KR102282032B1 - a device for cultivating microorganism - Google Patents

Abstract

The present invention relates to an air supply device, and more particularly, to an air supply device for easily dissolving air by supplying air in the form of fine bubbles when supplying air to places such as a microorganism incubator or a septic tank.
In the present invention for achieving the above object, in a microorganism incubator for culturing microorganisms therein, a tank in which the culture solution is accommodated, an inlet formed in the upper part of the tank, and formed so as to penetrate from the outside to the inside of the tank and an air supply pipe for supplying air, and an air dissolving unit for pulverizing the air supplied from the air supply pipe into fine bubbles is provided at the lower inner side of the tank.

Description

Air supply device {a device for cultivating microorganisms}

The present invention relates to an air supply device, and more particularly, to an air supply device for easily dissolving air by supplying air in the form of fine bubbles when supplying air to places such as a microorganism incubator or a septic tank.

In general, microorganisms are widely used in agriculture, livestock, fisheries, etc. As a method of using these microorganisms, photosynthetic bacteria, lactic acid bacteria, bacillus, yeast, cyanobacteria, etc. are cultured, diluted in water, and then seed disinfected and sprayed on the soil , irrigation or foliar application of crops and feeding to livestock.

Through such microorganisms, it is possible to promote the production of crops, prevent pests and diseases, and in the case of livestock, promote growth and prevent diseases, improve meat quality, and reduce odor and contamination of excrement, as well as inhibit the growth of pathogens or beneficial bacteria. It is used to help and to obtain the effect of inhibiting harmful bacteria.

In addition, microorganisms can be used for water purification, organic waste fermentation agent, and various industrial waste purification in the environmental field. When used in aquaculture, there are effects such as water purification, suppression of pathogens, and improvement of disease resistance. As one method, there are several physicochemical methods and biological methods for the treatment of wastewater.

Of these, the physicochemical method is expensive and has the disadvantage of having to reprocess the product after treatment, while the biological method decomposes and stabilizes a significant amount of organic components in the form of carbon dioxide or generates methane gas to produce organic matter in wastewater. By removing , the amount of product after treatment is relatively small.

And, the biological treatment method mainly uses microorganisms to decompose, detoxify and separate pollutants in wastewater, and is mainly used for secondary treatment of urban sewage, treatment of factory wastewater containing organic matter and sludge produced therefrom. It is the most widely used wastewater treatment method in the world due to its relatively low cost and various processes.

The microorganisms that play a key role in the biological treatment are mainly cultured and propagated in an incubator, and are a mixed culture composed of microorganisms of different populations of bacteria, fungi, protozoa and metazoans. It purifies wastewater by decomposing and removing organic pollutants using organic pollutants as nutrients.

The incubator in which the microorganisms used for such biological treatment are cultured is a device that creates an environment similar to the natural environmental conditions in which random microorganisms can best culture and propagate, supplying the solution, organic and inorganic medium, and air to be cultured inside. This results in culturing and propagation of microorganisms.

As an example of such a microorganism incubator, there is a technology described in Korean Patent No. 10-0698549 as shown in FIGS. 1 and 2, and the technical feature is that in a microorganism incubator for culturing microorganisms, the culture of microorganisms is made a culture vessel 20; Culturing in the culture vessel 20, including a supply pipe 30 connected to the upper part of the culture vessel 20, and a pump 31 installed on the supply pipe 30 to supply the culture solution to the culture vessel 30 a supply unit for supplying the desired solution and organic and inorganic medium; a stirring unit for receiving air from the air supply blower 40, injecting air into the culture solution in the culture vessel, and agitating the culture solution; Including a heater 51 installed inside the culture vessel 20, a control means 52 for controlling and operating the heater 51, and a temperature control unit for maintaining the temperature of the culture medium and performing sterilization, the stirring unit Connected to the blower 40 and installed vertically along the side of the culture vessel, the air supply hose 41 and two branch lines extending inward from the air supply hose 41 through the side of the culture vessel 20 ( 43, 44), annular injection pipes 60 and 61 connected to the ends of each branch line 43, 44, arranged along the outer circumferential surface of the upper injection pipe 60, in the outer direction of the injection pipe 60, the lower The injection nozzle 62 installed to face within the range of the direction, the injection nozzle 63 arranged along the outer circumferential surface of the lower injection pipe 61 and installed to face within the range of the upper direction from the inner direction of the injection pipe 61 ) is characterized in that it further comprises.

However, the technology described in Korean Patent No. 10-0698549 has the advantage of stably cultivating microorganisms by simultaneously stirring the culture medium and supplying oxygen, but because air is simply sprayed into the culture medium, oxygen is not absorbed into the culture medium. In the case of aerobic microorganisms that require a lot of oxygen because they cannot be stably dissolved in the air, there is a problem that sufficient oxygen cannot be supplied.

Korean Patent No. 10-0698549

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a tank with a culture solution for culturing microorganisms or a bubble generated in the process of supplying air to the lower center of a tank for purifying sewage, etc. of microorganisms for decomposing contaminants in the culture of microorganisms or sewage by pulverizing into fine bubbles through the distribution member and the rotary provided inside the distribution member so that air is more rapidly dissolved in the liquid accommodated in the tank. It is to provide an air supply device capable of stably supplying oxygen necessary for the operation.

And, another object of the present invention is that the distribution hole is formed radially in the distribution member for supplying air to the inside of the tank, and the direction of the distribution hole is formed to be inclined at a predetermined angle in the horizontal direction, so that air bubbles injected through the distribution hole are formed. An object of the present invention is to provide an air supply device capable of agitating the liquid contained in the tank even without a separate stirrer by rotating the liquid.

The present invention for solving these problems;

An air supply device for supplying air to a tank in which a liquid is accommodated, the air supply pipe being formed to pass through from the outside to the inside of the tank and supplying air, and a lower portion of the tank for supplying air supplied from the air supply pipe to fine bubbles It is characterized in that it comprises an air dissolving unit pulverized with a furnace.

Here, the air dissolving unit is characterized in that it comprises a rotor for spraying the air supplied from the air supply pipe to the side, and a distribution member having a receiving portion formed in the central portion is rotatably provided with the rotor.

At this time, it is characterized in that the distribution hole is formed in a radial direction with respect to the central portion of the distribution member so as to communicate with the receiving portion on the outside of the receiving portion.

In addition, a cover plate is provided on the upper portion of the distribution member, and a first through hole is formed in the center of the cover plate so as to penetrate vertically, and an upper portion of the center of the first through hole is supported by a support formed at the upper edge of the cover plate. A connector is provided, and an upper protrusion protruding to the upper portion of the rotor is rotatably connected to a lower portion of the connector, and an end of the air supply pipe is connected to an upper portion of the connector.

At this time, the rotor is characterized in that the injection hole for injecting air in the radial direction is formed, and the upper protrusion is formed with a connection hole communicating with the injection hole.

According to the present invention having the above configuration, a bubble generated in the process of supplying air to the center of the lower end of a tank for purifying a tank or a tank for purifying sewage or the like provided with a culture solution for culturing microorganisms is provided inside the distribution member and the distribution member. By pulverizing into fine bubbles through the rotary, air is dissolved more quickly in the liquid contained in the tank, so that oxygen necessary for the culturing of microorganisms or the action of microorganisms to decompose contaminants in sewage can be stably supplied. It works.

And, the present invention is a distribution hole is formed radially in the distribution member for supplying air to the inside of the tank, by forming the direction of the distribution hole to be inclined at a certain angle in the horizontal direction, liquid by air bubbles injected through the distribution hole to rotate, so that the liquid contained in the tank can be stirred even without a separate stirrer.

1 is a conceptual diagram showing the overall configuration of a conventional microbial incubator.
2 is a schematic cross-sectional view of a conventional microbial incubator.
3 is a conceptual diagram of a microorganism incubator installed with an air supply device according to the present invention.
Figure 4 is an exploded perspective view of the air dissolving unit of the air supply device according to the present invention.
5 is a conceptual view showing a cross section of an air dissolving unit of the air supply device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and repeated descriptions of the same components are omitted. And, it should be understood that the present invention may be implemented in many different forms and is not limited to the described embodiments.

3 is a conceptual diagram of a microorganism incubator installed with an air supply device according to the present invention, FIG. 4 is an exploded perspective view of an air dissolving unit of the air supply device according to the present invention, and FIG. 5 is an air dissolving unit of the air supply unit according to the present invention It is a conceptual diagram showing a cross-section.

The present invention relates to an air supply device installed in a tank such as a microbial incubator or septic tank for culturing microorganisms therein to supply air to a liquid accommodated therein. The microorganism incubator is formed to penetrate from the outside to the inside of the tank 100 and the inlet 110 formed in the upper part of the tank 100 and the tank 100, as shown in FIG. 3 , the culture solution is accommodated therein. and an air supply pipe 200 for supplying air.

Here, an air supply (not shown) for supplying air is provided on the outside of the tank 100 to supply air to the inside of the tank 100 through the air supply pipe 200 , and the air supply pipe 200 ) is provided with an air filter 210 for filtering foreign substances contained in the air, so that clean air can be supplied to the inside of the tank 100 .

At this time, although not shown in the drawings, a heater and a temperature sensor are further provided inside the tank 100 so that the temperature of the culture solution accommodated therein is appropriately adjusted to suit the microorganisms culturing the microorganisms so that the microorganisms can be stably cultured.

And, the air supply device of the present invention is provided in the lower portion of the air supply pipe 200 and the tank 100 for supplying air to the inside of the tank 100, as shown in FIGS. 3 to 5, the air It consists of an air dissolving unit 300 connected to the end of the supply pipe 200 to receive air, and the air dissolving unit 300 pulverizes the air supplied from the air supply pipe 200 into fine bubbles. By allowing it to dissolve easily inside, it is possible to stably supply oxygen to the cultured microorganisms.

Here, the air dissolving unit 300 includes a rotor 340 for laterally spraying the air supplied from the air supply pipe 200 and a distribution member 330 provided so that the rotor 340 is rotatable therein, and the The distribution member 330 includes a distribution hole 334 formed in a radial direction.

At this time, the rotor 340 is formed in a circular shape, and the receiving part 332 in which the rotor 340 is rotatably provided is formed in the center of the distribution member 330 , and the outer side of the receiving part 332 is formed. The distribution hole 334 is formed in the accommodating part 332 to communicate with the outside.

Thus, the air supplied from the air supply pipe 200 is sprayed laterally through the rotor 340 , and since the rotor 340 rotates, the air collides with the wall surface of the accommodating part 332 and forms fine bubbles. It is crushed and dissolved in the culture medium.

In addition, the air-dissolved culture solution and the undissolved air (bubbles) are sprayed in an all-outward direction of the distribution member 330 through the distribution hole 334 formed on the outside of the receiving part 332 .

At this time, the distribution hole 334 is formed radially with respect to the center of the injection member 330 and is inclined in the horizontal direction, so that by the culture solution and air injected through the distribution hole 334, the The culture medium accommodated therein is rotated.

Therefore, the air dissolving unit 300 pulverizes the air supplied from the air supply pipe 200 so that it is easily dissolved in the culture solution, and the entire culture solution rotates, thereby stably stirring the culture solution even without a separate stirrer. be able to do

On the other hand, the upper portion of the distribution member 330 is provided with a cover plate 350, the cover plate 350 is formed to correspond to the shape of the distribution member 330, the first through hole 352 so as to penetrate vertically in the center. this is formed

Here, a connector 356 is provided at an upper portion of the central portion of the first through hole 352 , and the connector 356 is supported by a support 354 formed at an edge of the upper surface of the cover plate 350 .

At this time, a central hole 357 is formed in the center of the connector 356 so as to penetrate vertically, and an upper protrusion 344 protruding from the center of the rotor 340 is rotatable in the lower portion of the connector 356 . and the end of the air supply pipe 200 is connected to the upper portion of the connector 356 .

In addition, the rotor 330 is formed in a circular shape, and a plurality of injection holes 342 for spraying air in a radial direction are formed, and the upper protrusion 344 is formed in the center of the upper surface of the rotor 330, the upper A connection hole 345 is formed in the center of the protrusion 334 to penetrate vertically, and a lower portion of the connection hole 345 is formed to communicate with the injection hole 342 .

Accordingly, the air supplied through the air supply pipe 200 connected to the upper portion of the connector 356 is the rotor 330 through the connection hole 345 of the upper protrusion 344 connected to the lower end of the connector 356 . It is supplied to the injection port 342 to be injected to the outside.

At this time, a first sealing member 358 made of PTFE (Polytetrafluoroethylene, Teflon) is provided at the lower inner side of the connector 356, and PTFE (Teflon) has high chemical resistance and low wear coefficient, so the upper protrusion ( 344), it is possible to rotate stably while increasing the sealing force by minimizing the frictional force.

On the other hand, an installation hole 120 is formed in the lower center of the tank 100 so as to penetrate vertically, and a plate-shaped fixing plate 310 is provided at the lower portion of the installation hole 120 to cover the lower portion.

Here, a fixing ring 320 is provided on the upper portion of the installation hole 120 , and the fixing ring 320 is fixed to the fixing plate 310 by bolting, and on the upper surface of the edge of the fixing plate 310 . A packing groove 312 into which the ring-shaped packing 314 is inserted is formed to seal the space between the fixing plate 310 and the tank 100, thereby preventing the culture solution contained therein from leaking.

At this time, a support leg 319 is provided on the upper surface of the fixing plate 310 , and the distribution member 330 is coupled and supported on the upper end of the support leg 319 so that the distribution member 330 is the lower part of the tank 100 . and is spaced apart from each other by a predetermined distance, and a cover part 322 is formed on the upper portion of the fixing ring 320 to cover the side of the support leg 319 .

In addition, a lower protrusion 346 is formed in the center of the lower surface of the rotor 340 to protrude downward, and a second through hole 336 is formed in the lower surface of the receiving portion 332 formed in the center of the distribution member 330 . is formed so that the lower protrusion 346 protrudes downward through the second through hole 336 .

Here, a third through hole 316 penetrating up and down is formed in the center of the fixing plate 310 , and a shaft 410 is inserted into the third through hole 316 , and the upper end of the shaft 410 is the lower portion. It is connected to the protrusion 346 , and the lower end of the shaft 410 is connected to the motor 400 provided in the lower part of the tank 100 .

At this time, a fixing groove 347 is formed in the center of the lower protrusion 346 , and the upper end of the shaft 410 is inserted into the fixing groove 347 and fixed through a fixing bolt (not shown), the shaft A keyway (not shown) is formed in the upper side of the 410 and the inside of the fixing groove 347 to correspond to each other, and a key (not shown) is provided in the keyway (not shown) to transmit the rotational force of the motor 400 . is transmitted to the rotor 340 .

In addition, the rotor 340 is positioned to be spaced a predetermined distance between the lower surface of the cover plate 350 and the receiving part 332 , and when air is sprayed through the injection hole 342 of the rotor 340 , the distribution hole 334 . ) through which air and a culture solution in which the air is melted are sprayed to form a negative pressure inside the receiving part 332 .

Therefore, the culture solution located outside is introduced through the first through-hole 352 formed in the cover plate 350 and the second through-hole 336 formed in the receiving part 332 , so that the inside of the tank 100 is The culture solution accommodated in the is allowed to flow, and the culture solution is stirred more stably.

And, an outlet 311 is formed in the lower portion of the fixing plate 310 to discharge the culture medium in which the microorganisms accommodated therein are cultured to the outside, and although not shown in the figure, the outlet 311 has a valve (not shown). is provided to control emissions.

Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the scope of the present invention extends to those substantially equivalent to the embodiments of the present invention. Various modifications are possible by those of ordinary skill in the art to which the invention pertains without departing from the scope of the invention.

The present invention relates to an air supply device, and more particularly, to an air supply device for easily dissolving air by supplying air in the form of fine bubbles when supplying air to places such as a microorganism incubator or a septic tank.

100: tank 110: inlet
120: installer 200: air supply pipe
210: air filter 300: air dissolving unit
310: fixing plate 320: fixing ring
330: distribution member 340: rotor
350: cover plate 400: motor
410: shaft

Claims (5)

An air supply device for supplying air provided in a tank in which a liquid is accommodated,
an air supply pipe that is formed to penetrate from the outside of the tank to the inside to supply air;
The lower portion of the tank comprises an air dissolving unit that pulverizes the air supplied from the air supply pipe into fine bubbles,
The air dissolving unit comprises a rotor for discharging the air supplied from the air supply pipe to the side, and a distribution member having a receiving unit formed in the center so that the rotor is rotatably provided,
A distribution hole is formed on the outer side of the receiving part in a radial direction with respect to the center of the distribution member so as to communicate with the receiving part, and the distribution hole is formed to be inclined in a horizontal direction. The culture medium accommodated inside rotates,
An installation hole is formed in the lower center of the tank to penetrate vertically, a plate-shaped fixing plate is provided at the lower portion of the installation hole to be located outside the tank, and a fixing ring is located at the upper portion of the installation hole to be located inside the tank is provided, and the fixing ring is fixed to the fixing plate by bolting,
A shaft is installed in the center of the fixing plate so as to penetrate vertically, an upper end of the shaft is connected to a lower portion of the rotor, and a lower end of the shaft is connected to a motor installed under the fixed plate.
delete delete According to claim 1,
A cover plate is provided on the upper portion of the distribution member,
A first through hole is formed in the center of the cover plate so as to penetrate vertically,
A connector supported by a support formed on an edge of the upper surface of the cover plate is provided at an upper portion of the center of the first through hole,
An upper protrusion protruding from the upper portion of the rotor is rotatably connected to a lower portion of the connector,
An end of the air supply pipe is connected to an upper portion of the connector.
5. The method of claim 4,
The rotor is formed with an injection port for spraying air in a radial direction,
The air supply device, characterized in that the upper protrusion is formed with a connection hole communicating with the injection port.

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