KR101863693B1 - Mass microorganism culture medium - Google Patents

Abstract

Disclosed is a mass microorganism culture medium. The mass microorganism culture medium includes: a starter tank preparing a starter to be cultured; a molasses mixing tank capable of manufacturing a molasses mixture used for culture of the starter; an atomizing device for atomizing the molasses mixture manufactured in the molasses mixing tank; and a nutrition tank in which the molasses mixture atomized in the atomizing device and the starter of the starter tank can be mixed with each other. According to the present invention, the mass microorganism culture medium ultra-atomizes the molasses used as feed for microorganisms and remarkably increases the growth rate of microorganisms by remarkably increasing the specific surface area of the microorganism to the feed. Also, the mass microorganism culture medium supplies the molasses mixture maintaining an optimal temperature and increases the microorganism′s speed of proliferation. Therefore, the mass microorganism culture medium can increase the efficiency of a culture medium.

Description

Mass microorganism culture medium

The present invention relates to a large-scale microorganism incubator.

Microorganisms are collectively referred to as small-sized organisms that are difficult to see, and their size is so small that they are treated as one group of millions of individuals rather than as one unit, Fungi, protozoa, bacteria, viruses, and algae.

Yeast, lactic acid bacteria, mycelia, photosynthetic bacteria, actinomycetes and the like, which are useful microorganisms for humans, are cultivated in a large number of fields and used in various fields such as fermentation, food, and detergent.

Providing temperature, humidity, and nutrients to grow these microorganisms so that they grow well under the right conditions is called an incubator.

Examples of such incubators are those of the patent literature presented below.

Conventionally, microorganisms were cultured in a general incubator including the patented hurdles shown below by inoculating molasses or sugar, which is normally used as microbial food, in water to inoculate the seeds.

However, in such a case, the molasses of a large lump was not sufficiently dissolved in the water, so that the microorganisms to be cultured had a limited contact area.

As a result, there has been a problem that molasses which is not used in culturing microorganisms in water is excessively left.

In addition, the molasses of a large lump, which does not sufficiently dissolve in water as described above, has a limited area in which microorganisms can contact, which slows down the cultivation of microorganisms.

If the temperature is raised to quickly melt molasses due to such a problem, there is a problem that the microorganism does not meet the culture conditions.

Registration Utility Model No. 20-0462334, Registration Date: August 31, 2012, Designation: Microorganism incubator Registered Utility Model No. 20-0374269, Registered Date: 17.01.2007. Name of Design: Microorganism incubator

The present invention relates to a method for preparing a molasses mixture for microbial food by superabsorbing molasses which is used as a food for microbes, thereby increasing the specific surface area of the microbes with respect to food, thereby increasing the rate of microbial cultivation and supplying a molasses mixture maintained at an appropriate temperature, And an object of the present invention is to provide a large-scale microorganism incubator capable of increasing the efficiency of the incubator.

In accordance with one aspect of the present invention, a large-scale microorganism culture apparatus includes a seed culture in which a seed culture to be cultured is prepared; A molasses mixing tank in which a molasses mixture used for culturing the seeds can be prepared; An atomizing device capable of making the molasses mixture produced in the molasses mixing tank into a fine particle; A nutritive water tank in which the molasses mixture finely atomized in the fine particleizing apparatus is stored before being introduced into a culture tank; And a device-moving member to which the fine particleizing device can be moved, wherein the fine particleizing device is connected to a part of the nutritive water tank, and a device-side connection for allowing the molasses mixture of the fine particleizing device to flow into the nutritive water tank Side connection member is formed in the nutrient water tank so as to be engaged with and connected to the device-side connection member, and the device-side connection member and the water-tank-side connection member are connected to each other And is formed in a magnetic shape.
Another aspect of the present invention is a large-scale microorganism culture apparatus comprising: a seed culture in which a seed culture to be cultured is prepared; A molasses mixing tank in which a molasses mixture used for culturing the seeds can be prepared; An atomizing device capable of making the molasses mixture produced in the molasses mixing tank into a fine particle; And a nutritious water tank in which the molasses mixture finely atomized in the fine particleizing apparatus is stored before being introduced into the culture tank, wherein the fine particleizing apparatus comprises a driving motor, a case capable of forming the molasses mixture into fine particles inside the driving motor, And an engaging protrusion formed on the lower end of the engaging body so as to protrude outward from the engaging body is formed on the lower end of the engaging body, A screw shaft having a threaded portion formed at a predetermined length from the upper end of the central shaft member and having a rotational direction and a screw thread portion connected to the central shaft member and rotated while rotating the central shaft member, A pulverizing blade capable of pulverizing the molasses mixture into fine particles, A threaded upper fixing part formed on an inner surface of the threaded part to engage with the thread of the threaded part and a lower threaded part which is disposed in a lower part of the case and is connected to the central shaft part, Wherein the engaging protrusion is formed in the engaging body so that the engaging protrusion can be moved to a length corresponding to the raised height of the compression plate, When the drive motor is driven, the latching body is rotated so that the latching groove pushes the latching protrusion in the direction of rotation so that the latching protrusion is rotated, As the projection rotates, the central shaft member is rotated, and the central shaft member upper The screw portion formed on the screw portion is raised or lowered along the screw top fixing portion and the compression plate member is moved up or down according to the upward or downward movement of the screw portion.

According to an aspect of the present invention, there is provided a mass culture apparatus for culturing a seed microorganism; A molasses mixing tank in which a molasses mixture used for culturing the seeds can be prepared; An atomizing device capable of making the molasses mixture produced in the molasses mixing tank into a fine particle; And a nutritious water tank in which the molasses mixture microparticulated in the micropartizing machine and the seeds of the seedlings can be mixed with each other, whereby the molasses used as food for the microorganisms is converted into ultrafine microparticles so that microorganisms have a specific surface area It is possible to increase the microbial growth rate and increase the efficiency of the incubator by supplying the molasses mixture with a rapid increase in the microbial growth rate and maintaining the proper temperature.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a large-scale microorganism incubator according to a first embodiment of the present invention. FIG.
FIG. 2 is an enlarged view of an enlarged view of FIG. 1 A schematically showing the internal components of the fine particleizing device according to the first embodiment of the present invention. FIG.
3 is an enlarged view showing a cross-sectional view of a side surface of a wing of a fine particleizing device according to a first embodiment of the present invention.
FIG. 4 is a view showing a large-scale microorganism culture apparatus according to a second embodiment of the present invention. FIG.
5 is a view showing a state in which the apparatus for side connection of the apparatus for fine particle formation according to the second embodiment of the present invention is coupled to the first tank side connecting member of the first nutritious water tank.
FIG. 6 is a view showing a state where the device-side connecting member and the second water tank side connecting member of the second nutrient water tank are coupled with each other by moving the fine particleizing device according to the second embodiment of the present invention.
7 is a view showing a large-scale microorganism culture apparatus according to a third embodiment of the present invention.
FIG. 8 is an enlarged view of an enlarged view of FIG. 7B schematically showing internal components of a fine particleizing device according to a third embodiment of the present invention; FIG.
9 is a view showing a state in which a compression plate member according to a third embodiment of the present invention is lifted.
FIG. 10 is a perspective view of an engaging body portion according to a third embodiment of the present invention, viewed from above. FIG.

Hereinafter, a large-scale microorganism incubator according to embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a view showing a large-scale microorganism incubator according to a first embodiment of the present invention. FIG. 2 is a schematic view of an internal component of the micropartizing device according to the first embodiment of the present invention. FIG. 3 is an enlarged view showing a cross-sectional view of a side surface of a wing of a fine particleizing device according to a first embodiment of the present invention.

1 to 3 together, the large-scale microorganism incubator 100 according to the present embodiment includes a seedling tank 110, a molasses mixing tank 120, a micropartizing device 130, a nutritious water tank 140, .

The microorganism culture apparatus 100 is used to cultivate microorganisms such as fermentation, detergent, and wastewater which are used in various fields such as sewage treatment. In the present embodiment, the microorganisms are collectively referred to as seeds.

The large-scale microorganism incubator 100 further includes a plurality of incubation tanks 150 for storing the seeds that have passed through the nutrient solution tank 140 to a predetermined amount or more.

The seedling bath 110 is a water tank in which the seedling to be cultured is prepared. When the seedling valve 111 is opened, the seedling is introduced into the seedling bath 110. When the seedling valve 111 is closed, The operation to flow into the seedling bath (110) is stopped.

In this case, the seedlings 110 provide an environment in which the seeds can be activated. For example, an apparatus capable of maintaining temperature and humidity suitable for the seed can be included.

Wherein the molasses mixture is used as a food for the seed for propagation of the seed.

For example, the molasses mixture may be composed of a mixture of molasses, water and salt. Generally, the molasses mixture for seed culture is a mixture of water: molasses: salt in a ratio of 1000: 250: 5 And the molasses mixture for the stock solution culture is composed of a mixture having a ratio of water: molasses: salt of 1000: 25: 1.

Here, when sugar is used as a substitute for molasses, 1/2 of molasses is added.

A water tank in which a molasses mixture to be used for culturing the seeds is prepared is referred to as the molasses mixing tank 120, and a water tank of 200 liters is usually used. In the tank, a mixture of materials for preparing the molasses mixture is mixed And a pump (not shown) for allowing the molasses mixture to flow to the fine particleizer 130 after the production of the molasses mixture is completed is provided inside the molasses mixing tank 120 As shown in Fig.

As described above, when the molasses mixture is produced in the molasses mixing tank 120, the molasses mixture, such as the molasses or the salt, is not agglomerated or diluted with water so that the molasses The surface area per molecule of the mixture was very narrow.

For this reason, the molasses mixture produced in the molasses mixing tank 120 flows into the fine particleizer 130 to be described later, and the molasses mixture is made into fine particles so as to enlarge the surface area per molecule of the molasses mixture.

The micropartizing device 130 is capable of making the molasses mixture produced in the molasses mixing tank 120 into a microparticle and comprises an instrument body 131, a crushing member 132, a temperature adjusting member 134, And a control unit 133. [

The instrument body 131 is a body of the micropartizing machine 130 that is passed through the molasses mixing tank 120 to be converted into microparticles before the molasses mixture flows into the nutritive water tank 140, The inside may be formed into a hollow water tank so as to contain the molasses mixture.

2, the pulverizing member 132 may be a wing 135 having a plurality of fine particle holes 137 similar to the particle size of the molten mixture in the apparatus body 131, And a crushing drive motor 136 for imparting a driving force to the vanes 135 to rotate the vanes 135 is formed.

3, the perforated surface in the direction in which the vanes 135 are rotated is formed in a trapezoidal shape wider than the surface through which the other side is penetrated, as shown in FIG. 3 have.

When the wing 135 is formed as described above, the molasses mixture is injected into the relatively wide through-hole of the fine particle hole 137, and the wing 135 continuously rotates in this state, The molasses mixture injected into the relatively wide perforated surface of the particulate filter 137 is disassembled as it is discharged into the relatively narrow perforated surface of the particulate hole 137.

That is, by decomposing the molasses mixture similar to the size of the relatively narrow perforated surface of the fine particle hole 137, the molasses mixture can be made into fine particles.

The temperature regulating member 134 integrates a temperature sensor, a cooler and a heater for adjusting a required temperature of the molasses mixture before the molasses mixture crushed in the device body 131 is introduced into the nutritive water tank 140 It is.

Here, the required temperature of the molasses mixture refers to the temperature at which the seedling propagates.

The growth of the seeds is greatly influenced by the environment. In such seeds, the temperature is too low depending on the type thereof, and the maximum growth temperature at which the seeds can not live is too high and the maximum growth temperature at which the seeds can no longer grow exist.

There is also an optimum growth temperature at which the propagation of the seed is most active between the minimum growth temperature and the maximum growth temperature.

Conventionally, the molasses mixture flows into the nutritious water tank 140 without being adjusted to the optimum growth temperature for actively propagating the seed. However, as described above, the optimum growth rate of the molasses mixture in the nutritive water tank 140 The molasses mixture to which the temperature has been adjusted is transferred to the culture tank 150 to meet the seed bacteria to provide an environment in which propagation of the seed bacteria can be performed well.

The control unit 133 controls the intensity and time at which the wing 135 of the crushing member 132 rotates according to the amount of molasses mixture in the body 131 of the apparatus, And the operation of the cooler and the heater can be controlled according to the value measured by the temperature sensor.

That is, the operation of the crushing drive motor 136 can be adjusted according to the amount of molasses mixture introduced into the device body 131 from the molasses mixing tank 120, and the optimal growth temperature And controls the cooler and the heater according to the temperature to control the temperature sensor value to approach the optimum growth temperature.

When the molasses mixture is formed as described above, for example, the molasses mixture may be made into fine particles at a time of about 30 minutes per ton of the molasses mixture using the micropartizing machine 130, The mixture can be called nutrient water.

The micropartizing device 130 is provided with a drain pipe 170 through which the nutrient water can be supplied to supply the nutrient water to the nutritive water tank 140.

The drain pipe 170 is connected to the microfibrillator 130 and includes an inlet 172 through which the nutrient solution is discharged in the device body 131 and a water inlet 172 through which the nutrient water is introduced into the nutrient water tank 140, A clockwise drain 173 may be formed using a memory elbow.

The water supply pipe 170 is connected to the water supply pipe 170 and the water supply pipe 170. The water supply pipe 170 is connected to the water supply pipe 140 through the drain pipe 170, A high-pressure pump member 171 is formed.

When the high-pressure pump member 171 is operated, the nutrient solution remaining in the drain pipe 170 flows rapidly into the apparatus body at a high pressure.

When the high pressure pump member 171 is formed as described above, the nutrient remaining in the drain pipe 170 is discharged from the inlet port 172 of the drain pipe 170 but is not discharged from the drain port 173, The nutrient water remaining in the water pipe 170 and fluctuating in temperature can be prevented from flowing into the nutritious water tank 140. As a result, It is possible to provide the nutrient water suitable for the temperature.

As described above, by feeding the nutrient water in the form of fine particles into the nutritive water tank 140 using the fine particleizing device 130, the specific surface area of the molasses mixture with respect to food of the seed bacterium is drastically increased The rate of propagation of the seed bacterium is further improved and the propagation rate of the seed bacterium is further improved as compared with the conventional method by providing the nutrient solution meeting the optimal growth temperature of the seed bacterium.

In addition, the efficiency of the large-scale microorganism incubator 100 can be increased.

In addition, since the molasses mixture in a lumpy state has a small surface area, it is not possible to properly serve as a feed for the seeds, and it is also possible to deposit a hole such as a pipe or a valve inside the nutritive water tank 140 And malfunction of the device occurred. However, the above-mentioned problem was solved by making the molasses mixture into fine particles as described above.

The nutrient water tank 140 is a water tank that is stored before the nutritive water, which is the molasses mixture made into fine particles in the fine particleizing device 130, flows into the culture tank 150, And a water / automatic temperature control function for storing the nutrient water.

The culture tank 150 can be manually or automatically controlled in temperature and the seeds are transferred from the seedling tank 110 and the nutrient water is transferred from the nutritive water tank 140 to be mixed with each other to cultivate the seedlings In the present embodiment, the culture tank 150 is composed of three, but may be formed of a plurality of different culture vessels 150.

Hereinafter, a method of culturing the seed culture in the culture tank 150 will be briefly described.

The initial culture method is a method in which a seed solution containing the seed is transferred from the seedling bath 110 to the culture tank 150 and the nutrient solution is transferred from the nutritive water tank 140 to the culture tank 150, And the nutrient solution are mixed with each other to cultivate the seeds.

Here, in the above-described first culture method, the ratio of the seed solution to the nutrient solution can be combined at a ratio of 1: 1.

After the above-mentioned formation, for example, the mixture is stirred twice for 10 minutes each day, and when the pH value is 3.8 pH or less, the cultivation of the seeds is completed and the cultivation is terminated.

In the continuous culture method, when a stock solution is present in the culture tank 150 and the seeds are mixed with the nutrient solution, the ratio of the seeds of the seedling 110 to the nutrient solution is adjusted to 5: (150) to cultivate the seeds. At this time, the total amount of the seed germs and the nutrient solution newly introduced into the culture tank 150 should not exceed the total amount of the original stock solution in the culture tank 150.

After the above-mentioned formation, for example, the mixture is stirred twice for 10 minutes each day, and when the pH value is 3.8 pH or less, the cultivation of the seeds is completed and the cultivation is terminated.

Hereinafter, a large-scale microorganism incubator according to another embodiment of the present invention will be described with reference to the drawings. In carrying out these explanations, the description overlapping with the content already described in the first embodiment of the present invention described above will be omitted and omitted here.

FIG. 4 is a view showing a large-scale microorganism incubator according to a second embodiment of the present invention. FIG. 5 is a schematic view of a microorganism culture apparatus according to a second embodiment of the present invention, FIG. 6 is a view showing a state in which the apparatus for connection to the water tank is connected; FIG. 6 is a view showing a state in which the apparatus for connection of the apparatus and the second water tank side connecting member of the second nutrition tank are connected FIG.

4 to 6, the mass culture apparatus 200 according to the present embodiment includes a seedling tank 210, a molasses mixing tank 220, a particleizer 230, a nutrient tank 240 270, and a device-moving member 260. The device-

The molasses mixing tank 220 in this embodiment includes a flow pipe 221 serving as a moving passage for allowing the molasses mixture to flow to the fine particleizer 230, Is connected between a portion of the molasses mixing vessel 220 and a portion of the micropartizing machine 230 to allow the molasses mixture in the bath 220 to flow into the micropartizing machine 230.

The flow pipe 221 may be formed of a rubber pipe that can be bent to move in accordance with the micropartizing device 230 having a high mobility.

The micropartizing device 230 is connected to a part of the nutritious water tanks 240 and 270 to connect the device side connecting member 240 for allowing the molasses mixture of the micropartizing device 230 to flow to the nutritive water tanks 240 and 270 238 are formed.

The water tub side connecting members 248 and 278 are formed in the nutrient water tanks 240 and 270 so as to be engaged with and connect to the apparatus side connecting member 238, respectively.

In the present embodiment, the nutritive water tanks 240 and 270 are constituted by the first nutrient water tank 240 and the second nutritious water tank 270, but it is needless to say that the nutritious water tanks 240 and 270 may be formed of a plurality of different ones.

A first water tank side connection member 248 is formed in the first nutrient water tank 240 and a second water tank side connection member 278 is formed in the second nutrition water tank 270.

The device-side connecting member 238 and the water-tank-side connecting members 248 and 278 may be formed of a quick connector that can be 100% sealed when coupled to each other, The water tank side connecting members 248 and 278 may be formed to be automatically engaged when they are close to each other, and such magnetic properties may also be adjusted.

The device moving member 260 is mounted on the micropartizing device 230 so that the micropartizing device 230 can be moved. For example, the micropartizing device 230 is movably coupled And may be formed of a rail formed with a predetermined length.

5, when the micropartizing device 230 is moved to the first nutrient solution tank 240 along the device moving member 260, the device-side connecting member 238 is moved to the first tank side And is coupled to the connecting member 248.

When the device side connecting member 238 is coupled to the first water tank side connecting member 248 as described above, the molasses mixture in the fine particleizing device 230 can be flowed into the first nutrient solution tank 240 have.

6, the device-side connecting member 238 is moved toward the second nutrient solution tank 270 by the second moving member 260, And is coupled to the water tub side connecting member 278.

When the device-side connection member 238 is coupled to the second water-tank-side connection member 278 as described above, the molasses mixture in the micropartizing device 230 can be flowed into the second nutrient solution tank 270 have.

That is, since the micropartizing device 230 can be connected to the required nutrient solution tanks 240 and 270 through the device moving member 260, a plurality of the nutritious water tanks 240 and 270 can be connected to the system There is no need to prepare the fine particleizer 230 and a plurality of marshmalline mixing vessels 220 corresponding thereto so that a plurality of fine granulating units 230 and a plurality of molasses mixing vessels 220 are used, Since the molasses compound can be supplied to the nutritious water tanks 240 and 270, the system can be simplified, and the facility cost can be reduced.

FIG. 7 is a view showing a large-scale microorganism incubator according to a third embodiment of the present invention, FIG. 8 is an enlarged view of FIG. 7B schematically showing internal components of a micropartizing device according to a third embodiment of the present invention And FIG. 9 is a view showing a state in which the compression plate member according to the third embodiment of the present invention is lifted. FIG. 10 is a perspective view of the latch body according to the third embodiment of the present invention.

7 through 10, the large-scale microorganism incubator 300 according to the present embodiment includes a seedling tank 310, a molasses mixing tank 320, a micropartizing device 330, a nutrient tank 340 ), And a culture tank 350.

Reference numeral 321 denotes a mixing side drain pipe allowing the molasses mixture 10 produced in the molasses mixing tank 320 to flow into the micropartizing device 330 and reference numeral 322 denotes a mixing side drain pipe 321, Is a mixed-side valve capable of closing the inside of the mixing-side drain pipe (321) to regulate the amount of the molasses mixture (10) to be introduced into the atomizer (330).

When the mixing valve 322 is opened, the molasses mixture 10 of the molasses mixing tank 320 flows to the micropartizing device 330 along the mixing-side drain pipe 321.

Reference numeral 341 denotes a nutrient drainage pipe for allowing the molasses mixture 10 of the fine particleizing device 330 to flow into the nutrient solution tank 340 and reference numeral 342 denotes a molten- Is a nutrient side valve capable of blocking the inside of the nutrient drain pipe 341 so that the amount of the mixture 10 flowing into the nutritive water tank 340 along the mixing drain pipe 321 can be controlled.

When the nutrient side valve 342 is opened, the molasses mixture 10 of the atomizing device 330 flows to the nutrient water tank 340 along the nutrient side drain pipe 341.

Generally, the mixing-side valve 322 and the nutrient-side valve 342 are closed and the micropartizing device 330 is operated.

When the atomizing valve 342 is opened in a state in which the air 20 in the case 330a is compressed, the atomizing device 330 in the present embodiment is operated to cause the air 20 to expand, The drive motor 335 and the engaging body 336 are formed by rapidly moving the molasses mixture 10 in the nutrient storage tank 330a to the nutritious water tank 340 along the nutritious drain pipe 341. [ A threaded portion 332, a threaded upper fixing portion 331, a compression plate member 334, a grinding wing 338, a coupling groove 339, a central shaft member 337, a threaded portion 332, (333).

The case 330a serves as the body of the fine particleizer 330, and the molasses mixture 10 can be made into fine particles in the case 330a.

The driving motor 335 rotates the engaging body 336 so that the central shaft member 337 rotates by the rotation of the engaging body 336 and the rotation of the central shaft member 337 The molten mixture (10) in the case (330a) is atomized while the crushing blade (333) rotates.

The engaging body 336 is connected to the driving motor 335 and rotated by driving the driving motor 335 so as to restrict the moving range of the engaging projection 338 The engaging groove 339 is formed.

The latching groove 339 is formed to have a predetermined length so that the latching protrusion 338 can be moved to a length corresponding to the height at which the compression plate member 334 is raised.

The lower end of the central shaft member 337 is inserted into the engaging body 336 and the engaging protrusion 338 protruding from the engaging body 336 is formed at a lower end thereof.

The threaded protrusion 338 is formed on the central shaft member 337 so that the threaded portion 332 formed on the upper portion of the central shaft member 337 rotates along the threaded upper fixing portion 331, ) Is raised.

As the engaging body 336 is rotated as described above, the engaging protrusion 338 engaged with the engaging recess 339 rotates along the engaging recess 339 and the engaging protrusion 338 As the central shaft member 337 rotates, the threaded portion 332, which will be described later, is rotated along the threaded upper fixing portion 331, and is lifted or lowered along the rotation direction thereof, The member 337 can be moved up and down.

When the central shaft member 337 is raised in the above-described state, the latching protrusion 338 rises along the latching groove 339 and is not able to rise anymore. At the upper end of the latching groove 339, So that the central shaft member 337 can not be moved upward any more.

The threaded portion 332 is formed to have a predetermined length in the upper end of the central shaft member 337 and has a threaded shape in the rotational direction and is moved up and down along the inner surface of the threaded upper fixing portion 331 to be described later.

The threaded upper fixing portion 331 is formed on the inner surface of the threaded portion 332 so as to rotate the upper portion of the threaded portion 332 and to engage with the threaded portion of the threaded portion 332.

The compression plate member 334 is connected to the central shaft member 337 so that the air 20 in the case 330a can be compressed as the threaded portion 332 is lifted and lowered. The compression plate member 334 is also disposed in the lower portion of the case 330a when the latching protrusion 338 is disposed at the lower end of the latching groove 339. [ Here, the lower end portion of the compression plate member 334 is a closed space, and the molasses mixture 10 at the upper end of the compression plate member 334 can not flow into the lower end portion of the compression plate member 334.

In this state, when the threaded portion 332 rotates along the threaded upper fixing portion 331 and the locking protrusion 338 rises to a position where it is caught by the upper end of the locking groove 339, as shown in FIG. 9 The compression plate member 334 is also lifted in accordance with the height at which the latching protrusion 338 is raised.

As the compression plate member 334 rises, the air 20 existing in the case 330a is compressed and the pressure of the air 20 is increased.

As described above, when the air 20 is compressed and the nutrient side valve 342 which is closed is opened, the air 20 expands so that the air 20 returns to the air pressure before the compression, The molasses mixture 10 in the case 330a can be rapidly pushed into the nutritious water pipe 341 toward the nutritive water tank 340 by the expansion force of the nut 32. [

The pulverizing blade 333 is connected to the central shaft member 337 and is rotated as the central shaft member 337 rotates. When the particles of the molasses mixture 10 collide with the pulverizing blade 333, The bond between the particles is broken and the molasses mixture 10 can be made into fine particles.

Although the method of raising the central shaft member 337 has been described in the present embodiment, the rotation of the driving motor 335 may be reversed to the direction of the original rotation so that the central shaft member 337 may be lowered Of course it is.

That is, when the rotation of the driving motor 335 is reversed, the threaded portion 332, which has been rotated along the threaded upper fixing portion 331, is rotated in the opposite direction to be lowered , The crushing blade 333 may be rotated in the same direction as the rotation direction of the screw portion 332 to continue to make the molasses mixture 10 into fine particles.

When the driving motor 335 of the fine particleizing device 330 is rotated in the state as described above, the engaging body 336 is rotated and the engaging protrusion 338 is caught by the engaging body 336 The central shaft member 337 is rotated together with the engaging body 336 so that the threaded portion 332 rises while being rotated by the threaded upper fixing portion 331 so that the central shaft member 337 The compression plate member 334 is lifted relative to the engaging body 336 so that the air 20 in the case 330a is compressed, The molasses mixture 10 which has been made into an atomized state can be discharged by the air 20 compressed in the case 330a.

Hereinafter, the process of making the molasses mixture 10 into fine particles using the fine particleizer 330 and then flowing the fine molasses mixture 10 to the nutritive water tank 340 will be described.

First, the mixing valve 322 is opened to flow the molasses mixture 10 produced in the molasses mixing tank 320 to the atomizer 330.

When the mixing valve 322 is opened as described above, the molasses mixture 10 of the molasses mixing tank 320 flows into the case 330a along the mixing-side drain pipe 321. [

Here, the amount of the molasses mixture 10 flowing into the case 330a is adjusted so that an air layer having a predetermined height or higher is formed in the case 330a.

In this state, the mixed-side valve 322 is closed so that the molasses mixture 10 of the mixed-side water pipe 321 can no longer enter the atomizer 330.

In this state, the driving motor 335 is driven to rotate the engaging body 336.

When the engaging body 336 is rotated, the engaging protrusion 338 is rotated while the engaging protrusion 338 is pushed in the direction of rotation.

The central shaft member 337 is rotated as the latching protrusion 338 rotates and the threaded portion 332 formed at the upper end of the main shaft member 337 is raised or lowered along the threaded upper fixing portion 331 .

Further, as the threaded portion 332 is raised or lowered, the compression plate member 334 connected to the central shaft member 337 is raised or lowered.

Here, the driving motor 335 determines whether the threaded portion 332 rises or falls according to a direction in which the engaging body 336 rotates.

When the driving motor 335 is driven in the rotating direction in which the threaded portion 332 is raised, the crushing blade 333 rotates in the same direction as the rotating direction, and the compression plate member 334 also rises do.

Conversely, when driving the drive motor 335 in the opposite rotational direction in which the threaded portion 332 descends, the crushing blade 333 rotates in the same direction as the counterclockwise direction, and the compression plate member 334 ) Is lowered accordingly.

Accordingly, the compression plate member 334 can be moved up and down using the drive motor 335, and the crushing blade 333 can be continuously rotated with the rotation direction varied.

Here, the lower end of the compression plate member 334 is a closed space, and the air 20 and the molasses mixture 10 can not be introduced. The edge portion of the compression plate member 334 is made of a rubber material O-rings.

The molten mixture 10 can be made into fine particles by the rotation of the pulverizing blade 333 and the precipitate of the molasses mixture 10 can be formed by the upward and downward movement of the compression plate member 334, There is an effect that the phenomenon of the occurrence of this problem can be prevented.

When the molasses mixture 10 in the case 330a is made into fine particles, the compression plate member 334 is lifted so that the air 20 is compressed as shown in FIG.

In this state, when the nutrient side valve 342 is opened or closed, the molten mixture 10 in the case 330a is pushed into the nutrient side drain pipe 341 by the expansion force of the air 20 to expand, So that it can flow quickly into the water tank 340.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the following claims And can be changed. However, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

According to one aspect of the present invention, the molasses used as food for microorganisms is superfine, so that the microbes have a drastically increased specific surface area for food, so that the microbial culture speed is increased and the molasses mixture maintained at the proper temperature is supplied Thereby increasing the growth rate of the microorganism and thereby increasing the efficiency of the incubator.

100: Mass microorganism incubator
110:
120: molasses mixing tank
130: atomizing machine
140: Nutrition tank
150: culture tank
260:

Claims (4)

A seed bacterium in which a seed bacterium to be cultured is prepared;
A molasses mixing tank in which a molasses mixture used for culturing the seeds can be prepared;
An atomizing device capable of making the molasses mixture produced in the molasses mixing tank into a fine particle;
A nutritive water tank in which the molasses mixture finely atomized in the fine particleizing apparatus is stored before being introduced into a culture tank; And
And a device moving member to which the atomizing device can be moved,
Wherein the apparatus for fine granulating is connected to a part of the nutritious water tank to form a device-side connecting member for allowing the molasses mixture of the fine particleizing apparatus to flow to the nutritive water tank,
A water tank side connecting member is formed in the nutritive water tank so as to be engaged with the appliance side connecting member,
Wherein the device-side connecting member and the water-tank-side connecting member are formed in a magnetic shape so that they can be automatically coupled with each other when they are close to each other. A seed bacterium in which a seed bacterium to be cultured is prepared;
A molasses mixing tank in which a molasses mixture used for culturing the seeds can be prepared;
An atomizing device capable of making the molasses mixture produced in the molasses mixing tank into a fine particle; And
And a nutritious water tank in which the molasses mixture finely atomized in the fine particleizing apparatus is stored before being introduced into the culture tank,
The micropartizing machine
A drive motor,
A case in which the molasses mixture can be made into fine particles,
An engaging body connected to the driving motor and rotated by driving of the driving motor,
A central shaft member having a lower end portion inserted into the engaging body and formed at a lower end thereof with a protrusion protruding from the engaging body,
A threaded portion formed at a predetermined length in the upper end of the central shaft member and having a threaded portion having a rotating direction,
A crushing blade connected to the central shaft member and rotated as the central shaft member rotates to collide with the particles of the molasses mixture to make the molasses mixture into fine particles;
A threaded upper fixing part which rotatably holds the upper part of the threaded part and which is formed on the inner surface of the threaded part to engage with the threaded part of the threaded part,
And a compression plate member disposed at a lower portion of the case, the compression plate member being connected to the central shaft member and compressing the air in the micropartizing device as the thread portion is raised and lowered,
The latching body is formed with a latching groove, which is formed on the latching body and has a length corresponding to the height of the compression plate and is movable to a predetermined length so that the latching protrusion can be moved. And,
When the drive motor is driven, the latching body is rotated so that the latching groove pushes the latching projection in the direction of rotation to rotate the latching protrusion. As the latching projection rotates, the central shaft member rotates, Wherein the threaded portion formed on the upper end of the shaft member is raised or lowered along the threaded upper fixing portion, and the compression plate member is moved up or down according to the upward or downward movement of the threaded portion. 3. The method of claim 2,
O-rings of rubber material are formed at edge portions of the compression plate member,
Wherein the lower end of the compression plate member is formed as a closed space so that the molasses mixture at the upper end of the compression plate member can not flow into the lower end of the compression plate member. 3. The method of claim 2,
The molasses mixture in the case flows into the nutritive water tank by the expansion force of the compressed air so that the compression plate member is lifted so that the air is compressed when the molasses mixture in the case is made into fine particles, Lt; RTI ID = 0.0 > microorganism < / RTI >

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