KR20100022968A - Bacillus megaterium bc1-1 kccm 10856p reducing nasty odor and heavy metal and clarification methods for resource recovery from food waste or livestock waste water by using it - Google Patents

Abstract

PURPOSE: A composition containing a novel Bacillus megaterium BC1-1 is provided to quickly remove odor and heavy metals contained in livestock waste water or food waste and to produce livestock feed from food waste. CONSTITUTION: A novel Bacillus megaterium BC1-1 KCCM 10856P which is useful in removing odor and heavy metals is isolated from mushroom and spawn existing near fallen leaves in the forest. A microorganism formulation for removing odor and heavy metals contains Bacillus megaterium BC1-1(KCCM 10856P), Bacillus megaterium BC1-2(KCCM 10857P), Bacillus megaterium BC2-1(KCCM 10858P), Bacillus cereus BC3(KCCM 10859P), Bacillus licheniformis BC4(KCCM 10860P), Bacillus cereus BC5(KCCM 10861 P), Bacillus sphaericus BC6(KCCM 10862 P), Bacillus firmus BC9(KCCM 10865P), and Bacillus cereus BC10(KCCM 10866P).

Description

BACILLUS MEGATERIUM BC1-1 KCCM 10856P REDUCING NASTY ODOR AND HEAVY METAL AND CLARIFICATION METHODS FOR RESOURCE RECOVERY FROM FOOD WASTE OR LIVESTOCK WASTE WATER BY USING IT}

An object of the present invention is to provide a microorganism that reduces odors and heavy metals of livestock wastewater and food waste.

It is also an object of the present invention to provide a method for producing organic liquid fertilizer using livestock wastewater and a livestock feed production method using food waste.

The present invention relates to a microorganism for reducing odor generated from wastewater or food waste generated in livestock raising and heavy metals in the wastewater and garbage, and to a method for purifying livestock wastewater or food waste using the same.

Odors generated during livestock manure storage in the pit of the barn, and the resulting odors, which are harmful to both livestock and humans, are mostly global warming gases. It is a substance. These odors are mainly caused by livestock stocks, and their general composition shows that degradable substances such as carbohydrates, starches, proteins and cellulose are easily decomposed by microorganisms, and fats and lignin which are not easily degraded by microorganisms. It can be classified as a hardly decomposable substance.

In addition, the odor components generated when the nutrient is decomposed in the aerobic state are ammonia, methylmecaptan, hydrogen sulfide, methyl sulfide, methyl disulfide, trimethylamine, acetaldehyde, styrene, propionic acid, butyric acid and gil acetic acid. Odors come in many forms. For example, methylmecaptan is a rotten onion smell, hydrogen sulfide is a colorless gas, irritating, suffocating and rotting onion, and ammonia is a colorless gas that is irritating and has a characteristic odor like urine. If you do so, you will get a disgusting hygiene and inhibit livestock growth.

Odor discomfort continues to increase at present, and legal regulations have been enacted and enforced to raise the importance of odor management. Odors are reported as livestock wastewater treatment plants, food waste treatment plants, manure treatment plants, landfills, and feed manufacturing industries. However, the odor generated in such a facility is not generated only in some processes but is generated in the entire process, and there is a great difficulty in process management, facility improvement, and prevention facility installation to reduce odor occurrence. In addition, since such environmental basic facilities are mainly mixed with residential areas, it is necessary to develop highly efficient odor reduction technology to minimize the impact on the surroundings.

Legal regulations on odors currently include hydrogen sulfide (H ₂ S), methyl mercaptan (CH ₃ SH), methyl sulfide ((CH ₃ ) ₂ S), methyl disulfide ((CH ₃ ) ₂ S ₂ ), ammonia (NH ₃ ), trimethylamine ((CH ₃ ) ₃ N), acetaldehyde (CH ₃ CHO), styrene (C ₆ H ₅ CH = CH ₂ ) is carried out for eight items, these components are compared with other organic compounds Otherwise, it is known to have a strong smell even at low concentrations. In particular, the odor generated in the barn such as pigs, barn, cages, etc., hydrogen sulfide (H ₂ S) is the main pollutant, but in addition, ammonia (NH ₃ ), methyl mercaptan (CH ₃ SH), trimethylamine ((CH ₃ ) ₃ N) and contains a substance such as a lower fatty acid to thereby increase the strength of odor.

In general, malodorous substances cause various malodorous compounds by their source, causing malodors. As a single compound, hydrogen sulfide (H ₂ S) smells like rotting eggs, and mercaptan smells like rotting vegetables. The amines have a peculiar smell like fish smell.

As a method of removing odors, there are largely a method of separating or destroying odorous substances, such as oxidation, enzymatic decomposition, and adsorption, and so-called masking, which simply hides odors. Oxidation has been suggested to oxidize and decompose odorous substances and to remove odors fundamentally with a wide range of bactericidal effects on bacteria, fungi and viruses. The types of oxidants that have been widely used in chemical oxidation methods include chlorine dioxide (duozone), sodium hypochlorite (Lax), and chlorine dioxide, but these substances contain chlorine and may have harmful effects on humans and livestock. . Enzymatic digestion is a deodorant made by extracting plant extracts, but it is easy to decompose odors.However, the specific ingredients and the principle of action are not known precisely. When used for a certain time, the efficiency decreases due to the rapid decrease of the surface area of the adsorbent. The masking method solves the sensory odor problem by dissolving natural or artificial flavors in a volatile solvent such as methyl alcohol and then volatilizing it in the air, but it is not a fundamental solution to the odor.

Although there is a method of using ozone or ultraviolet light alone or in combination as a method without using chemicals, ozone has a sterilizing and deodorizing effect, but excessive generation of ozone may act as a new pollutant. In addition, a method of decomposing odor sources using photocatalysts such as TiO ₂ with ozone generation has been proposed, but catalysts such as TiO ₂ have limitations in increasing the specific surface area, as well as hydrogen sulfide (H ₂ S) and methyl mercaptan (CH _3). When interacting with sulfides such as SH), methyl sulfide ((CH ₃ ) ₂ S), and methyl disulfide ((CH ₃ ) ₂ S ₂ ), the catalyst surface is easily poisoned and the catalyst efficiency decreases drastically. .

In general, odor, benzene, toluene, and xylene in various industrial sites such as petrochemical plant, urban sewage / manure treatment plant, rubber manufacturing plant, painting plant, food processing plant, livestock manure treatment plant, and manure treatment plant. Volatile organic compounds (VOCs) such as BTX, organic acids, aldehydes, ketones, and aromatic compounds are generated in large quantities at the same time, which causes delays in the construction of factories necessary for industrial development due to surrounding complaints. Construction of sewage treatment plants and landfills is delayed.

Removal of odors and volatile organic compounds (VOCs) generated in industrial sites can be largely divided into chemical and biological methods. The chemical method of combustion produces secondary air pollution, and the adsorption method is uneconomical due to the use of expensive activated carbon. These methods cost a lot of money due to excessive chemical consumption instead of low construction costs. On the other hand, biological methods have disadvantages in that construction costs and operating conditions are difficult, but they are easy to maintain and manage and consume less operating costs. Biological odor removal methods include biofilters filled in reactors by immobilizing malodor-decomposing microorganisms on a carrier, and biofilters have emerged as an odor treatment method that is economical and does not cause secondary pollution. The operating costs for operating the biofilter system are the most economical. Operation costs are high in order of biofilter, chemical liquid cleaning, catalytic combustion, activated carbon adsorption, and direct combustion.

Korean Patent Application No. 10-1996-0025606 (filed June 29, 1996) relates to a fermentation agent composition and a composting method for biological treatment of food wastes, high temperature resistant filamentous fungi; High temperature resistant and high temperature proteins belonging to Bacillus bacteria and oil-fat decomposition bacteria; Thermophilic fungi; Provided is a fermentation agent composition for fast fermentation treatment of food waste containing high temperature resistant actinomycetes adapted to high temperature.

Korean Patent No. 292879 (filed April 7, 1999) relates to a microbial preparation for condensation treatment and a method of treating condensate using the same, and has an excellent ability to secrete carbohydrates and protein processing enzymes of condensate (Bacillus subtilis ( Bacillus subtilis) subtilis KCTC 1028) and a microbial agent composed of photosynthetic microorganisms (Rhodopseudomonas sp., photosynthetic microorganisms deposited as KCTC 8937P with the Korea Institute of Science and Technology Gene Bank) with the ability to remove odors as a source of nutrients The microbial agent is applied to livestock and livestock to remove odors, and consequently provides a method for treating livestock, which has a function of improving the growth environment of livestock and the living environment of livestock farmers.

Korean Patent No. 378667 (filed Aug. 31, 2000) relates to a method for rapid deodorization and composting and composition of livestock manure, and is a decay odor generated in the early stages of decay such as odor or food waste generated from livestock manure. The present invention relates to a composition and a method for manufacturing the same, which are used to remove the organic matter and rapidly fermentatively decompose to form an odorless organic fertilizer. Streptomyces sp., Bacillus sp., Micrococcus sp., Achromobacter sp., Flavobacterium sp. One or more strains selected from the genus Escherichia sp. And Pseudomonas sp. Are aerobicly cultured in common liquid media such as neutrient or TSB media to select them from limestone powder, bentite clay or humus soil. An odorless composition obtained by adsorbing on an adsorption medium and then drying is provided.

Korean Patent No. 433268 (filed Oct. 5, 2000) relates to a fermentation agent composition for biological treatment of malodorous substances and a method for producing the same, and includes a high temperature organic substance and a high temperature resistant malodorous filamentous fungus; Filamentous fungi with consideration of substrate transition and excellent odor availability; Substrate degrading bacteria and odor useful bacteria belonging to Bacillus bacteria having high temperature and high temperature and broad substrate availability; The present invention relates to a fermentation agent composition comprising a microorganism for malodorous oil containing a high temperature resistant actinomycetes adapted to high temperature while being adapted to a high concentration of organic matter, and a method of manufacturing the same. The high temperature odor-resistant filamentous fungus is Aspergillus niger , Aspergillus oryzae , Penicillium spp., Mucor spp., Tricho At least one mixed bacterium selected from the group consisting of Trichoderma viride , Cephallosporium acremonium , and Issatchenkia orientalis is preferred, and the substrate transition relationship The filamentous fungi that are highly contemplated and odor-soluble are at least one selected from the group consisting of Candida spp., Arthrobacter spp., And Nocardia spp. Mixed bacteria were used. Substrate decomposing bacteria and odor useful bacteria belonging to the Bacillus bacterium, having high temperature resistance and high temperature, and broad substrate availability, were found in Bacillus subtilis. Odor -10 (Bacillus subtilis CH-10) , Bacillus mesen Terry carcass (Bacillus mesentericus), Bacillus mega emitter Solarium (Bacillus megaterium), Bacillus piece you miss formate enel alahyi -33 (Bacillus licheniformmis NLRI-33) , Bacillus turing if N-Sys ( Bacillus thuringiensis ), one or more mixed bacteria selected from the group consisting of Bacillus circulans was used, the thermophilic actinomycetes adaptable to the high concentration organic matter, Thermoactinomyces sp. And / or thermomonspora spp. And, the high temperature resistant actinomycetes adapted to the high temperature while being adaptable to the high concentration organic material, Streptomyces griseus , Streptomyces globisporius , Streptomyces flavus as Streptomyces flavus It is preferable that it is at least one mixed bacterium selected from the group consisting of, and the above-mentioned substrate degrading bacteria and odor useful bacteria having broad substrate availability are Pseudomonas putida NLRI-X50 and Corynebacterium. Corynebacterium spp., Staphylococcus lentus ( Staphylococcus lentus ), Micrococcus lylae ( Micrococcus lylae ) is one or more selected from the group consisting of mixed bacteria is said to be preferable.

Korean Patent Application No. 10-2005-0044120 (filed May 25, 2005) relates to an air purifier for removing odors and yellow dust in barns and has been applied to remove odors using a Bacillus subtilis.

Korean Patent Application No. 10-2006-0032543 (filed April 11, 2006) discloses a method for efficiently treating malodorous waste gas using a hybrid system process including a photocatalytic reactor, a fluidized bed aerobic system, and an anaerobic tank and a biofilter. The device has been filed.

Korean Patent Application No. 10-2004-0011349 (filed February 2, 2004) provides a biofilter to which the strain of the genus Geotricum is fixed and a method of removing methyl ethyl ketone using the same. When the methyl ethyl ketone was removed using a biofilter immobilized with a strain of Geotricum on the carrier, it was relatively inexpensive and did not generate nitrogen oxides or secondary pollutants compared to conventional methods such as activated carbon or incineration.

Korean Patent Application No. 10-2003-0078402 (filed Nov. 6, 2003) provides a biofilter for removing odors and volatile organic compounds, and removes volatile organic compounds using a strain of Pseudomonas genus. It has been shown.

Technical challenge

The present invention provides a Bacillus megaterium BC1-1 KCCM 10856P strain for reducing the odor generated from wastewater or food waste generated in livestock raising and heavy metals in the wastewater and waste. The purpose.

The present invention provides a microbial agent for odor removal and heavy metal removal containing Bacillus megaterium BC1-1 (Cacillium megaterium BC1-1) KCCM 10856P strain as an active ingredient and a method for purifying livestock wastewater or food waste using the same For the purpose of

Technical solution

The present invention provides a Bacillus megaterium BC1-1 KCCM 10856P strain that has the ability to remove odors much faster and more efficiently than conventional strains, and also has the ability to remove heavy metals.

The present invention provides a microbial agent for odor removal and heavy metal removal containing Bacillus megaterium BC1-1 KCCM 10856P strain as an active ingredient.

Bacillus megaterium BC1-1 KCCM 10856P strain according to the present invention excellently reduced the odor generated in livestock wastewater or food waste. In particular, the microorganisms also reduced heavy metals from livestock wastewater or food waste. Therefore, the microbial agent according to the present invention can be used to purify odors and heavy metals of livestock wastewater or food waste. In addition, it can be widely used for the production of organic liquid fertilizer using livestock wastewater or livestock feed using food waste.

1 shows an experimental apparatus for removing odor of livestock wastewater.

Figure 2 shows an experimental device for removing odor of food waste.

Best Mode for Carrying Out the Invention

The present invention provides a strain of Bacillus megaterium BC1-1 KCCM 10856P, which is useful for removing odors and removing heavy metals.

Another aspect of the present invention provides a microbial agent for odor removal and heavy metal removal comprising an effective amount of the new strain Bacillus megalium BC1-1 KCCM 10856P.

The method for formulating Bacillus megalium BC1-1 KCCM 10856P according to the present invention can apply conventional techniques. Methods for formulating microorganisms include a method of preparing a solid in the form of beads and a method of preparing a liquid formulation. In the case of preparing the microorganism in a solid form, the product may be non-uniform in the manufacturing process, there is a disadvantage such as reduced application of the product due to the deactivation of microorganisms or dust generated in the manufacturing process. On the other hand, the liquid microbial agent has advantages such as faster activity and easier handling than the powder product, but has a disadvantage of poor shelf life compared to the powder product.

Examples of methods for preparing the beads include (a) 0.1-5.0 wt% solution of negatively charged biodegradable polymers such as alginate, pectin, carrageenan or polyaspartic acid; The mixture of the Bacillus megacium BC1-1 culture medium was mixed with a Ca ²⁺ , Cu ²⁺ , Zn ²⁺ , Ni ²⁺ , Co ²⁺ , Mn ²⁺ , Al ²⁺ , Fe ²⁺ , or Mg ²⁺ metal salt solution at a concentration of 0.5 to 3.0% by weight. Dropping in to produce beads; And

(b) the beads are immersed in a 0.1 to 3.0% by weight solution of a positively-charged biodegradable polymer such as chitosan, chitosan derivatives or polylysine and stirred for 30 minutes to 2 hours to coat the beads by electrostatic attraction. It can be prepared including the step. The microbial preparation prepared as described above may be used as it is by lyophilization, in order to increase the persistence of the survival and active effect of the microorganisms; (c) washing the beads with 50 mM sodium acetate (pH 5.5) to remove excess positively charged biodegradable polymeric material; (d) immersing the beads in 0.1-2.0 wt% negative charge biodegradable polymer solution and stirring; And (e) further washing the beads with physiological saline and then immersing in 0.1 to 2.0 wt% positive charge biodegradable polymer solution to stir to form an outer membrane to form a thicker biodegradable polymer membrane thereon. It is possible to increase the effect persistence of the microbial agent produced by.

Another embodiment of the present invention is Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus Lai Kenny Po Ms BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus at least one bacillus selected from the group consisting of clausii BC7), Bacillus licheniformis BC8 ( Bacillus licheniformis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) To provide a microbial agent for odor removal and heavy metal removal consisting of species and an effective amount of the new strain Bacillus megalium BC1-1 KCCM 10856P.

Another aspect of the present invention is a method for removing odor and heavy metals in food waste or livestock waste by culturing the new strain Bacillus megalium BC1-1 KCCM 10856P with odorous food waste or livestock wastewater.

Another embodiment of the present invention is Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus Lai Kenny Po Ms BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus at least one bacillus selected from the group consisting of clausii BC7), Bacillus licheniformis BC8 ( Bacillus licheniformis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) Food waste or livestock that stinks odor-depleting microorganisms consisting of species and effective amounts of new strain Bacillus megalium BC1-1 KCCM 10856P Incubated with you to a method for removing heavy metals in the odor and food waste, or livestock waste water.

Another embodiment of the present invention is an organic liquid fertilizer production method using livestock wastewater containing an effective amount of the new strain Bacillus megaliumium BC1-1 KCCM 10856P and livestock feed production method using food waste.

Organic liquid fertilizer production method using livestock wastewater and livestock feed production method using food waste according to the present invention can be applied to the conventional technology in addition to using the new strain Bacillus megalium BC1-1 KCCM 10856P. Examples of organic liquid fertilizer production using livestock wastewater include a method for producing organic liquid fertilizer using livestock wastewater and peat. This method comprises the steps of pulverizing peat and organic material and oyster shells and briquettes at an appropriate ratio; Deodorizing by mixing a proper ratio of sodium bicarbonate, calcium oxide and calcium chloride; Fermentation using microorganisms; Extracting the organic liquid fertilizer; Neutralizing by adding dilute hydrochloric acid to the extracted organic liquid fertilizer; And aeration of the neutralized organic liquid for a predetermined time to reduce the chemical oxygen demand (C.O.D).

Fermentation feed using food waste can be used by the new strain Bacillus Megalium BC1-1 KCCM 10856P, dry fermentation feed, mixed fermentation feed, mixing and dry fermentation or liquid fermentation feed. The dry fermentation feed method has a high weight reduction effect, but it is difficult to use in the state because the energy cost for drying is inconvenient and nutritionally unfinished state, and because it is high moisture (around 40%), packaging and automatic feeding The application of lines also has a disadvantage. The mixed fermentation feed method is capable of maintaining nutritional balance, but it is difficult to manufacture a variety of feeds having different requirements by age. The combined form of mixing and dry fermentation is easy to maintain nutritional balance and moisture control, but has a disadvantage of high cost, including the energy cost and moisture control agent input to dry. Liquid fermented feed produced at around 85% moisture content has a disadvantage in that it is difficult to distribute despite the advantage that the manufacturing cost is much cheaper than other methods.

Another embodiment of the present invention is Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus Lai Kenny Po Ms BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus at least one bacillus selected from the group consisting of clausii BC7), Bacillus licheniformis BC8 ( Bacillus licheniformis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) Production method of organic liquid fertilizer and food waste using livestock wastewater consisting of species and effective amount of new strain Bacillus megalium BC1-1 KCCM 10856P Animal feed production is one way.

Embodiment for Invention

<Example 1> Bacillus megaliumium BC1-1 ( Bacillus megaterium  BC1-1) Isolation and Identification of KCCM 10856P Strains

Bacillus megaterium BC1-1 KCCM 10856P bacteria used in the present invention were obtained from mushrooms and mycelium masses inhabiting fallen leaves in Samgimyeon forest, Iksan, Jeollabuk-do. The mushrooms and mycelium collected were put in a 500ml beaker, immersed in a culture solution prepared by adding 300ml of water and about 5g of soil sugar, and then incubated at 28-30 ° C. After spraying a portion of the culture solution to the ceremonial toilet to see the odor disappears in one day, it was found that the Bacillus bacteria of the present invention has a good odor removal ability. The culture solution was continuously cultured using molasses, and subsequently used for food waste, it was also confirmed that the odor removal ability is excellent, and entered the pure separation of useful microorganisms.

Separation of useful microorganisms was performed at the Department of Microbiology, Kunsan National University, and a total of 12 microorganisms were isolated using NA medium, forming a heat resistant spore with a chain-like arrangement, and exhibiting resistance to penicillin, all of which are Bacillus strains. It confirmed that it was. The pure microorganisms were passaged and stored using NA medium. The 16S rDNA gene sequences of all 12 isolated Bacillus bacteria were analyzed by the Korea Institute of Biotechnology of Daejeon, Chungnam. As a result, including Bacillus megaterium BC1-1 KCCM 10856P species, Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P (Bacillus cereus BC3) , Bacillus Lai Kenny Po Ms BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6), Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny Po Ms BC8 KCCM 10864P (Bacillus licheniformis BC8) , Bacillus buffer mousse BC9 KCCM 10865P (Bacillus firmus BC9) , Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) species was identified. It was deposited with the Korean spawn center on April 27, 2007 and each KCCM accession number was assigned.

<Example 2> Bacillus Megalium BC1-1 KCCM 10856P and Bacillus Megalium BC1-1 KCCM 10856P and other Bacillus microbial composition of the livestock wastewater removal effect

Bacillus mega emitter Solarium BC1-1 KCCM 10856P by Bacillus in order to measure the odor reduction efficiency of livestock waste Mega emitter Solarium BC1-1 KCCM 10856P and Bacillus mega emitter Solarium BC1-1 (Bacillus megaterium BC1-1) KCCM 10856P , Bacillus mega Bacillus megaterium BC1-2 ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus Lycheniform BC4 KCCM 10860P (Bacillus licheniformis BC4), Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny Four Miss BC8 KCCM 10864P ( Bacillus licheniformis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) The odor in the container was collected by measuring the microorganism reaction vessel containing the waste water (see FIG. 1 ) after 4 days.

The microbial reaction vessel condition of livestock wastewater was set up to maintain the temperature at 37.5 ℃ by using aeration and heating band and thermostat to install aeration device for active microorganism as follows. (See FIG. 1 ).

In addition, the concentration of odor generated in the livestock wastewater before microbial input was measured and analyzed for the change in concentration of each odor after microbial input. For accurate measurement of efficiency, 2 liters of wastewater were injected into each of 11 microbial reaction vessels to reduce the odor of the livestock wastewater, and one vessel of 5 ml of Bacillus megalium BC1-1 KCCM 10856P culture medium and another vessel of Bacillus mega Bacillus megaterium BC1-1, Bacillus megaterium BC1-2, Bacillus megaterium BC1-2, Bacillus megaterium BC1-2, Bacillus megaterium BC2-1, Bacillus megaterium BC2-1, Bacillus cereus BC3 KCCM 10859P (Bacillus cereus BC3) , Bacillus Lai Kenny Po Ms BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny Po Ms BC8 KCCM 10864P (Bacillus licheniformis BC8) , Bacillus buffer mousse BC9 KCCM 10865P (Bacillus firmus BC9) , Bacillus Aureus KCCM 10866P BC10 (Bacillus cereus BC10) culture media were used as evenly mixed mixture microorganism 5ml turned on, the remaining one container without added microorganisms contrast put the waste water effluent 5ml.

(1) analysis method

1) Measurement method of ammonia

Ammonia is quantified by measuring the absorbance of indophenols produced by adding phenol-nitroprusside sodium solution and sodium hypochlorite solution to the analytical sample solution and reacting with ammonium ion.

end. reagent

-Collecting solution

5 g of boric acid is dissolved in distilled water, and the total amount is 1 L.

-Phenol, pentacyano nitrosyl sodium (III) acid solution

5 g of phenol and 25 mg of pentacyano nitrosyl ammonium iron (III) sodium dihydrate6) are dissolved in distilled water to make a total amount of 500 mL. Store this solution in a cool dark place and do not use more than 1 month after preparation.

Sodium hypochlorite solution

Sodium hypochlorite solution (3-10% effective chlorine) 60 / CmL [where C is the effective chlorine concentration (in%) of sodium hypochlorite (NaOCl) quantified at the time of preparation)], 10 g of sodium hydroxide and sodium hydrogen phosphate 12 Dissolve 35.8 g of hydrate in distilled water to make the total amount 1 L. This solution is prepared each time it is used.

I. Solution absorption

The absorber bottle is made of hard glass that can hold 20 mL of absorbent liquid and is equipped with a filter port. In the middle, take a sample solution that can hold 20 mL of absorbent liquid and connect the two in series. The suction pump draws more than 10 L / min of air with an absorbent bottle installed. After collection, the absorbent solutions from the two absorbent bottles are combined and transferred to a 50 mL volumetric flask. The absorbed solution is then transferred to the volumetric flask and the total volume is 50 mL. Transfer 10 mL of this solution into the test tube and use it as the sample solution for analysis.

All. Absorbance Measurement of Analytical Sample Solution

5 mL of phenol pentacyano nitrosyl iron (III) iron solution was added to the sample solution for analysis, shaken well, and 5 mL of sodium hypochlorite solution was mixed and left at 25 to 30 ° C for 1 hour, followed by 640 nm wavelength. Absorbance is measured at. For blank test solution, use 10 mL of the collecting solution (absorbent solution) in the same manner as the analytical sample solution.

2) Methylmercaptan, hydrogen sulfide, dimethyl sulfide and dimethyl disulfide test method

In the sulfide method, the sample gas was concentrated at low temperature by -170 ° C Sample Preconcentration Trap (SPT), heated and desorbed again, and injected into the gas chromatograph, and PFPD (Pulse Flame Photometri Dectector) was used as a detector.

3) trimethylamine

Trimethylamine was analyzed by distilling analytical sample solution absorbed into aqueous sulfuric acid solution (359 + 1) with a syringe and injecting the solution into a decomposition bottle containing potassium hydroxide solution through a silicone stopper at 0.2-0.L / min. The trimethylamine generated by bubbling about 2-3 L of nitrogen was cooled with a liquid acid, concentrated in a condenser tube, heated and desorbed to about 70 ° C., and trimethylamine was introduced into a column and analyzed by FID.

4) Analysis of Aldehydes

Analysis of aldehydes is carried out through a sample collection tube filled with octadecyl silylated silica gel coated with 2,4-dinitrophenyl hydrazine, to collect aldehydes and to evaporate acetonitrile from the sample collection tube. The mixture was dissolved in ethyl acetate, and a portion thereof was introduced into HPLC (Young Lin) for quantification.

(2) Analysis result

Bacillus megagium BC1-1 KCCM 10856P and Bacillus megagium BC1-1 KCCM 10856P and the mixed microbial composition of the other Bacillus bacteria and the culture for 4 days and only the control waste water is shown in Table 1 below.

Table 1

Bacillus megalium BC1-1 KCCM 10856P removes ammonia, hydrogen sulfide, methyl mercaptan, dimethyl sulfide, dimethyl disulfide and trimethylamine in livestock wastewater. However, acetaldehyde was detected at a concentration similar to that of the control sample and the mixed microbial input sample after 4 days after the input, and the removal efficiency of acetaldehyde was insignificant.

<Example 3> Analysis of odor of food waste by mixed microorganism composition of Bacillus megalium BC1-1 KCCM 10856P and Bacillus megalium BC1-1 KCCM 10856P and other Bacillus bacteria

Bacillus megaterium BC1-1 KCCM 10856P and Bacillus megaterium BC1-1 KCCM 10856P, Bacillus mega Bacillus megaterium BC1-2 ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus Lycheniform BC4 KCCM 10860P (Bacillus licheniformis BC4), Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny Four Miss BC8 KCCM 10864P (Bacillus licheniformis BC8) , Bacillus putting mousse BC9 KCCM 10865P (Bacillus firmus BC9) , Bacillus cereus BC10 KCCM 10866P (Bacillus cereus BC10) given the mixed microbial population It was charged into a reaction vessel containing a microbial plant waste (see Fig. 2) was measured by collecting the odor in the container after 4 days.

Microbial reaction vessel conditions of food waste was viscous to maintain a constant temperature to 37.5 ℃ using a heating band (heating band) and a thermostat (see Figure 2 ).

In addition, the concentration of odor generated by raw food waste was measured before microbial input, and the concentration change of each odor after microbial input was analyzed. In order to accurately measure the odor of food waste, 2 liters of 11 microbial reaction vessels each were injected into a certain amount, and one vessel was Bacillus megalium BC1-1 KCCM10856 5 ml of culture medium, and the other vessel Bacillus megalium BC1 -1 KCCM10856 ( Bacillus megaterium BC1-1), Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaliumium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus rickeniformis BC4 KCCM 10860P ( Bacillus licheniformis BC4), Bacillus cereus BC5 KCCM 10861P ( Bacillus cereus BC5), Bacillus sphaericus BC6 KCCM 10862P ( Bacillus sphaericus BC6), Ba7 KCCM 10863P ( Bacillus clausii BC7), Bacillus rickeniformis BC8 KCCM 10864P ( Bacillus licheniformis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus Serum BC10 KCCM 10866P ( Bacillus cereus BC10) 5 ml of mixed microorganisms in which the culture solution was evenly mixed, and the other one container was used as a control without putting microorganisms 5ml of food waste.

Odor analysis of food waste was carried out in the same manner as the livestock wastewater odor analysis experimental method of Example 2.

<Result>

TABLE 2

Bacillus megacium BC1-1 KCCM10856 removed ammonia, hydrogen sulfide, methyl mercaptan, dimethyl disulfide and trimethylamine from food waste. However, dimethyl sulfide and acetaldehyde were detected at the same concentrations as the control sample and the mixed microorganism input sample after 4 days after the addition, and the removal efficiency for dimethyl sulfide and acetaldehyde seems to be insignificant.

<Example 4> Heavy Metal Reduction Effect of Livestock Wastewater and Food Waste

Bacillus megalithium BC1-1 In order to measure the effect of reducing heavy metals in livestock wastewater and food waste by KCCM10856, 2 liters of food waste were injected into each of 11 microbial reaction vessels, and then one vessel was Bacillus megalithium BC1-. 5 ml of KCCM10856 culture, another container contains Bacillus megaterium BC1-1 KCCM10856, Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaclium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus rickeniformis BC4 KCCM 10860P ( Bacillus licheniformis BC4), Bacillus cereus BC5 KCCM 10861P ( Bacillus cereus BC5) Bacillus sphaericus BC6 ( Bacillus sphaericus BC6), Bacillus clausii BC7 KCCM 10863P ( Bacillus clausii BC7), Bacillus rickeniformis BC8 KCCM 10864P ( Bacillus lichenifor mis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) 5 ml of mixed microorganisms in which the cultures are evenly mixed, and the other one container does not contain microorganisms 5ml was used as a control. The same was done for livestock wastewater. The concentration of heavy metals in food waste and livestock wastewater was measured during microbial culture and after 4 days of culture. Heavy metal was measured by the following method.

(1) Preparation of Reagent

Ternary solution: Mix HNO ₃ , H ₂ SO ₄ and HClO ₄ in the ratio of 10: 1: 4 to prepare the required amount.

-Concentrated HNO ₃

(2) disassembly

10 ml of the collected sample is weighed into a 250 ml Erlenmeyer flask, 10-30 ml of concentrated HNO _{3 is} added, and left to stand overnight, then placed on a hot plate and dried slowly until a white precipitate is formed. After cooling, 10-50 ml of ternary solution is added and heated on a hot plate to blow off some white smoke of H ₂ SO ₄ and HClO ₄ , and the decomposition stops when the decomposition solution becomes white or brown. After cooling, add hot distilled water to the No. 50 or 100 ml mass flask. 6 Filter with filter paper and continue with hot distilled water. Rinse the flask with policemen and filter.

(3) measurement

The filtrate is diluted in a predetermined amount, and then K, Ca, Mg, Na, Fe, Mn, Cu, Zn, Cr, Cd, Pb, Ni, and the like are collected in AA (Atomic Absorption Flame Emission Spectrometer) or ICP (Inductively Coupled Plasma). Make a calibration curve with the standard solution of each component and measure it.

TABLE 3

Table 4

Bacillus megacium BC1-1 KCCM 10856P removes highly cadmium, chromium, copper, zinc and lead from livestock wastewater. In addition, cadmium, nickel, copper, zinc, and lead were removed from food waste. However, the amount of chromium was increased in food waste, which is different from the livestock wastewater, and the effect of chromium removal by Bacillus metharium BC1-1 KCCM 10856P was uncertain.

Bacillus megalithium BC1-1 KCCM 10856P according to the present invention was excellent in removing odor from livestock wastewater and food waste, and the microorganism mixture (hereinafter referred to as EM) used in the past is approximately 30 days to remove the odor. Compared with the required point (without data), the odor is removed at a very high speed, and the odor removal ability is excellent. At the same time, the strains of the present invention also have the ability to remove heavy metals at very high levels for some of the heavy metals contained in livestock wastewater or food waste.

Claims (9)

Bacillus megaterium BC1-1 KCCM 10856P useful for removing odors and removing heavy metals. New strain Bacillus Megalium BC1-1 KCCM 10856P containing microorganisms for odor removal and heavy metal removal. Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megaterium BC2-1 KCCM 10858P ( Bacillus megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3), Bacillus Lai Kenny Po Ms BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) Effective amount with at least one Bacillus species selected from the group consisting of Bacillus licheniformis BC8, Bacillus licheniformis BC8, Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) New strain of Bacillus megacium BC1-1 KCCM 10856P microbial preparation for odor removal and heavy metal removal. New strain Bacillus megacium BC1-1 KCCM 10856P is incubated with odorous food waste or livestock wastewater to remove odors and heavy metals in food waste or livestock wastewater. Bacillus megaterium BC1-2, Bacillus megaterium BC1-2, Bacillus megaterium BC2-1, Bacillus megaterium BC2-1, Bacillus cereus BC3 KCCM 10859P, Bacillus cereus BC3 Miss BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny One or more Bacillus species selected from the group consisting of Bacillus licheniformis BC8, Bacillus permus BC9 KCCM 10865P, Bacillus cerus BC9, Bacillus cereus BC10, and an effective amount of Bacillus sp. Odor microorganisms for removing odor composed of Megacium BC1-1 KCCM 10856P are incubated with odorous food waste or livestock wastewater. How to remove heavy metals in food waste or livestock wastewater. A method for producing organic liquor using livestock wastewater containing an effective amount of new strain Bacillus megalium BC1-1 KCCM 10856P. Bacillus megaterium BC1-2, Bacillus megaterium BC1-2, Bacillus megaterium BC2-1, Bacillus megaterium BC2-1, Bacillus cereus BC3 KCCM 10859P, Bacillus cereus BC3 Miss BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny One or more Bacillus species selected from the group consisting of Bacillus licheniformis BC8, Bacillus permus BC9 KCCM 10865P, Bacillus cerus BC9, Bacillus cereus BC10, and an effective amount of Bacillus sp. Method for producing organic liquid fertilizer using livestock wastewater consisting of Megarium BC1-1 KCCM 10856P. New Bacillus Bacillus Megatium BC1-1 A method for producing livestock feed using food waste containing an effective amount of KCCM 10856P. Bacillus megaterium BC1-2 KCCM 10857P ( Bacillus megaterium BC1-2), Bacillus megacium BC2-1 KCCM 10858PKCCM 10859P megaterium BC2-1), Bacillus cereus BC3 KCCM 10859P ( Bacillus cereus BC3) BC4 KCCM 10860P (Bacillus licheniformis BC4) , Bacillus cereus BC5 KCCM 10861P (Bacillus cereus BC5) , Bacillus spa Erie kusu BC6 KCCM 10862P (Bacillus sphaericus BC6) , Bacillus claw when BC7 KCCM 10863P (Bacillus clausii BC7) , Bacillus Lai Kenny PO One or more Bacillus species selected from the group consisting of Miss BC8 KCCM 10864P ( Bacillus licheniformis BC8), Bacillus permus BC9 KCCM 10865P ( Bacillus firmus BC9), Bacillus cereus BC10 KCCM 10866P ( Bacillus cereus BC10) Method of producing livestock feed using food waste consisting of Lungium BC1-1 KCCM 10856P.

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