under normal culture conditions and culture conditions, and microalgae cultures are put into sewage treatment plants of living sewage generated in urbanization industrialization process. At this time, it is preferable to add 0.5 liters to 5 liters of the microalgae culture to 10 liters of the domestic sewage. When the microalgae culture is injected at a rate of 0.5 liters or less to 10 liters of the waste water or wastewater, a biological treatment period is required for a long period of time. On the other hand, when the microalgae culture is fed at a rate of 5.0 liters or more, But it is not preferable because there is a problem that the microalgae must bear an excessive related cost for the cultivation of the microalgae.

In the present invention, a treatment tank for domestic wastewater into which the microalgae are introduced is converted into a kind of photobioreactor and used. For this purpose, a light guide plate is installed in the treatment tank of the domestic wastewater, light emitted from the outside is irradiated, and air is blown from the outside, and the mixture is slowly kneaded for about one to four days at room temperature. At this time, the microalgae are in constant contact with various contaminants contained in the domestic sewage, and rapidly grow as nutrients in the microalgae as food.

In this process, the municipal wastewater is deprived of various nutrients, so that dissolved inorganic nitrogen (N), dissolved inorganic (P), ammonia, nitrite, nitrate, organic nitrogen compound, inorganic Phosphates, organophosphates, and silicates are gradually declining, while microalgae, which feed on these nutrients, grow rapidly.

The present invention can separate microalgae that have grown rapidly in the sewage treatment tank to obtain microalgae required in the present invention. The microalgae may be used as it is, or the microalgae may be dried and used. Meanwhile, the domestic wastewater from which the nutrients are removed is discharged to the outside through the discharge port.

On the other hand, the present invention, on the other hand, purifies and desalinates the domestic wastewater derived from the process of urbanization with microalgae, and on the other hand, utilizes the microalgae obtained in the process of domestic wastewater, It is advantageous that the fertilizer can be produced at a low cost at the same time.

In addition to the microalgae being injected into the aqueous solution of the sericite, the present invention may further comprise various mineral components to produce a liquid fertilizer. The various minerals may be those conventionally used in the art. Examples of the additional components include wood vinegar, boron, activated carbon powder, water-soluble silicic acid, zinc sulfate, manganese sulfate, and citric acid.

While the present invention has been particularly shown and described with reference to the preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, The range is determined and limited.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

Claims (6)

(S 110) finely grinding the sericite, separating it using a sieve vibrator, collecting it in a size of 300 to 400 mesh to prepare a fine-grained sericite;
An aqueous solution treatment step (S 120) of mixing the monolithic sericite with 10 parts by weight of water and 20 parts by weight to 40 parts by weight of water, stirring the mixture at room temperature for 2 hours to 3 hours, and taking a supernatant;
A step (S 130) of concentrating the aqueous solution of the sericite to remove the insoluble particles in the aqueous solution of the sericite, neutralize the acidity of the aqueous solution of the sericite, and then secondly filter and concentrate the neutralized aqueous solution;
Treatment step (S 140) of concentrating the concentrate to obtain a final sericidal liquid fertilizer by inputting 0.5 to 5 parts by weight of microalgae to 100 parts by weight of the concentrated aqueous solution of the sericite; To
≪ RTI ID = 0.0 > 1, < / RTI >
The method according to claim 1,
Wherein the filter for primarily filtering the aqueous solution of the sericite is a membrane filter, a microfilter, or an ultrafiltration filter.
The method according to claim 1,
Wherein the ratio of secondary concentrating the aqueous solution of the sericite is based on the content of the mineral component of 1.2 to 3 times the initial aqueous solution.
The method of claim 3,
Wherein the secondarily concentrated aqueous solution of the sericite is used as it is to proceed to the next step or to return a portion of the concentrated aqueous solution to a previous stage to perform a recycling process.
The method according to claim 1,
Wherein the microalgae are cultivated as a nutrient source from various living sewage generated in an urbanized and industrialized area, and obtained through a photobioreactor.
A composite liquid fertilizer produced by any one of claims 1 to 5.

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