KR102277780B1 - Method for manufacturing wastewater treatment agent by soil microbes - Google Patents

Abstract

The present invention relates to a method for manufacturing a sewage and wastewater treatment agent by soil microorganisms. More specifically, the present invention relates to a method for manufacturing sewage and wastewater treatment agent by modified soil microorganisms so that sewage and wastewater are decomposed to be treated with high efficiency by using soil microorganisms, thereby reducing environment pollution.

Description

Method for manufacturing wastewater treatment agent by soil microbes

The present invention relates to a method for producing a wastewater treatment agent by soil microorganisms, and more particularly, to a method for producing a wastewater treatment agent by soil microorganisms improved to reduce environmental pollution by efficiently decomposing wastewater using soil microorganisms will be.

Wastewater such as livestock manure, including various organic wastes, accelerates pollution of rivers as well as soil and environmental destruction.

Such environmental pollution is a phenomenon inevitably accompanied by accelerated mechanization and industrialization, and is acting as a great burden on the industrialized society.

Accordingly, advanced countries are investing a lot of money every year for environmental improvement and restoration of contaminated soil to limit development and pass on resources to recognize the importance of the environment. The damage situation is getting worse every year.

In such a situation, attempts have been made to decompose and purify wastewater using soil microorganisms.

However, there is still a need to further solve the problem of aggravating the odor generated during the decomposition process, as the ability to separate the solid-liquid wastewater, decompose the treated water and purify the wastewater is low due to the low activation of the ability to reproduce and settle microorganisms.

Domestic Registered Patent No. 10-1545537 (2015.08.12) Method for manufacturing microbial preparations for soil improvement and soil environment improvement and microbial preparations manufactured through the same

The present invention was created to solve the problems in the prior art as described above, and the soil microorganisms are used to efficiently decompose and treat the wastewater to reduce environmental pollution. Its main purpose is to provide a method.

The present invention is a means for achieving the above object, including a coagulation reagent preparation step, a microbial solution preparation step to be used after the coagulation reaction, and a decomposition accelerator manufacturing step used for activating microorganisms after the microbial solution input In a method for manufacturing a wastewater treatment agent by soil microorganisms;

The coagulation reagent preparation step is based on 100 parts by weight of calcium carbonate, sodium aluminate _{(NaAlO 2} ) 50 parts by weight, tannin 25 parts by weight, sepiolite 20 parts by weight, sulfur 5 parts by weight, and potassium permanganate 80 parts by weight are mixed A first process of stirring; a second process of mixing the mixture stirred through the first process and the water-soluble silicone polyester resin in a volume ratio of 1:1; A third process of extruding the resin mixture obtained through the second process into pellets for reaction; consists of;

The microbial liquid preparation step is a step of vacuum packaging in a container in a state containing ^{2×10 6 cfu/g of Bacillus bacteria and 2×10 6} cfu/g of yeast bacteria based on 1 liter of rice water;

The decomposition accelerator manufacturing step is a step of decomposing and removing organic matter by inducing sufficient activation of microorganisms put into the wastewater to cause fermentation and heat, and the decomposition accelerator is a biodegradable aliphatic polyester resin 60 parts by weight, boric acid based on 100 parts by weight of rice bran 15 parts by weight, molasses 80 parts by weight, provides a method for producing a wastewater treatment agent by soil microorganisms, characterized in that it contains 80 parts by weight of coco peat powder.

According to the present invention, it is possible to obtain an improved effect to reduce environmental pollution by efficiently decomposing wastewater using soil microorganisms.

Hereinafter, preferred embodiments according to the present invention will be described in more detail.

The method for manufacturing a wastewater treatment agent by soil microorganisms according to the present invention includes soil microorganisms.

As preferred soil microorganisms, Bacillus and yeast are used together. In particular, the Bacillus bacteria is preferably Bacillus Lichenifomis RTT 184 as a representative strain.

Among these soil microorganisms, Bacillus bacteria decomposes and removes ammonia as well as odorous substances such as nitrites; Yeast bacteria resynthesize the organic matter decomposed by Bacillus bacteria into amino acids, vitamins, and growth factors to promote fermentation and raise the fermentation heat to 60-80℃, thereby contributing to the killing of various pathogens.

In particular, since these soil microorganisms eat and decompose organic matter and make thick mycelium, the adsorption and decomposition ability of organic matter can be increased.

More specifically, the method for producing a wastewater treatment agent by soil microorganisms according to the present invention includes a coagulation reagent production step, a microbial solution production step to be used after coagulation reaction, and a decomposition accelerator input and used for activating microorganisms after the microbial solution input manufacturing steps.

Thus, based on 10 liters of wastewater, 2 kg of coagulation reagent is first added to remove solids that have reacted with coagulation, and then 1 liter of microbial liquid is added and then 2 kg of decomposition accelerator is continuously added. decomposition proceeds efficiently. This wastewater decomposition treatment is used in the primary purification treatment stage, and it is expected that the treatment efficiency can be increased by more than 30% compared to the existing one.

At this time, the coagulation reagent preparation step is based on 100 parts by weight of calcium carbonate, sodium aluminate _{(NaAlO 2} ) 50 parts by weight, tannin 25 parts by weight, sepiolite 20 parts by weight, sulfur 5 parts by weight, and potassium permanganate 80 parts by weight A first process of mixing and stirring the parts; a second process of mixing the mixture stirred through the first process and the water-soluble silicone polyester resin in a volume ratio of 1:1; A third process of extruding the resin mixture obtained through the second process into pellets for reaction; consists of.

Here, sodium aluminate reacts with calcium carbonate and combines with various organic materials to accelerate separation from wastewater in the form of floating or sedimentation while solidifying.

And, tannin is a natural material that increases cohesiveness and contributes to the formation of flocs.

In addition, sepiolite is added to promote the separation of solids and liquids through adsorption of organic matter as meersham, a round tubular variety.

In addition, sulfur is added to neutralize harmful substances and kill fungi.

In addition, potassium permanganate is added to sterilize by strong oxidizing power while being reduced to _{2KM 3} O ₄ → K ₂ MnO ₄ + MnO ₂ + O _{2 .}

In particular, the water-soluble silicone polyester resin exhibits an independent and highly efficient dispersing ability without the use of a surfactant, so it improves the mixing reactivity with the mixture. The reason for making pellets is to increase the reaction efficiency and induce sufficient reactivity even in wastewater. to be.

That is, the pellet does not react immediately after falling into the wastewater, but is immersed until the resin constituting the shell is melted, and then reacts after the shell is melted to flocculate the solidable aggregates in the upper part of the wastewater as well as the inside.

On the other hand, the microbial liquid preparation step is a step of sealing the container in a state containing ^{2×10 6 cfu/g of Bacillus bacteria and 2×10 6} cfu/g of yeast bacteria based on 1 liter of rice water.

In this case, the seal should be packaged in a vacuum and processed so that the strain is not activated and is dormant, and 2×10 ⁶ cfu/g of photosynthetic bacteria may be further contained.

The decomposition accelerator manufacturing step is a step of decomposing and removing organic matter by inducing sufficient activation of the microorganisms injected into the wastewater to generate heat while fermentation occurs.

To this end, the decomposition accelerator includes 60 parts by weight of biodegradable aliphatic polyester resin, 15 parts by weight of boric acid, 80 parts by weight of molasses, and 80 parts by weight of coco peat based on 100 parts by weight of rice bran.

At this time, rice bran is rich in fiber and generates organic acids during fermentation, so it has excellent antibacterial and antioxidant effects, so it acts as a natural antibiotic that can replace it without using a separate antibiotic, so it is very effective in treating wastewater.

In addition, the biodegradable aliphatic polyester resin contributes to the growth of microorganisms while being decomposed into carbon dioxide and water by microbial cells, and at the same time also contributes to the adsorption and removal of organic matter.

In addition, when boric acid is exothermic, the decomposition power is promoted to increase the decomposition ability of organic matter.

In addition, molasses is added to promote fermentation of microorganisms and induce exothermic acceleration.

In addition, coco-peat powder (Coco-peat Powder) is the fibrous body, which is the outer shell of the coconut fruit, compressed at high pressure and then pulverized, which serves as a good food for microorganisms and promotes fermentation and fever.

In addition, in the present invention, after the coagulation reagent is added to the wastewater, the deodorant may be first added to the deodorant before the microbial solution is added, and the deodorant used at this time is as follows.

The deodorant according to the present invention contains 60% by weight of feldspar processed product, 15% by weight of grass concentrate containing acetic acid, 2.5% by weight of manganese acetate, 5% by weight of manganese nitrate, 15% by weight of NTA (Nitrilotriacetic acid), and 2.5% by weight of _{FeCl 3} % consists of a mixed mixture

At this time, the process of crushing feldspar to a particle size of 0.2-0.3cm, washing the crushed material with ethanol, drying after washing, purging the dried material with carbon dioxide in an oxygen-free atmosphere, and purging the water-soluble silicone polyester resin Use the one made through the process of immersing in and drying.

In this case, the reason for washing with ethanol is to maximize the three-dimensional network structure by expanding the porosity, and the reason for purging carbon dioxide and confining it with water-soluble silicone polyester resin is carbon dioxide when water-soluble silicone polyester resin is dissolved in wastewater. This is to increase the ability to capture and remove decomposition of organic matter and odor by generating air bubbles while reacting.

In addition, the grass concentrate is added for this purpose because it has an excellent effect in decomposing and removing odors as a dark brown dry distillate made when carbonizing wood.

In particular, the grass concentrate contains at least 5 parts by weight of acetic acid, thereby decomposing the odor generated by the decomposition of organic matter and having sterilizing power.

In addition, manganese acetate is slowly oxidized when it is decomposed into rhombic crystalline powder to form manganese oxide and is added to enhance the effect of promoting the decomposition reaction of organic matter; Manganese nitrate is added to increase the ability to decompose and remove organic matter and odors by expressing a photocatalytic effect in the visible light region.

In addition, NTA is nitrilotriacetic acid, which is a white crystalline powder obtained by reacting a mixture of ammonia and monochloroacetic acid with potassium cyanide and formalin. Through chelation with iron salts, ammonia, trimethylamine, hydrogen sulfide, and mercaptan are odor-like. It is an excellent chelating agent for removal.

And, FeCl ₃ reacts with the chelating agent to directly affect the removal of hydrogen sulfide.

In order to confirm the deodorizing effect of such a deodorant, a transparent box having a size of 1m × 1m × 1m was half filled with wastewater, and 500g of the deodorant according to the present invention was added, and then the deodorization ability was checked.

As a result of the confirmation, the smell started to decrease 10 minutes after the deodorant was added, and there was almost no smell after 1 hour and 30 minutes. In addition, when the lid was opened and the test was conducted with exposure to sunlight, there was almost no smell after 40 minutes.

Claims (4)

In a method for producing a wastewater treatment agent by soil microorganisms comprising a coagulation reaction agent production step, a microbial solution production step used after coagulation reaction, and a degradation accelerator production step used for activating microorganisms after the microbial solution input;
The coagulation reagent preparation step is based on 100 parts by weight of calcium carbonate, sodium aluminate _{(NaAlO 2} ) 50 parts by weight, tannin 25 parts by weight, sepiolite 20 parts by weight, sulfur 5 parts by weight, and potassium permanganate 80 parts by weight are mixed A first process of stirring; a second process of mixing the mixture stirred through the first process and the water-soluble silicone polyester resin in a volume ratio of 1:1; A third process of extruding the resin mixture obtained through the second process into pellets for reaction; consists of;
The microbial liquid preparation step is a step of vacuum packaging in a container in a state containing ^{2×10 6 cfu/g of Bacillus bacteria and 2×10 6} cfu/g of yeast bacteria based on 1 liter of rice water;
The decomposition accelerator manufacturing step is a step of decomposing and removing organic matter by inducing sufficient activation of microorganisms put into the wastewater to cause fermentation and heat, and the decomposition accelerator is a biodegradable aliphatic polyester resin 60 parts by weight, boric acid based on 100 parts by weight of rice bran 15 parts by weight, 80 parts by weight of molasses, and 80 parts by weight of coco pit powder.
According to claim 1,
The method for producing a wastewater treatment agent by soil microorganisms, characterized in that the microbial solution ^{further contains 2×10 6 cfu/g of photosynthetic bacteria.}
According to claim 1,
After the coagulation reagent is added to the wastewater, the deodorant is first added before the microbial solution is added to cause a deodorization reaction, but a deodorant is further included.
The deodorant is 60% by weight of the feldspar process, 15% by weight of a grass concentrate containing acetic acid, 2.5% by weight of manganese acetate, 5% by weight of manganese nitrate, 15% by weight of NTA (Nitrilotriacetic acid), and 2.5% by weight of _{FeCl 3 is mixed} A method for manufacturing a wastewater treatment agent by soil microorganisms, characterized in that it consists of a mixture of
According to claim 1,
The wastewater treatment agent removes the coagulated solids by first introducing 2 kg of the coagulation reagent based on 10 liters of wastewater, then 1 liter of the microbial solution is added, and then 2 kg of the decomposition accelerator is continuously added. It is characterized in that it is used. A method of manufacturing a wastewater treatment agent by soil microorganisms.