KR20020011267A - Bacteria living material and its manufacture method - Google Patents

Abstract

PURPOSE: Provided are habitat materials of microbes for water purification and deodorization, which offer a place for activity and rest of microbes according to the surroundings. CONSTITUTION: The habitat materials of microbes are divided into anionic and cationic materials. The anionic materials comprises 70.05wt.% of SiO2, 19.71wt.% of Al2O3, 2.72wt.% of Fe2O3, 0.33wt.% of TiO2, 2.10wt.% of CaO, 0.76wt.% of MgO, 1.55wt.% of Na2O, 1.07wt.% of K2O, and 1.20wt.% of ignition loss. The anionic materials comprises 70.19wt.% of SiO2, 16.41wt.% of Al2O3, 2.85wt.% of Fe2O3, 0.27wt.% of TiO2, 3.67wt.% of CaO, 0.82wt.% of MgO, 2.81wt.% of Na2O, 1.81wt.% of K2O, and 1.20wt.% of ignition loss. The habitat materials of microbe are prepared by pouring the anionic or cationic materials into a mold and heating at 800-1800deg.C for effective hours to be granules and preferably cylindrical granules; removing infiltrated impurities; and cooling by rotation or under vacuum. The cylindrical granule(20), being 2-10mm in size, has three pierced holes(22a) to pass organics and grooves(22b) to crush organics.

Description

BACTERIA LIVING MATERIAL AND ITS MANUFACTURE METHOD}

The present invention relates to a microbial collection member used for purifying various kinds of water treatment such as livestock manure, living and factory wastewater, or removing odors. In particular, it provides a place of living of microorganisms and ensures dormancy and activity according to surrounding environmental conditions. The present invention relates to a microorganism collecting member for providing an atmosphere to decompose a substance and a method of manufacturing the same.

For example, the conventional manure treatment uses a method of separating solids and then purifying the liquid through a decay tank and an aeration tank. In the decay tank, the microorganism itself has a time to decompose the organic matter during the residence time of the liquid, and in the aeration tank, aerobic conditions are created to decompose the residual organic matter.

However, according to this simple method, not only the processing capacity of organic matters can be increased, but also microorganisms such as aerobic bacteria, anaerobic bacteria, and aerobic bacteria cannot be properly used.

Because these bacteria determine their activity according to the surrounding environmental conditions, because when the conditions worsen, the bacteria die. In other words, when oxygen is deficient, aerobic bacteria are killed, and if oxygen is present, anaerobic bacteria are killed and aerobic bacteria are killed.

Therefore, it is necessary to provide a place where the microorganisms can be actively retired according to the surrounding conditions and guarantee the effective microbial activity.

The present invention was devised in view of the above circumstances, and provides a microbial collection member for water treatment to provide a chip atmosphere to decompose contaminants while providing a place of living for microorganisms and ensuring dormancy and activity according to surrounding environmental conditions. And to provide a method for producing the object.

Specific means of the present invention for achieving the above object,

As a microbial member used for water purification or odor removal,

70.05% by weight of silicon dioxide, 19.71% by weight of aluminum oxide, 2.72% by weight of ferric oxide, 0.33% by weight of titanium dioxide, 2.10% by weight of calcium oxide, 0.76% by weight of magnesium oxide, 1.55% by weight of sodium oxide, 1.07% by weight of oxide The first mixture containing 1.20% by weight, 70.19% by weight of silicon dioxide, 16.41% by weight of aluminum oxide, 2.85% by weight of ferric oxide, 0.27% by weight of titanium dioxide, 3.67% by weight of calcium oxide, 0.82% by weight of magnesium oxide, oxide Characterized in that the second mixture containing sodium 2.81% by weight, potassium oxide 1.81% by weight, 1.20% by weight loss is selected by sintering to a predetermined grain size at a high temperature.

Moreover, as a manufacturing method of a microbial collection member used for water treatment purification, deodorization removal, etc.,

(a) 70.05% by weight of silicon dioxide, 19.71% by weight of aluminum oxide, 2.72% by weight of ferric oxide, 0.33% by weight of titanium dioxide, 2.10% by weight of calcium oxide, 0.76% by weight of magnesium oxide, 1.55% by weight of sodium oxide, 1.07% by weight of potassium oxide %, Loss of ignition 1.20% by weight of the first mixture, silicon dioxide 70.19% by weight, aluminum oxide 16.41% by weight, ferric oxide 2.85% by weight, titanium dioxide 0.27% by weight, calcium oxide 3.67% by weight, magnesium oxide 0.82% by weight Selecting a mixture of any one of a second mixture consisting of%, sodium oxide 2.81 wt%, potassium oxide 1.81 wt%, and loss on ignition 1.20 wt%;

(b) injecting the selected first or second mixture into a mold and heating it to 800 ° C. to 1800 ° C. for a predetermined time; And

(c) removing impurities impregnated in the heated sintered material and cooling the same by rotating or vacuuming.

Figure 1a, 1b is a perspective view and a plan view of a microbial collection member according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

20: microorganism collecting member 22a: flow hole

22b: groove

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

Figure 1a, 1b is a perspective view and a plan view showing the shape of the microbial collection member 20 according to an embodiment of the present invention, which can be divided into alkaline anionic microbial collection member and acidic cationic microbial collection member.

First, the anion microorganism collecting member of the present invention, silicon dioxide 70.05% by weight, aluminum oxide 19.71% by weight, ferric oxide 2.72% by weight, titanium dioxide 0.33% by weight, calcium oxide 2.10% by weight, magnesium oxide 0.76% by weight, sodium oxide 1.55 Weight%, potassium oxide 1.07 weight%, loss on ignition 1.20 weight% are mixed to form a first mixture.

Next, the first mixture is injected into a mold and heated to 800 ° C. to 1800 ° C. for a predetermined time to form a sintered product, preferably cylindrical, in granular form.

At this time, the sintering temperature satisfies 800 ° C to 1800 ° C. It is because sintering is difficult when it becomes 800 degrees C or less, and when a temperature goes over 1800 degreeC, a physical property changes.

Removing impurities that have penetrated the heated sintered material and cooling in a rotating or vacuum state.

In the process of sintering, cooling is used to prevent deterioration of the form using vacuum drying. This is to prevent clogging phenomenon that the microbial passage is blocked when the shape is changed.

On the other hand, the cationic microbial collection member of the present invention is produced by the same method as the above production by varying the components in the first mixture. That is, the cationic microbial member is 70.19% by weight of silicon dioxide, 16.41% by weight of aluminum oxide, 2.85% by weight of ferric oxide, 0.27% by weight of titanium dioxide, 3.67% by weight of magnesium oxide, 0.82% by weight of magnesium oxide, 2.81% by weight of sodium oxide, A second mixture containing 1.81% by weight potassium oxide and 1.20% by weight loss is selected.

Here, the loss on ignition is determined in consideration of the amount of evaporation during sintering.

The microbial collection member thus produced had a specific gravity of 1.35 and a size of 2 to 10 mm.

One embodiment of the microbial collection member produced in this manner is shown in Figures 1a, 1b.

That is, the microbial collection member 20 has three flow holes 22a penetrating through the body 22, and various grooves 22b are formed on the surface thereof.

The flow hole 22a is used as a passage through which the organic material passes freely, and the recess 22b functions to crush the contacted water finely.

In the present embodiment, the flow holes 22a may be configured in plural, but may be formed in one, and the through direction thereof may also appear in various forms. In addition, the flow hole 22a may be formed not only of a semicircle but also of a polygon such as a triangle or a square, or may be mixed with each other.

In addition, the anion microbial collection member is alkaline with a pH (hydrogen index) of 7.0 and an acidic cation microbial collection member with a pH (hydrogen index) of 6.9.

On the other hand, as shown in the table below the composition and content for each mixture, the anion microorganism collecting member is 99,49% by weight and the cationic microorganism collecting member is 100.03% by weight, and the amount of deficiency of 0.51% by weight is 100%. It can be seen that an excess of 0.03% by weight is generated to carry anions and cations.

The microorganism collecting member 20 of the present invention configured as described above may be used by uniformly inserting the anion microbial collecting member and the cationic microbial collecting member, respectively, into the contact aeration tank during the livestock waste treatment process.

That is, when a large amount of anion and cationic microorganism collecting member 20 is added to the contact aeration tank together with the liquid treated material collected from the manure, microorganisms such as aerobic bacteria, anaerobic bacteria, and breathable bacteria that are added to the contact aeration tank are microbial collecting member 20 Doing dormancy and activities.

That is, when oxygen is deficient in the organic matter in the contact aeration tank, anaerobic bacteria are activated from the microorganism collecting member 20 to decompose the organic matter, and when oxygen is sufficient, the aerobic bacteria act to decompose the organic matter. Of course, depending on the environmental conditions, breathable bacteria are dormant and repeat activities.

Therefore, an optimum decomposition environment is always formed in the contact aeration tank, thereby improving the decomposition treatment capacity of the contaminants.

On the other hand, while the organic matter in the contact aeration tank is in contact with the flow hole (22a) and the groove (22b) of the microbial collecting member 20 is broken more finely to help the decomposition action.

Therefore, in the contact aeration tank, an optimum decomposition of organic matter is formed and clean water without green algae can be discharged.

The reason why the anion microbial collecting member and the cationic microbial collecting member are added together is to increase the ionic action of each other to properly exhibit the treatment ability.

Although the present invention has been described in the case of applying the manure treatment, the present invention is not limited to its use, and can be used for various water treatments such as living and factory wastewater or for removing odors.

As described above, according to the present invention, the microorganisms can double the processing capacity for effectively purifying contaminants by providing a place where the microorganisms can be concealed and activated according to the surrounding environmental conditions.

Claims (3)

As a microbial member used for water purification or odor removal, 70.05% by weight of silicon dioxide, 19.71% by weight of aluminum oxide, 2.72% by weight of ferric oxide, 0.33% by weight of titanium dioxide, 2.10% by weight of calcium oxide, 0.76% by weight of magnesium oxide, 1.55% by weight of sodium oxide, 1.07% by weight of oxide The first mixture containing 1.20% by weight, 70.19% by weight of silicon dioxide, 16.41% by weight of aluminum oxide, 2.85% by weight of ferric oxide, 0.27% by weight of titanium dioxide, 3.67% by weight of calcium oxide, 0.82% by weight of magnesium oxide, oxide A microorganism collection member for water treatment, characterized in that formed by sintering to a predetermined grain size at a high temperature by selecting any mixture of the second mixture containing 2.81 wt% sodium, 1.81 wt% potassium oxide, and 1.20 wt% ignition loss. The method of claim 1, The granules have at least one flow hole (22a) through the body 22, microbial collection member for water treatment, characterized in that the grooves (22b) of various forms are formed on the surface. As a method for producing a microbial cell member used for purifying water or removing odor, (a) 70.05% by weight of silicon dioxide, 19.71% by weight of aluminum oxide, 2.72% by weight of ferric oxide, 0.33% by weight of titanium dioxide, 2.10% by weight of calcium oxide, 0.76% by weight of magnesium oxide, 1.55% by weight of sodium oxide, 1.07% by weight of potassium oxide %, Loss of ignition 1.20% by weight of the first mixture, silicon dioxide 70.19% by weight, aluminum oxide 16.41% by weight, ferric oxide 2.85% by weight, titanium dioxide 0.27% by weight, calcium oxide 3.67% by weight, magnesium oxide 0.82% by weight Selecting a mixture of any one of a second mixture consisting of%, sodium oxide 2.81 wt%, potassium oxide 1.81 wt%, and loss on ignition 1.20 wt%; (b) injecting the selected first or second mixture into a mold and heating it to 800 ° C. to 1800 ° C. for a predetermined time; And (c) removing the impurities penetrated into the heated sintered material and then cooling in a rotating or vacuum state.