KR101831826B1 - Organic fertilizer having soil microbes and production method of the same - Google Patents

Abstract

Provided are an organic fertilizer containing microorganism and a production method thereof. To this end, a complete fermentation is carried out by a production system comprising an aging section to conduct a continuous fermentation aging step in which mesophilic and thermophilic fermenting microorganism is injected at a variable temperature and a post-aging section to conduct a post-aging step. Accordingly, it is possible to derive crop growth promotion effects and gas barrier improvement effects when the organic fertilizer is used to improve soil conditions in crop cultivation areas.

Description

TECHNICAL FIELD [0001] The present invention relates to an organic fertilizer containing microorganisms and a method of producing the same. BACKGROUND ART < RTI ID = 0.0 >

The present invention relates to an organic fertilizer and a method for producing the same, and more particularly, to a microorganism-containing organic fertilizer produced by a complete fermentation into a production system and a method for producing the same.

Since the 1960s, the fertilizer application of fertilizer (inorganic fertilizer) has continued to be applied to the cultivation area and the plantation area of the field to increase the yield of cultivated crops and increase the profit per unit area. Proper use of chemical fertilizers can guarantee the rapid growth of crops and the resulting increase in profits, but due to excessive fertilization, there has been a problem of causing salt damage due to acidification and salt accumulation of cultivated soils.

Salt obstruction means that the fertilizer components (mainly nitrogen and phosphoric acid) fertilized in the soil are excessively accumulated in the soil water around the roots of the cultivated crops and can not be efficiently absorbed through the roots of the cultivated crops, And by changing the physical properties of the soil such as acidification of the soil and hardening of the soil, it is possible to prevent the survival of the microorganism closely related to the growth of cultivated crops and to induce the activity of pathogenic microorganisms And it means that the cultivated crops can no longer grow normally, such as causing imbalance in the supply and demand of the minerals necessary for the cultivation of crops, despite continued fertilization of chemical fertilizers.

These problems are not confined to some crop growing sites, and they are problematic in almost all crop growing areas in Korea where excessive fertilization is prevalent. Especially, in the case of the plantation growing areas, continuous cropping is a problem.

In other words, compared with the non-growing area, the plantation area is attempted to increase the annual yield, so that the over-fertilization is continued and the enclosed space is continued, so that, depending on the continuous evaporation of the soil water, More rapidly integrated, and the salt obstacle becomes more severe.

Therefore, it is necessary to improve the cultivation soil to solve the salt obstacle. Accordingly, there has been proposed a method of applying silicate fertilizer fertilizer to provide soil cultivation, green growth crops, useful phosphoric acid for a certain period of time, treating a salt adsorbent of a complex compound component, introducing rice straw and crushed wood to provide pores and microbial habitats in the soil .

However, the cultivation of fallow and greenery crops causes a decrease in profits, and silicate fertilizer can cause another problem of overfishing. In addition, the treatment of salt adsorbent does not guarantee safety as well as cost, Has the advantage of providing physical pores and providing organic materials with available soil microorganisms, but harmful fermentation gases such as ammonia and nitrous acid are generated during the decomposition of organic matter by the microorganisms, which causes harmful problems to cultivated crops and agricultural workers .

Other methods of soil improvement include organic fertilizer (compost) that is used as a substitute for chemical fertilizers in environmentally friendly agriculture. Organic fertilizer is to ferment organic matter into microorganisms and decompose them to provide nutrients that plants can use. Inorganic fertilizers (N, P, K) and trace elements (Mg, Mn, Cu, B, Mo, etc.) are supplied as nutrients for growing crops when organic fertilizer is applied to the cultivation area, , Provide physical pores in the soil, and amino acids, nucleic acids, organic acids, vitamins, and corrosion are supplied to the soil microorganisms to settle them, and the microorganisms are restored, and organic acids secreted by the rhizosphere microorganisms It is expected that salts will be ionized so that crops can absorb easily, and mitigation of salt accumulation in crops.

Therefore, in Korean Patent No. 10-1313749 (method of producing compost having soil improving effect), rice straw, rice hull or sawdust and natural microorganism Bacillus cereus (ATCC 14579 (T)) and Bacillus perum Bacillus firmus, NCIMB 9366 (T)), which is a natural mineral bearing mixed strains, is fermented. In Korean Patent Laid-Open No. 10-2017-0050743 (system for producing soil modifying material using food waste), dehydrated food wastes are reacted with moisture control material and quicklime, and then they are reacted with humus and microorganisms (Bacillus, A selenomonas system, and a streptomonase system), and a rice straw support.

The above prior arts provide organic fertilizer produced by fermenting organic matter (shredded or food waste) with microorganisms contained in a microorganism carrier composed of minerals or rice straw, respectively, as well as providing sustained So that the organic matter can be decomposed.

However, in the case of Korean Patent No. 10-1313749, it is difficult for the microorganism of the genus Bacillus to completely ferment the starch, rice straw, rice hull or sawdust, and in case of Korean Patent Publication No. 10-2017-0050743, And it is packaged and stored. Therefore, it is difficult to judge that the fermented product is completely fermented since the odor is evaluated by using the smell after leaving for only 5 days without describing the fermentation time or the like separately. In this way, when fertilized organic fertilizer which is not fully fermented is added to the soil with salt obstruction, the organic matter that is less fermented by the microorganism is decomposed and the gas trouble (ammonia gas, nitrite gas, etc.) which is harmful to cultivated crops and agricultural workers .

In order to solve the above problems, the inventor of the present invention has developed a production system disclosed in Korean Patent Application No. 10-2017-0052092 of the present inventor (Rye soil produced by recycling production system of organic wastes and a slope surface greening construction method using the same) The present invention has been accomplished by developing a completely fermented organic fertilizer containing microorganisms that can be utilized for improving the soil with a salt obstruction by utilizing some modifications.

The present invention has been proposed in order to solve the above problems in a comprehensive manner, and it is an object of the present invention to provide a fermentation system which comprises a fermentation process in which a medium-temperature and high-temperature microorganism culture solution is injected into a continuous fermentation fermentation stage, The present invention provides a microorganism-containing organic fertilizer which can solve the gas barrier problem and can improve the gas barrier and the crop growth promotion effect when used for the soil improvement of the crop growing area, and a method for producing the same.

In order to accomplish the above object, the present invention provides a microorganism-containing organic fertilizer produced by a production system divided into aged copper, agitated copper and packed copper, wherein the aged copper and the agitated copper are respectively ground, An odor reducing device, and at least one fermenter, wherein the air introducing device comprises a plurality of elongated grooves opened at the top of the bottom of the fermenter, a plurality of elongated grooves A plurality of air supply pipes arranged in the grooves, an air distribution pipe connected to the plurality of air supply pipes, and an air injector connected to one end of the air distribution pipe, wherein the air supply pipe and the air distribution pipe are provided with compressed air And further comprises a temperature control device for controlling the temperature, wherein the aged copper and the agitation copper Inner side of the plurality of nozzles is provided a microorganism culture solution injection tube provided towards the fermentation tank, the composition of the microorganism-containing organic fertilizer is characterized in that it is configured to include a-axes and the microorganism culture medium.

Wherein the fermentation tank is divided into at least two fermentation tanks and the temperature regulating device is configured to control the temperature of the compressed air differently depending on the fermentation tanks. The microbial culture solution injection pipe is configured to inject the microbial culture solution into the fermentation tank Another characteristic of the organic fertilizer containing microorganisms according to the present invention is as follows.

The microbial culture solution supplied to the microorganism culture solution inlet tube and constituting the composition of the microorganism-containing organic fertilizer may be selected from the group consisting of Pseudomonas protegens, Aspergillus callestemii, Rhodotorula aurantiaca, At least one of Bacillus megaterium, Streptomyces costaricanus, Thermoascus thermophilus and Bacillus subtilis is 1 x ^{10 6 to 7} cfu / g of the microorganism powder is diluted 400 to 600 times with respect to water to make the microorganism-containing organic fertilizer according to the present invention different.

Wherein the one fermentation tank and the nine fermentation tanks are symmetrically divided into two rows with the same size and facing each other so as to be perpendicular to the longitudinal direction, wherein the one or more fermentation tanks are longitudinally divided, The front and rear transfer devices are fastened to the rails above the side walls, and the agitating device provided with the up-and-down moving and rotating means of the stirring arm is fastened to the predetermined frame in the front and rear transfer devices. Containing organic fertilizer.

The composition of the organic fertilizer includes 35 wt% of sawdust, 3 wt% of coffee beans, 1 wt% of the microbial culture solution, and 1 wt% of other zeolite together with 35 wt% of weeds, 20 wt% Is another feature of the microorganism-containing organic fertilizer according to the present invention.

Meanwhile, a method for producing an organic fertilizer containing microorganisms according to the present invention is a method for producing a microorganism-containing organic fertilizer by the above-described production system, Growing in the stirring copper; And a step of storing and packing in the packed copper, wherein the step of fermenting and aging in the aged copper comprises a composition preparation step, a middle temperature fermentation step and a high temperature fermentation step.

Wherein the fermentation tanks are divided into two tiers symmetrically with respect to one another in such a manner that one preparation vessel and nine fermentation tanks 2 to 10 face each other in a direction perpendicular to the longitudinal direction and that the one or more fermentation vessels are longitudinally divided, In the mesophilic fermentation step, the composition prepared in the composition preparation step is transferred from the preparation tank to the fermentation tank No. 2 and mixed, and the Pseudomonas protegens, Aspergillus callestemii and Rhodotorula aurantiaca A first mesophilic fermentation step in which a first mesophilic microorganism culture solution mixed with Rhodotorula aurantiaca is injected and fermented by supplying compressed air at 30 ° C; A second mesophilic fermentation step of transferring the composition fermented by the first intermediate temperature fermentation step to a fermentation vessel No. 3, mixing the same, feeding a predetermined amount of the first mesophilic microorganism culture liquid, and supplying the compressed air at 30 ° C to ferment; And the composition fermented by the second mild fermentation step is transferred to a fermentation tank No. 4 and mixed, and a second mesophilic microorganism culture solution mixed with Aspergillus callestemii and Rhodotorula aurantiaca And a third medium-temperature fermentation step in which a predetermined amount of the microorganism-containing organic fertilizer is fed by supplying compressed air at 30 DEG C to ferment the microorganism-containing organic fertilizer according to the present invention.

The high temperature fermentation step comprises: transferring the fermented composition to the fifth fermentation tank, mixing the fermented mixture with the third medium temperature fermentation step, mixing the mixture with Bacillus megaterium, Streptomyces costaricanus and Thermo Ascus thermophilus A first high temperature fermentation step in which a first thermophilic microorganism culture solution mixed with Thermoascus thermophilus is injected and fermented by supplying compressed air at 45 ° C; A second high temperature fermentation step of transferring and mixing the composition fermented in the first high temperature fermentation step to a fermentation tank No. 6, injecting a predetermined amount of the first thermophilic microorganism culture liquid, and supplying the compressed air at 50 ° C to ferment; A third high temperature fermentation step of transferring the composition fermented in the second high temperature fermentation step to a fermentation tank No. 7, mixing the same, injecting a predetermined amount of the first thermophilic microorganism culture liquid, and supplying compressed air at 50 ° C to ferment; The composition fermented by the third high-temperature fermentation step is transferred to the fermenter No. 8 and mixed, and a second thermophilic microorganism culture solution in which Streptomyces costaricanus and Thermoascus thermophilus are mixed is mixed with a predetermined amount A fourth high-temperature fermentation step of feeding fermentation by supplying compressed air at 50 ° C; The composition fermented by the fourth high temperature fermentation step is transferred to a fermenter No. 9 and mixed. A predetermined amount of a third thermophilic microorganism culture solution containing Thermoascus thermophilus is injected, and 55 ° C compressed air is supplied A fifth high temperature fermentation step in which the fermentation is performed; And a sixth high temperature fermentation step of transferring the composition fermented in the fifth high temperature fermentation step to the fermentation tank 10 and mixing the same, feeding a predetermined amount of the third thermophilic microorganism culture liquid, and feeding the compressed air at 60 ° C. to the fermentation step Another aspect of the present invention is a method for producing an organic fertilizer containing microorganisms according to the present invention.

Wherein the step of growing in the agitating copper comprises a first post-growing step, a temperature lowering step and a second post-growing step, wherein the first post-growing step comprises transferring the composition fermented in the sixth high temperature fermentation step to the fermenter , A predetermined amount of the first thermophilic microorganism culture solution is injected, and compressed air of 50 ° C is supplied to the microorganism and mixed for a predetermined period of time. The method of manufacturing the microorganism-containing organic fertilizer according to the present invention will now be described.

Wherein the first post-fermentation step comprises transferring the sixth hyperthermally fermented composition to the fermentor of the stirred fermenter and mixing the fermented broth with Bacillus megaterium, Streptomyces costaricanus, and Thermo The first thermophilic microorganism culture solution mixed with Asukus thermophilus is injected at a predetermined rate, compressed air is supplied at a temperature of 50 ° C, and the mixture is mixed at a constant rate using a transfer device Another aspect of the present invention relates to a method for producing an organic fertilizer containing microorganisms.

Wherein the temperature lowering step is to lower the temperature by supplying compressed air at 30 DEG C to the composition after the first maturing step and the second maturing step is a step in which the composition of the first mesophilic microorganism is added to the composition after the temperature lowering step And then mixing and supplying compressed air at 25 ° C to adjust the water content. Another feature of the method of manufacturing a microorganism-containing organic fertilizer according to the present invention is as follows.

The present invention solves the problem of gas obstruction by completely fermenting into a production system composed of aged copper and aged copper aged in a continuous fermentation aging step in which a medium and low temperature microorganism culture solution is injected at different temperatures, Containing organic fertilizer and a method of producing the same, which can be expected to improve the gas barrier and promote the growth of crops when used for soil improvement.

FIG. 1 conceptually illustrates a plan layout for one embodiment of a ripening motion in a production system according to the present invention.
FIG. 2 is a cross-sectional view taken along the line AA 'in FIG. 1, showing the structure according to one embodiment of aging.
FIG. 3 conceptually illustrates a plan layout for one embodiment of stirring in a production system according to the present invention.
FIG. 4 is a sectional view taken along the line BB 'of FIG. 3, showing a structure according to an embodiment of stirring.
FIG. 5 conceptually illustrates a side view of a packaging agreement embodiment in a production system according to the present invention.
6 is a flow chart showing a step of fermentation aging in aged copper in an embodiment of the method for producing an organic fertilizer containing microorganisms according to the present invention.
FIG. 7 is a flow chart showing a step of growing in an agitating copper in an embodiment of the method for producing an organic fertilizer containing microorganisms according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The organic fertilizer containing microorganisms according to the present invention is produced in a production system divided into aged copper 100, agitated copper 120 and packed copper 140, 200 as illustrated in Figs. 1 to 5.

The aged copper 100 and the agitating copper 120 are connected to an independent closed space surrounded by the floor 1, the side wall 2 and the roof 3, respectively, as shown in Figs. 2 and 4, ), A malodor reduction apparatus (110) and at least one fermenter (4, 5; 6).

As shown in FIG. 1, the fermentation tank of the aged copper 100 can be divided into two (4, 5) or more, as shown in FIG. 2, The fermentation tanks (2) to (10) may be symmetrically divided into two rows of the same size, facing each other perpendicularly to the longitudinal direction.

1 to 4, the air injection device 20 includes a plurality of long grooves 10 opened at an upper portion of a bottom 1 of the fermenter 4, 5, 6, A plurality of air supply pipes (24) inserted into the grooves, an air distribution pipe (22) connected to one end of the air supply pipe, and an air injector (21) for supplying compressed air to the air distribution pipe .

At this time, a plurality of pores 26 are formed in the air supply pipe 24 inserted in the plurality of long grooves 10 to store the leachate generated in the composition in the long grooves 10, So that the compressed air supplied from the compressed air supply pipe 20 can smoothly discharge the leached water impregnated into the long groove 10 and the air supply pipe 24 to the long groove 10 through the plurality of pores 26, (S) introduced into the composition (S) is also discharged from the long groove (10) together with the leachate to be sprayed to the bottom of the composition (S).

2, it is preferable that the air distribution pipe 22 is connected at a predetermined height higher than the plurality of air supply pipes 24. By doing so, the leachate leaking into the air supply pipe 24 is discharged to the air distribution pipe 22).

2 and 4, a temperature controller 23 may be further provided between the air distribution pipe 22 and the air supply pipe 24 to adjust the temperature of the compressed air.

At this time, the temperature regulating device 23 may be provided so that the compressed air passes through the hot wire or the like and is heated. It is preferable that the temperature of the compressed air to be distributed to the fermenter is controlled differently. The temperature control error range of the temperature regulating device 23 is preferably ± 1 ° C. If the error range is larger than this range, the facility cost may be lowered, but there is a problem that it is difficult to achieve the desired complete fermentation by providing a constant fermentation environment. However, if the error range is smaller than this range, the facility cost increases and the effect becomes ineffective .

By doing so, the temperature of the compressed air can be adjusted for each fermentation tank, thereby providing a condition for complete fermentation.

2, 4 and 5, the fermentation tank 100, the stirring copper 120, and the roof 3 of the packaging dynamic loading chamber 140, which enclose the fermentation tanks 4, 5 and 6 in a closed space, The malodor reduction apparatus 110 may be connected to the malodor reduction apparatus 110. In this case, the malodor reduction apparatus 110 evaporates the leachate from the fermentation tank and sends it out together with the malodorous gas, thereby polluting the environment caused by the discharge of the leachate It is possible to solve the problem fundamentally.

The malodor reduction apparatus 110 includes a chlorine dioxide generator 50 for supplying chlorine dioxide (ClO ₂ ), a gas discharge pipe 40, an exhaust device 60, And one or more line mixers (70) provided between the exhaust pipe (54) and the exhaust device (60), so that the odor can be effectively neutralized and discharged.

As shown in FIGS. 2 and 4, the microbial culture liquid injection pipe 30 is further provided in the longitudinal direction of each aged copper and the stirring copper inside the respective roofs 3 of the aged copper 100 and the agitated copper 120 A plurality of nozzles 32 may be provided in the fermentation tank 4, 5, 6 in the microbial culture fluid injection tube 30. [

At this time, it is preferable that the microorganism culture solution injecting tube 30 is configured such that the microbial culture solution is separately injected for each fermentation tank because the microorganisms having high activity at the temperature controlled by the temperature adjusting device 23 are provided for each fermentation tank It is possible to expect complete fermentation by the microorganism.

The composition of the microorganism-containing organic fertilizer comprises a stock powder and a microorganism culture liquid.

The microbial culture solution is supplied to the microbial culture solution injection tube 30, and it is preferable that the mesophilic microbial culture solution having high activity at 25 to 35 ° C and the heat-resistant microbial culture solution at 40 to 65 ° C are contained.

The microorganism used as the mesophilic microorganism culture solution may be at least one of Pseudomonas protegens, Aspergillus callestemii and Rhodotorula aurantiaca, and the thermophilic microorganism The microorganism used as the culture medium may be one or more of Bacillus megaterium, Streptomyces costaricanus and Thermoascus thermophilus.

Pseudomonas proteogens (ATCC BAA-477) is a rhizosphere microorganism isolated from cultivated soil, antagonistic to crop pathogenic fungi, insoluble phosphate soluble, siderophore, The plant hormone, indole acetic acid, is secreted and promotes plant growth. Chitinase and polymer degrading enzymes are also secreted to decompose organic matter. In addition, since the growth rate is fast due to the presence of bacteria, it is possible to provide an effect of relatively quickly killing bacteria and spoilage bacteria that may be contained in the composition (S).

The Aspergillus callestemii (ATCC MYA-4943) is a soil-borne fungus that is mesophilic and has an antagonistic effect against phytopathogenic bacteria. Therefore, it is possible to provide an effect of effectively killing harmful and pernicious bacteria that may be contained in the composition. In addition, it takes a little time to grow by producing mycelium because it is a fungus and it grows. However, since the mycelium spreads inside the organic material of the composition (S), it is used as an access passage of the thermophilic microorganism in the subsequent high temperature fermentation process, It is expected to provide a physical basis that can be well established.

The above Rhodotorula aurantiaca (ATCC 90775) is a mesophilic fungus with a mildew, and it has the advantage of fermenting lignin biomass to produce organic acids and having antibacterial activity against phytopathogenic bacteria have. Therefore, it is expected that not only the harmfulness which may be contained in the composition and the death of the pernicious bacteria but also the rapid proliferation by yeast-like propagation method, the rapid decomposition of organic matter at middle temperature is expected.

The above-mentioned Bacillus megaterium (ATCC 15374) is a soil microorganism having high temperature, heat resistance, antifungal activity against phytopathogenic fungi, and endospore production, which is useful for high temperature fermentation. Also, since the growth rate is fast, it is possible to effectively decompose the organic matter and the refractory organic matter remaining in the composition in the early high temperature fermentation step, and is expected to be useful also in the death of the thermophilic pathogenic fungi.

The Streptomyces costaricanus (ATCC 55274) is a soil rhizospheric actinomycetes, which has high temperature, heat resistance, antifungal activity against phytopathogenic fungi, and has the advantage of activity of xylenolytic enzyme which is a degradable carbohydrate. Therefore, it is anticipated that actinomycetes grow relatively fast, killing of pathogenic fungi, and rapid decomposition of degradable organics.

The Thermoascus thermophilus (ACTT 26413) is a soil fungus fungus, which is resistant to heat and has the advantage of releasing an enzyme capable of degrading carbohydrate. It is expected to be able to maintain the decomposition of degradable organic matter even if the temperature is elevated by the high temperature fermentation because it is fungus and it grows mycelium and it grows somewhat late but can control the relatively wide region.

The mesophilic microorganism culture solution is prepared by diluting a mixed microbial powder containing Pseudomonas proteens, Aspergillus calescimentii and Rhodotorula aurantiaca at a concentration of 1 x ¹⁰ < ^-6 > ^{to 7} cfu / g, A mixed microbial powder containing 1x10 < ^-6 > ^{to 7} cfu / g of Aspergillus calescimentii and Rhodotorula aurantiacca as a culture medium for sex sterilization was diluted 400 to 600 times with water to prepare a second mesophilic microorganism culture solution, And the like.

The thermophilic microorganism culture solution is prepared by diluting a mixed microbial powder containing Bacillus megaterium, Streptomyces Costa Ricanus and Thermo Ascus thermophilus at a concentration of 1 x ¹⁰ < ^-6 > ^{to 7} cfu / g, A mixed microorganism powder containing 1x10 < ⁶ > ^{to 7} cfu / g of Streptomyces Costa Ricanus and Thermo Ascus Thermophilus as a microbial culture solution was diluted 400-600 times with water to prepare a second thermophilic microorganism culture solution, The microbial powder containing 1 x ¹⁰ < ⁶ > ^{to 7} cfu / g of the thermophilus may be diluted 400 to 600 times with water to be used as the third microbial culture solution in the manufacturing process described below.

Of course, a mixed microbial powder containing Bacillus subtilis at a concentration of 1 x ¹⁰ < ^-6 > ^{to 7} cfu / g may be diluted to 400 to 600 times with water. Bacillus subtilis is known as Bacillus subtilis, which anaerobically metabolizes various saccharides such as glucose, starch and the like, but also decomposes pectin and polysaccharides of organic substances such as plant tissues, and especially degradable carbohydrates such as cellulose, hemicellulose and lignin It has excellent resolution.

Each of the mixed microbial powders may contain an appropriate amount of lactic acid bacteria, yeast, photosynthetic bacteria, actinomycetes and filamentous bacteria useful for vegetation.

In addition, when each of the strains contained in each of the mixed microbial powders contains less than 1 × 10 ⁶ to 10 ⁷ cfu / g, a proper dilution amount of water becomes small, This is not easy. It is most preferable that each of the mixed microbial powders is diluted 500 times in water.

The above-mentioned shaft fraction may be used as a flour, cow's milk, pig flour, etc., and it may be used as the recovered shaft fraction itself, but it is preferable to use a product having a water content of 60% or less. These nutrients contain various organic substances and nutrients such as insoluble proteins, carbohydrates, etc., and are supplied as a major source of organic matter required for plant growth after fermentation.

The composition of the organic fertilizer may include a part of sawdust, coffee ground, and other soil (minerals) in addition to the above-mentioned starch and microorganism culture solution. Here, the coffee bean is a by-product produced after extracting the coffee bean after the boiling of the coffee bean during the production of the coffee, and the soil may be a zeolite having a property of selectively adsorbing unsaturated hydrocarbons or polar substances.

In a concrete example, the composition of the organic fertilizer may be composed of 35% by weight of hemp, 20% by weight of fowl, 5% by weight of pig powder, 35% by weight of sawdust, 3% by weight of coffee bean, 1% by weight of microorganism culture and 1% by weight of zeolite have.

Specific structural examples of the aged copper (100), the agitating copper (120) and the copper copper (140, 200) will be described.

First, as shown in Fig. 1, the fermentation copper (100) has one preparation vessel (1) and nine fermentation tanks (4, 5; 2 to 10) facing each other perpendicularly to the longitudinal direction, . ≪ / RTI >

9 fermentation tanks (4, 5; ② to 10) of the aged copper 100 are deposited and fermented in each fermentation tank for a predetermined period of time, transferred to a neighboring fermentation tank, mixed and fermented into the microorganism culture liquid , The fermentation is carried out in the order of (2) to (10) as shown in FIG. 1), and the fermentation is preferably performed for a certain period of time in the fermentation copper (100).

Unlike the fermentation tanks 4 and 5 (② to ⑩), the preparation tank (1) is a place where a variety of materials used as a raw material of the composition (S) (10) may not be formed.

3 and 4, one or more fermentation tanks (6) are longitudinally divided, and a rail (96) is provided on both side walls (6) of the fermentation tanks The front and rear conveying devices 90 are fastened to the rails 96 and the vertical movement of the rotary shaft 82 to which the stirring arm 84 is attached to the predetermined frame 83, 81, and 85 may be fastened to each other.

4, the stirring arm 84 is horizontally moved along the rails 96 by the back and forth conveying device 90, and is rotated by the up and down moving and rotating means 81, (S) and is rotated by a predetermined driving shaft (82) to stir the uniform composition (S).

5, the packed copper is divided into a loading chamber 140 and a packing chamber 200, and a part of the bottom 1 of the middle separation sidewalls of the loading chamber 140 and the packing chamber 200, A collecting space 144 is formed in a hopper shape below and a collecting space 144 is provided with a first conveyor 212 for receiving a raw material and transferring the raw material to the packing chamber 200, And a hopper type crusher 210 is provided at an end of the crusher 210. The crusher is connected to the separator 220 through a second conveyor 222 and a third conveyor 228 is disposed in front of the separator, The fourth conveyor 231 is connected to both the mass distributor 230 and the small-volume distributor 240 through the fifth and sixth conveyors 242 and 232, .

1 to 5, a method of manufacturing a microorganism-containing organic fertilizer according to the present invention is a method of producing a microorganism-containing organic fertilizer according to the present invention, wherein the production system is divided into the above-mentioned aged copper 100, agitated copper 120 and packed copper 140, Fermenting in the fermentation copper 100 as a whole; Growing in the stirring copper 120; And storing and packing the same in the packaging machine (140, 200).

The step of fermenting the fermented copper 100 in the fermentation broth 100 includes the preparation of the composition (S100), the fermentation at the middle temperature (S200) and the fermentation at the high temperature (S300), as shown in FIG. 6 , It is possible to perform efficient and complete fermentation by dropping the appropriate microorganism culture solution under the temperature condition of the step.

That is, at the mid-temperature fermentation step (S200), harmful and perishable bacteria or fungi that may be contained in the organic matter of the composition (S) are removed at an early stage by adding a mesophilic culture medium having high activity at 25 to 35 ° C, It is possible to provide a space required for high temperature fermentation.

The high-temperature fermentation step (S300) removes harmful bacteria and fungi of high temperature, which may be contained in the organic matter of the composition (S), by adding a heat-resistant, high temperature microorganism culture solution at 40 to 65 ° C, It kills the pathogens and parasites contained in it and makes them fully fermented.

Specifically, the mid-temperature fermentation step (S200) is preferably divided into the first and second mesophilic microorganism cultures and added in each fermentation tank. By doing so, the first mesophilic microorganism culture liquid provides the proliferation time of the fungus having a relatively slow growth rate, and at the same time, the microorganisms such as bacteria are killed by using bacteria and yeasts showing rapid proliferation, And the second mesophilic microorganism culture solution is composed of a mixture of yeast and fungi to complete the removal of bacterial harmful microorganisms and to open a physical pathway inside the organic matter.

The high-temperature fermentation step (S300) is also preferably divided into the first to third thermophilic microorganism cultures and added in each fermentation tank. Thus, by the first thermophilic microorganism culture solution, the initial high temperature fermentation is initiated by using the bacterium which first proliferates actinomycetes and fungi having a relatively slow growth rate and exhibits rapid proliferation, and at the same time, It is possible to kill harmful microorganisms such as sexually transmitted bacteria.

More specifically, in the mid-temperature fermentation step (S200), as shown in FIGS. 1 and 6, the prepared composition (S) such as syrup or sewage sludge is prepared in the preparation preparation step (S100) 2) and mixed, and a first mesophilic microorganism culture solution in which Pseudomonas protegens, Aspergillus callestemii and Rhodotorula aurantiaca are mixed is injected, A first intermediate temperature fermentation step (S210) for supplying the compressed air at 30 DEG C through a temperature controller (23) to ferment; (S) fermented in the first intermediate temperature fermentation step is transferred to a fermenter (3) 3, mixed with a predetermined amount of the first mesophilic microbial culture solution, fed with compressed air at 30 ° C, Fermentation step (S220); And the composition (S) fermented by the second mild fermentation step are transferred to and mixed with the fermenter (4) 4 and mixed with Aspergillus callestemii and Rhodotorula aurantiaca A third mesophilic fermentation step (S230) in which a predetermined amount of the second mesophilic microbial culture solution is poured and 30 ° C of compressed air is supplied for fermentation.

The feeding of the compressed air at 30 ° C in the mid-temperature fermentation step (S200) is performed by adjusting the activation conditions of the mesophilic microorganism by the first and second mesophilic microorganism culture medium, and the high temperature fermentation is too early To prevent the occurrence of harmful microorganisms, and to enable effective microbial death.

1 and 6, the fermented composition (S) fermented in the third intermediate fermentation step is transferred to the fifth fermenter (5) and mixed with the Bacillus megaterium megaterium, Streptomyces costaricanus and Thermoascus thermophilus, and the first high temperature fermentation which is fermented by supplying compressed air at 45 ° C. Step S310; The composition (S) fermented in the first high temperature fermentation step is transferred to a fermentation tank (6) and mixed. A predetermined amount of the first thermophilic microorganism culture liquid is poured, and a second high temperature Fermentation step (S320); The composition (S) fermented in the second high-temperature fermentation step is transferred to and mixed with the fermentation tank (7), and a predetermined amount of the first thermophilic microorganism culture liquid is injected. The third high temperature fermentation Fermentation step (S330); The composition (S) fermented in the third high-temperature fermentation step is transferred to a fermenter (No. 8) (⑧) and mixed, and the mixture of Streptomyces costaricanus and Thermoascus thermophilus A fourth high temperature fermentation step (S340) of injecting a certain amount of the thermophilic microbial culture solution and fermenting by supplying compressed air at 50 DEG C; The composition (S) fermented in the fourth high temperature fermentation step is transferred to a fermenter (9) No. 9, mixed with a predetermined amount of a third thermophilic microorganism culture solution containing Thermoascus thermophilus, (S350), wherein the fermentation is performed by supplying compressed air at a temperature of 50 to < 0 >C; And a fermented composition (S) fermented in the fifth high temperature fermentation step are transferred to and mixed with the fermentation tank (10), and a predetermined amount of the third thermophilic microorganism culture liquid is injected. And a high temperature fermentation step (S360).

At this time, the temperature of the compressed air gradually increases from 45 ° C to 60 ° C in the high-temperature fermentation step (S300) as described above, so that the microorganisms can not adapt to a given environment due to rapid temperature increase due to high temperature fermentation In addition, the thermophilic microorganisms are activated in harmony with each other at the respective temperatures, and the functional and physical transitions are efficiently performed according to the gradual increase in temperature. In other words, bacteria grow rapidly, leading to early high-temperature fermentation, followed by actinomycetes, which are activated at a higher temperature, while fungi slowly grow and become activated at higher temperatures.

As described above, when high-temperature fermentation is carried out at 45 ° C for a certain period of time in the fermentation tank 5, the mesophilic microorganisms used in the mid-temperature fermentation step S200 are gradually physiologically inactivated and become a resting state, The microbes (bacteria, actinomycetes, fungi) contained in the first thermophilic microorganism culture fluid are proliferated and functional and physical transitions with the mesophilic microorganisms are performed, so that the high temperature fermentation can be stably activated. In particular, the high temperature fermentation by Bacillus megaterium, which is a fast growing bacterium, and Streptomyces Costa Ricanus, which is the next fastest actinomycetes, can be effectively initiated and proceeded. At the same time, Thermo Ascus thermophilus, a fungus with relatively slow growth rate, And the proliferation is gradually started.

In addition, since various plant pathogenic microbial control substances are secreted from the thermophilic microorganisms to which they are administered, the microbes are accumulated in the composition (S) as well as the effect of killing potentially harmful harmful microorganisms. Therefore, The growth inhibition and killing effect of the pathogenic microorganism of the crop can be expected.

Thereafter, in the second and third high temperature fermentation steps (S320 and S330) proceeding in the sixth and seventh fermentation tanks (6, 7), the temperature is adjusted to 50 ° C so that full- The culture solution is added so that sufficient thermophilic microorganisms are proliferated and high-temperature fermentation is activated.

Therefore, when the second and third high-temperature fermentation steps (S320, S330) are performed, Bacillus megaterium, which is a fast growing bacterium, is sufficiently proliferated and activated, so that it is economically preferable not to further input at the subsequent high- Do.

Next, in the fourth high temperature fermentation step (S340) proceeding in the fermentation tank 8 (8), the temperature is adjusted to 55 캜 so as to proceed the high temperature fermentation at a higher temperature. For this reason, the thermophilic actinomycetes and fungi 2 < / RTI > thermophilic microorganism.

By doing so, the introduced thermophilic microorganisms can be physiologically adapted so that high-temperature fermentation can be performed at a higher temperature, so that the highest input efficiency can be reconsidered.

Thereafter, in the fermentation tanks 9 and 10, the third thermophilic microorganism culture fluid composed of fungi is administered and the temperature of the compressed air is adjusted to 60 ° C, whereby high-temperature fermentation can be effectively performed, In addition, it is possible to kill parasitic algae of the axillae.

The fermentation time (fermentation period) in each of the fermentation tanks in the middle temperature fermentation step (S200) and the high temperature fermentation step (S300) may vary depending on the scale of the composition (S) It is preferable to ferment for 3 days. In addition, the amount of each microorganism culture solution injected may be determined in an amount assigned to each fermentation tank within a range of 1 to 2 wt% of the total composition. For example, when the total composition is 10 tons, a culture medium of 100 to 200 kg of microorganism is added. Therefore, when passing through 10 fermentation tanks including one fermentation tank with stirring, 10 to 20 kg of microorganism culture solution is sprayed per fermentation tank. The injection time of the compressed air by the air injector 20 can be determined in consideration of the target water content of the final organic fertilizer, the amount of the microbial culture liquid injected into each fermentation tank, and the amount of evaporation of the compressed air in each fermentation tank.

The step S400 of growing in the stirring copper 120 may be performed after the composition S provided through the mid-temperature fermentation step S200 and the high-temperature fermentation step S300 contains the inorganic nutrients N , P, K) and trace elements (Mg, Mn, Cu, B, Mo, etc.), and the microorganisms used in the present manufacturing process can be utilized as rhizosphere microorganisms in the cultivation soil.

To this end, the sleeping step S400 may include a first maturing step S410, a temperature lowering step S420, and a second maturing step S430, as shown in FIG.

In the first sowing step S410, the composition S fermented in the sixth high temperature fermentation step is transferred to the fermentation tank 6 of the stirring copper 120, and the fermented product of Bacillus megaterium, Streptomyces Costa Ricanus, and Thermo A certain amount of the first thermophilic microorganism culture solution mixed with Ascus thermophilus may be injected, and compressed air of 50 캜 may be supplied and mixed to be maintained for a certain period of time.

The temperature lowering step S420 is a step of lowering the temperature by supplying compressed air at 30 DEG C to the composition S which has undergone the first roughening step and the second roughening step S430 is a step of cooling the composition S) is mixed with Pseudomonas proteens, Aspergillus calescimentii and Rhodotorula aurantiaca, and the mixture is supplied with compressed air at 25 ° C. to adjust the water content of the final organic fertilizer ≪ / RTI >

The fermentation time in the fermentation tank (fermentation period (fermentation period), fermentation period (fermentation period), and fermentation period (fermentation period) are the same in the first mature stage S410 and the second mature stage S430 ), The injection amount of each microorganism culture liquid and the injection time of compressed air can be determined.

The composition S is changed to a middle temperature of about 25 캜 at a high temperature to allow the thermophilic microorganisms to adapt to the middle temperature to survive and to physically inactivate or die in the high temperature fermentation step By replenishing with the injection of the first mesophilic microbial culture liquid, it becomes possible to play a role as rhizosphere microorganism in the soil.

The method for producing an organic fertilizer containing microorganisms according to the present invention can provide a microorganism-containing organic fertilizer having a water content of 55% or less, preferably 30% or less. In addition, it is possible to contain physiologically stabilized rhizospheric microorganisms, and it is possible to use the amino acids, nucleic acids, organic acids, vitamins, and corrosion as well as essential nutrients (N, P, K) contained in the organic fertilizer It is possible to restore the microorganism, effectively kill the parasitic eggs in the crop pathogenic microorganisms and the shrubs in the cultivation soil, and solubilize the insoluble salts in the soil.

10: floor groove of the floor 20: air injection device
30: microorganism culture liquid injection tube 40: gas discharge tube
50: chlorine dioxide generating device 60: exhaust device
70: line mixer 80: stirring device
90: forward and backward conveying device 100:
110: odor reducing apparatus 120: stirrer
140: Loading chamber 200: Packing chamber

Claims (10)

A fermentation aging step in which the aging copper, the agitating copper and the copper copper are divided into a production system and a fermentation copper; Growing in the stirring copper; Wherein the step of fermenting and aging the fermentation broth comprises the steps of: preparing a composition, preparing a fermentation medium, and fermenting the fermentation at a high temperature; As a result,
In the aged copper, one preparation vessel and nine 2 to 10 fermentation vessels are symmetrically divided into two rows of the same size facing each other perpendicularly to the longitudinal direction,
The stirring copper is characterized in that at least one fermenter is longitudinally divided,
The medium-temperature fermentation step may be carried out by transferring the composition prepared in the composition preparation step from the preparation tank to the fermentation tank No. 2, mixing the Pseudomonas proteogens, Aspergillus callestemii and Rhodotorula aurantia A first mesophilic fermentation step in which a first mesophilic microorganism culture solution mixed with Rhodotorula aurantiaca is injected and the mixture is fed by supplying compressed air at 30 ° C;
A second mesophilic fermentation step of transferring the composition fermented by the first intermediate temperature fermentation step to a fermentation vessel No. 3, mixing the same, feeding a predetermined amount of the first mesophilic microorganism culture liquid, and supplying the compressed air at 30 ° C to ferment; And
The composition fermented by the second mild fermentation step is transferred to a fermentation tank No. 4 and mixed, and a second mesophilic microorganism culture solution mixed with Aspergillus callestemii and Rhodotorula aurantiaca And a third intermediate temperature fermentation step in which a predetermined amount of the microorganism is injected and fermented by supplying compressed air at 30 ° C.
The method according to claim 1,
Wherein the aged copper and the agitation copper each include an air injection device, a malodor reduction device, and at least one fermenter in independent closed spaces surrounded by a floor, a side wall, and a roof,
Wherein the air introducing device includes a plurality of long grooves which are opened at the bottom of the fermenter, a plurality of air supply pipes respectively disposed in the plurality of long grooves, an air distribution pipe connected to the plurality of air supply pipes, And a temperature control device for controlling the temperature of the compressed air is further provided between the air supply pipe and the air distribution pipe,
A microbial culture fluid injection tube having a plurality of nozzles facing the fermentation tank is installed inside each of the aged copper and the roof of the agitation copper,
Wherein the composition of the microorganism-containing organic fertilizer comprises a starch and a microorganism culture liquid,
The temperature control device is configured to control the temperature of compressed air differently depending on the fermentation tank,
Wherein the microbial culture fluid injection tube is configured to inject a microbial culture fluid into the fermentation tank.
3. The method of claim 2,
The microbial culture solution supplied to the microorganism culture solution inlet tube and constituting the composition of the microorganism-containing organic fertilizer may be selected from the group consisting of Pseudomonas protegens, Aspergillus callestemii, Rhodotorula aurantiaca, At least one of Bacillus megaterium, Streptomyces costaricanus, Thermoascus thermophilus and Bacillus subtilis is 1 x ^{10 6 to 7} cfu / g of the microorganism powder is diluted 400 to 600 times with water.
The method of claim 3,
A rail is provided above both sidewalls of the fermentation tank for stirring,
The front and rear transfer devices are fastened to the rails,
Wherein the front and rear conveying apparatuses are provided with an agitating device having a stirring frame provided with a vertically moving and rotating means for the stirring arm.
5. The method according to any one of claims 1 to 4,
The composition of the organic fertilizer contains 35 wt.% Of weeds, 20 wt.% Of fowl, 5 wt.% Of fowl, 35 wt.% Of sawdust, 3 wt.% Of coffee beans and 1 wt.% Of a microbial culture and 1 wt.% Of other zeolite Wherein the organic fertilizer is a microorganism-containing organic fertilizer.
delete A fermentation aging step in which the aging copper, the agitating copper and the copper copper are divided into a production system and a fermentation copper; Growing in the stirring copper; And a step of storing and packing in the packed copper, wherein the step of fermenting and aging in the aged copper comprises a composition preparation step, a middle temperature fermentation step and a high temperature fermentation step,
In the aged copper, one preparation vessel and nine 2 to 10 fermentation vessels are symmetrically divided into two rows of the same size facing each other perpendicularly to the longitudinal direction,
The stirring copper is characterized in that at least one fermenter is longitudinally divided,
The medium-temperature fermentation step comprises:
The composition prepared in the composition preparation step is transferred from the preparation tank to the fermentation tank No. 2 and mixed. Then, Pseudomonas protegens, Aspergillus callestemii and Rhodotorula aurantiaca A first mesophilic fermentation step in which a mixed medium of the first mesophilic microorganism is injected and fermented by supplying compressed air at 30 ° C;
A second mesophilic fermentation step of transferring the composition fermented by the first intermediate temperature fermentation step to a fermentation vessel No. 3, mixing the same, feeding a predetermined amount of the first mesophilic microorganism culture liquid, and supplying the compressed air at 30 ° C to ferment; And
The composition fermented by the second mild fermentation step is transferred to a fermentation tank No. 4 and mixed, and a second mesophilic microorganism culture solution mixed with Aspergillus callestemii and Rhodotorula aurantiaca And a third intermediate temperature fermentation step in which a predetermined amount of the microorganism is injected and fermented by supplying compressed air at 30 ° C.
8. The method of claim 7,
Wherein the high temperature fermentation step comprises:
The composition fermented by the third intermediate temperature fermentation step was transferred to a fermenter No. 5 and mixed and mixed with Bacillus megaterium, Streptomyces costaricanus and Thermoascus thermophilus A first high temperature fermentation step of pouring the first thermophilic microbial culture solution and feeding it with compressed air at 45 ° C;
A second high temperature fermentation step of transferring and mixing the composition fermented in the first high temperature fermentation step to a fermentation tank No. 6, injecting a predetermined amount of the first thermophilic microorganism culture liquid, and supplying the compressed air at 50 ° C to ferment;
A third high temperature fermentation step of transferring the composition fermented in the second high temperature fermentation step to a fermentation tank No. 7, mixing the same, injecting a predetermined amount of the first thermophilic microorganism culture liquid, and supplying compressed air at 50 ° C to ferment;
The composition fermented by the third high-temperature fermentation step is transferred to the fermenter No. 8 and mixed, and a second thermophilic microorganism culture solution in which Streptomyces costaricanus and Thermoascus thermophilus are mixed is mixed with a predetermined amount A fourth high-temperature fermentation step of feeding fermentation by supplying compressed air at 50 ° C;
The composition fermented by the fourth high temperature fermentation step is transferred to a fermenter No. 9 and mixed. A predetermined amount of a third thermophilic microorganism culture solution containing Thermoascus thermophilus is injected, and 55 ° C compressed air is supplied A fifth high temperature fermentation step in which the fermentation is performed; And
And a sixth high temperature fermentation step in which the composition fermented by the fifth high temperature fermentation step is transferred to and mixed with the fermentation tank No. 10, the predetermined amount of the third thermophilic microorganism culture liquid is injected, and the compressed air is supplied at 60 ° C. Wherein the microorganism-containing organic fertilizer is a microorganism-containing organic fertilizer.
9. The method of claim 8,
Wherein the step of growing in the agitating copper comprises a first post-growing step, a temperature lowering step and a second post-growing step,
The first fermentation step is a step of transferring the composition fermented in the sixth high temperature fermentation step to the fermentation tank of the stirring fermenter, injecting a certain amount of the first thermophilic microorganism culture liquid, supplying compressed air at 50 ° C, ≪ / RTI > wherein the organic fertilizer comprises a microorganism.
10. The method of claim 9,
The temperature lowering step is to lower the temperature by supplying compressed air at 30 DEG C to the composition after the first maturing step,
Wherein the first mesophilic microorganism culture solution is injected into the composition after the temperature lowering step and the moisture content is controlled by supplying compressed air at 25 ° C. and mixing the composition with the microorganism containing organic fertilizer .

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