KR101309637B1 - Continuous fermentation device useful microbes - Google Patents

Abstract

The present invention relates to a continuous microbial useful fermentation apparatus, through the fermentation contact tank, fermentation culture tank and fermentation ripening tank to easily and continuously ferment the useful microorganisms in order to obtain a more stable fermentation by-products and thereby the fermentation by-products Not only can the product be expected to be homogenized and mass-produced, but in particular, the high temperature heat emitted by one heater can be more easily transferred to the fermentation contact tank, the fermentation culture tank and the fermentation aging tank through the first and second compartment plates. Therefore, there is an effect that the useful microorganism can be continuously fermented at a higher efficiency by using only one heater that emits high temperature heat.

Description

Useful Microorganism Continuous Fermentation Device {CONTINUOUS FERMENTATION DEVICE USEFUL MICROBES}

The present invention not only obtains more stable fermentation by-products by continuously fermenting useful microorganisms sequentially and more easily through fermentation contacting tanks, fermentation culture tanks, and fermentation aging tanks, and thus, it is possible to expect homogenization and mass production of the fermentation by-product products. Of course, in particular, since the high-temperature heat emitted by one heater can be more easily transferred to the fermentation contact tank, the fermentation culture tank and the fermentation ripening tank through the first and second compartment plates 1 The present invention relates to a useful microorganism continuous fermentation apparatus capable of continuously fermenting a useful microorganism with higher efficiency.

In general, useful microorganisms (EM) is a combination of and cultured dozens of microorganisms beneficial to humans among many microorganisms in nature.

Yeasts, lactic acid bacteria and photosynthetic bacteria are the main species that make up useful microorganisms, and the antioxidant power of fermentation products produced by the complex coexistence coexistence between these bacteria can be said to be the effect of useful microorganisms.

The present inventors can not only obtain a more stable fermentation by-products by successively fermenting useful microorganisms sequentially and sequentially through fermentation contacting tanks, fermentation culture tanks, and fermentation aging tanks. Of course, in particular, since the high temperature heat emitted by one heater can be more easily transmitted through the first and second compartment plates than the fermentation contact tank, the fermentation culture tank and the fermentation ripening tank 1 The present invention proposes a useful microbial continuous fermentation apparatus capable of continuously fermenting a useful microorganism with higher efficiency.

The present invention not only obtains more stable fermentation by-products by continuously fermenting useful microorganisms sequentially and more easily through fermentation contacting tanks, fermentation culture tanks, and fermentation aging tanks, and thus, it is possible to expect homogenization and mass production of the fermentation by-product products. Of course, in particular, since the high-temperature heat emitted by one heater can be more easily transferred to the fermentation contact tank, the fermentation culture tank and the fermentation ripening tank through the first and second compartment plates 1 It is an object of the present invention to provide a useful microbial continuous fermentation apparatus capable of continuously fermenting a useful microorganism with higher efficiency using only the above heaters.

The present invention for achieving the above object is a housing, a first partition plate which is provided in the vertical direction in the front and rear direction between the front inner peripheral surface of the housing and the rear inner peripheral surface of the housing and a rearward upper portion is formed, and the A second partition plate provided vertically in a horizontal direction between the other outer peripheral surface of the first partition plate and the other inner peripheral surface of the housing and having a second moving hole formed thereon; and an interior of the housing to be located in one side direction of the first partition plate; A fermentation contacting tank formed on one side, a fermentation culture tank formed on the other inner side of the housing so as to be located in the rearward direction of the second compartment plate, and formed on the other inner side of the housing so as to be located in the front side direction of the second compartment plate. A useful microorganism inlet configured to include a fermentation maturation tank, respectively, which introduces useful microorganisms and water into the fermentation contact tank into the housing; A fermentation tank having a water inlet and an outlet for discharging the useful microorganisms and water from the fermentation aging tank to the outside; A solid medium supply unit for supplying a solid medium to the fermentation contact tank of the fermentation tank; A stirring unit for stirring water, useful microorganisms, and solid medium contained in the fermentation contacting tank of the fermentation tank; A heater provided in the fermentation contacting tank of the fermenter to dissipate heat; It provides a useful microbial continuous fermentation apparatus comprising a; a useful microbial carrier provided in the fermentation contact tank of the fermentation tank.

Here, the floating passage for preventing the float floating in the water contained in the housing passing through the first moving port of the first partition plate, the second moving port of the second partition plate and the outlet of the housing, respectively. It is preferable that a prevention part is provided.

In particular, the floating passage preventing portion is formed of a tube member extending a predetermined length in the vertical direction, the lower side is opened, the upper side of the tube member in the state of covering the first moving port, the second moving port and the discharge port respectively the first It is preferable to be fixed to an outer circumferential surface of the rear upper portion of the partition plate, an upper side of the rear surface of the second partition plate, and the front side of the other inner circumferential surface of the housing.

Furthermore, an inclined plate is formed on the upper side of the pipe member to cover the first moving hole, the second moving hole and the discharge port, and the inclined plate has an upper portion of the first moving hole, the second moving hole and the discharge port from the lower end toward the upper end. It is preferable to tilt upward in the direction.

In addition, the solid medium supply unit and the hopper provided in the upper direction of the housing and the solid medium is accommodated therein; An upper driving member provided at an upper portion of the hopper; A rotating shaft vertically provided in the hopper in an axially coupled state with the upper driving member; Rotating blades provided at equal intervals on the lower end of the rotating shaft; A supply pipe provided under the hopper so as to communicate with the hopper and supplying a solid medium into the fermentation contacting tank; A transfer screw provided in the supply pipe; It is preferably made of; a lower drive member provided on the other side of the supply pipe in the state coupled to the transfer screw.

In addition, the stirring portion and the drive member provided on the upper portion of the housing; A rotating shaft vertically provided in the fermentation contacting tank in axially coupled state with the drive member; It is preferably made of; rotary blades provided at equal intervals in the lower end of the rotating shaft.

A timer for setting an inflow period of water flowing into the water inlet of the housing; It is preferable that a temperature sensor for sensing the temperature in the housing;

The present invention not only obtains more stable fermentation by-products by continuously fermenting useful microorganisms sequentially and more easily through fermentation contacting tanks, fermentation culture tanks, and fermentation aging tanks, and thus, it is possible to expect homogenization and mass production of the fermentation by-product products. Of course, in particular, since the high-temperature heat emitted by one heater can be more easily transferred to the fermentation contact tank, the fermentation culture tank and the fermentation ripening tank through the first and second compartment plates 1 Using only the above heaters has the effect of continuously fermenting useful microorganisms at higher efficiency.

1 is a perspective view schematically showing a useful microbial continuous fermentation apparatus of an embodiment of the present invention,
Fig. 2 is a sectional view taken along the line A-A in Fig. 1,
3 is a cross-sectional view taken along the line B-B of FIG.
4 is a cross-sectional view taken along the line C-C of FIG.
5 is a cross-sectional view taken along the line D-D of FIG.
6 is a cross-sectional view taken along the line E-E of FIG.
7 is a schematic cross-sectional view of the solid medium supply unit of FIG. 1.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 is a perspective view schematically showing a useful microbial continuous fermentation apparatus of an embodiment of the present invention, Figure 2 is a cross-sectional view taken along the line A-A of Figure 1, Figure 3 is a cross-sectional view taken along the line B-B of Figure 1 .

As shown in Figures 1 to 3, the useful microbial continuous fermentation device of the present invention is large, fermentation tank 10, solid medium supply unit 20, stirring unit 30, the heater 40 and the useful microbial carrier It consists of 50.

First, the fermentation tank 10 is a housing 100, the first compartment plate 110, the second compartment plate 120, the fermentation contact tank 130, the fermentation culture tank 140 and the fermentation ripening tank 150 It is configured to include.

Legs 101 for supporting the housing 100 at a predetermined height from the ground may be integrally vertically provided at each corner of the lower surface of the housing 100.

As shown in FIG. 2, the first partition plate 110 is integrally vertically integrated in the front-rear direction between the front inner circumferential surface of the housing 100 and the rear inner circumferential surface of the housing 100.

A first moving hole 111 is formed on the rear side of the first partition plate 110 to extend a predetermined length in the front-rear direction.

The second compartment plate 120 is integrally vertically provided in a horizontal direction between the center of the other outer peripheral surface of the first compartment plate 110 and the center of the other inner peripheral surface of the housing 100.

A second moving hole 121 extending at a predetermined length in left and right directions is formed at an upper center portion of the second partition plate 120.

The fermentation contact tank 130 is formed on one side of the housing 100 to be located in one side direction of the first compartment plate 110 as shown in FIG.

The fermentation culture tank 140 is formed on the other inside of the housing 100 to be located in the rear side direction of the second compartment plate 120 as shown in FIG.

The fermentation aging tank 150 is formed on the other inner side of the housing 100 to be located in the front side direction of the second compartment plate 120 as shown in FIG.

The housing 100 has a useful microorganism inlet 160, a water inlet 170, and an outlet 180.

The useful microorganism inlet 160 may be formed on one side of the rear side of the housing 100.

The useful microorganism inlet 160 is fixed to the front end is hermetically connected to the useful microorganism inlet 160, the rear end of the useful microorganism supply pipe 161 is securely connected to the known microorganism supply (not shown) stored useful microorganisms It may be connected to the microorganism supply unit (not shown).

The useful microorganisms stored in the microorganism supply unit (not shown) may be introduced into the fermentation contact tank 130 through the useful microorganism supply pipe 161 and the useful microorganism inlet port 160.

The water inlet 170 may be formed on one side of the rear side of the housing 100 so as to be located in the lower direction of the useful microorganism inlet 160.

The water inlet 170 is fixed to the front end is hermetically connected to the water inlet 170, the rear end of the water supply (not shown) through a water supply pipe 171 is fixedly connected to the water supply (not shown) It can be connected with.

As the water supply unit (not shown), general water and sewage may be used.

The water supplied by the water supply unit (not shown) may be introduced into the fermentation contact tank 130 through the water supply pipe 171 and the water inlet 170.

The outlet 180 is formed at the front upper side of the other side of the housing 100.

The outlet 180 discharges the useful microorganisms and water in the fermentation aging tank 150 to the outside of the housing 100.

One end portion of the discharge pipe 181 for guiding and discharging useful microorganisms and water to the discharge port 180 may be securely connected.

An opening plate 190 may be provided at an upper portion of the housing 100 as shown in FIG. 1.

The opening and closing plate 190 may be composed of one opening and closing plate 191 and the other opening and closing plate 192.

The one side opening and closing plate 191 may open and close the inside of the fermentation contact tank 130 by moving the rear end in the vertical direction by the user in a state in which the front end is hinged to the rear side of one side of the upper surface of the housing 100. have.

The other side opening and closing plate 192 may include a first other side opening and closing plate 192a and a second other side opening and closing plate 192b.

The first other opening and closing plate 192a opens and closes the inside of the fermentation aging tank 150 by rotating the rear end in the vertical direction by the user in a state where the front end is hinged to the front side of the other upper surface of the housing 100. can do.

The second other opening and closing plate 192b is positioned at the rear of the first other opening and closing plate 192a so that the rear end is hinged to the rear side of the other upper surface of the housing 100 in a vertical direction by the user. It can rotate to open and close the inside of the fermentation culture tank 140.

Next, the solid medium supply unit 20 may be provided on the front side of one side upper surface of the housing 100 to be located in front of the one opening and closing plate 191.

The solid medium supply unit 20 is to supply a solid medium which is a nutrient source for the growth of useful microorganisms into the fermentation contact tank 130.

Next, the stirring unit 30 is provided in the middle of one side upper surface of the housing 100 to be located between the solid medium supply unit 20 and the one side opening and closing plate 191 as shown in FIGS. Can be.

The stirring unit 30 is to stir the water, useful microorganisms and solid medium contained in the fermentation contact tank 130.

Next, the heater 40 may be horizontally provided on the front inner circumferential surface of the housing 100 so as to be provided in the fermentation contacting tank 130 as shown in FIG.

The water, useful microorganisms, and solid medium contained in the fermentation contact tank 130 may be heated by the high temperature heat emitted by the heater 40.

The first compartment plate 110 so that the high temperature heat emitted by the heater can be more easily transmitted to the fermentation culture tank 140 and the fermentation aging tank 150 as well as the fermentation contact tank 130. ) And the second compartment plate 120 is preferably made of a metal material with excellent thermal conductivity.

Next, the useful microbial carrier 50 may be vertically provided on the rear inner circumferential surface of the housing 100 to be provided in the fermentation contact tank 130 as shown in FIG. 3.

The useful microorganism carrier 50, which is a porous molded article, is a structure manufactured to attach and grow the useful microorganism, which is a well-known technique and is a matter that can be clearly understood by those skilled in the art to which the present invention pertains. Detailed description will be omitted below.

4 is a cross-sectional view taken along the line C-C of FIG. 2, FIG. 5 is a cross-sectional view taken along the line D-D of FIG. 2, and FIG. 6 is a cross-sectional view taken along the line E-E of FIG.

Next, as shown in Figures 3 to 6 may be provided with a float prevention portion 70.

The floating passage preventing portion 70 is a float 60 including a part of the solid medium suspended in the water contained in the housing 100, the first movement hole 111 of the first compartment plate 110. ), Passing through the second moving port 121 of the second partition plate 120 and the discharge port 180 of the housing 100, respectively.

More specifically, the floating passage preventing portion 70 may be made of a pipe member 710.

The pipe member 710 may extend a predetermined length in the vertical direction, the lower side may be opened.

The upper side of the pipe member 710 to cover the first moving port 111, the second moving port 121 and the outlet 180,

The upper side of the pipe member 710 may be welded to the outer peripheral surface of the rear upper part of the first compartment plate 110, the upper side of the rear surface of the second compartment plate 120, and the other inner peripheral surface of the housing 100. Can be fixed in a manner.

An inclined plate 720 may be formed on an upper side of the pipe member 710.

The upper end of the inclined plate 720, the outer peripheral surface of the rear upper portion of the first partition plate 110 to be located in the upper direction of the first moving port 111, the second moving port 121 and the discharge port 180. And, it is fixed to the upper rear side of the second partition plate 120 and the front side of the other inner peripheral surface of the housing 100, respectively, to cover the first moving port 111, the second moving port 121 and the discharge port 180. Can be.

The inclined plate 720 may be inclined upward in the upper direction of the first moving hole 111, the second moving hole 121, and the discharge hole 180 from the lower end toward the upper end.

Through the inclined plate 720, the first moving port 111, the second moving port 121 and the discharge port 180 can be more easily covered, as well as water introduced into the inside of the pipe member 710; Useful microorganisms can be more easily moved in the direction of the first port (111), the second port (121) and the discharge port 180 (see the solid arrows of Figures 4, 5, 6). .

FIG. 7 is a schematic cross-sectional view of the solid medium supply unit 20 of FIG. 1.

Next, to allow the solid medium supply unit 20 to more easily supply the solid medium into the fermentation contact tank 130,

The solid medium supply unit 20 is large, as shown in Figure 7, the hopper 210, the upper drive member 220, the rotating shaft 230, the rotary blade 240, the supply pipe 250, the transfer screw 260 and The lower driving member 270 may be formed.

The hopper 210 may be provided in an upper direction of the housing 100.

The hopper 211 may be composed of a storage tank 211 and the opening and closing plate 212.

The storage tank 211 may be provided in an upper direction of the housing 100.

A solid medium may be accommodated in the storage tank 211.

The opening and closing plate 212 may be bolted to be detachably horizontally on top of the hopper 211.

The upper driving member 220, which may be made of a driving motor, may be vertically provided at the center of the upper surface of the opening and closing plate 212 of the hopper 210.

The rotary shaft 230 may be vertically provided at the inner center of the storage tank 211 of the hopper 210 while the upper side of the rotary shaft 230 is axially coupled with the upper driving member 220.

The rotary blade 240 may be horizontally provided at equal intervals on the outer peripheral surface of the lower end of the rotary shaft 230 to be orthogonal to the rotary shaft 230.

The supply pipe 250 may supply a solid medium into the fermentation contact tank 130.

The supply pipe 250 may be composed of a horizontal supply pipe 251 and a vertical supply pipe 252.

The horizontal supply pipe 251 may be provided below the storage tank 211 of the hopper 210.

The other upper portion of the horizontal supply pipe 251 may be in communication with the storage tank 211 of the hopper 210.

An upper side of the vertical supply pipe 252 may be hermetically connected to a lower side of one side of the horizontal supply pipe 251 so that the vertical supply pipe 252 communicates with the horizontal supply pipe 251.

The lower side of the vertical supply pipe 252 may be hermetically connected to the front side of one side upper surface of the housing 100 to communicate with the fermentation contact tank 130.

The transfer screw 260 may be horizontally provided in the horizontal supply pipe 251 of the supply pipe 250.

The lower driving member 270, which may be made of a driving motor, may be horizontally provided on the other side of the horizontal supply pipe 251 of the supply pipe 250 in a state in which the lower driving member 270 is axially coupled with the other side of the transfer screw 260.

The inside of the storage tank 211 of the hopper 210 by the rotary blade 240 is rotated forward and backward along the rotation shaft 230 when the rotary shaft 230 is forward and backward rotation by the upper drive member 220 The solid medium stored in it may be smoothly discharged into the horizontal supply pipe 251 of the supply pipe 250 while being stirred.

As the transfer screw 260 rotates forward and backward by the lower driving member 270, the stirred solid medium discharged into the horizontal supply pipe 251 moves to the vertical supply pipe 252 to the fermentation contact tank 130. Can be fed into.

Next, in order to more easily agitate the water, useful microorganisms and solid medium contained in the fermentation contact tank 130,

As shown in FIG. 3, the stirring unit 30 may be formed of a driving member 310, a rotation shaft 320, and a rotation wing 330.

The driving member 310, which may be made of a driving motor, may be vertically provided at the middle of one upper surface of the housing 100.

The rotary shaft 320 may be vertically provided in the fermentation contact tank 130 while the upper side of the rotary shaft 320 is axially coupled with the driving member 310.

The rotary blade 330 may be horizontally provided at equal intervals at the lower end of the rotary shaft 320 in a state orthogonal to the rotary shaft 320.

When the rotary shaft 320 is reversely rotated by the drive member 310, the rotary blade 330 is reversely rotated along the rotary shaft 320 to receive water, useful microorganisms and solids contained in the fermentation contact tank 130 The medium is stirred.

Next, the timer 80, the temperature sensor 90 and the control unit 200 may be further provided.

The timer 80 may be provided to the controller 200 in various ways such as a push button or a dial button.

The user may set an inflow period of water flowing into the water inlet 170 of the housing 100 through the timer 80.

The temperature sensor 90 may be provided on the front inner circumferential surface of the housing 100 so that the temperature sensor 90 may be provided inside the fermentation contact tank 130 to sense the temperature in the housing 100.

The control unit 200 may be vertically provided on one side of the front surface of the housing 100.

More specifically, although not shown in the drawing, the water supply pipe 171 connected to the water inlet 170, the opening and closing including the solenoid valve for opening and closing the water supply pipe 171 under the control of the controller 200. Member may be provided.

In addition, the inflow period of water which may be set in the timer 80 may be an inflow time of water or an inflow time interval of water.

When the inflow period of the water set in the timer 80 is the inflow time of the water, the inflow time of the water is 1 pm, 3 pm, 4 pm, 7 pm,

The controller 200 controls the opening / closing member to open the water supply pipe 171 every 1 pm, 3 pm, 4 pm, and 7 pm to allow water to flow into the fermentation contacting tank 130. do.

When the inflow period of water set in the timer 80 is the inflow time interval of water, the inflow time interval of water is 30 minutes,

The control unit 200 controls the opening and closing member to open the water supply pipe 171 at intervals of 30 minutes to allow water to flow into the fermentation contact tank 130.

In the fermentation contacting tank 130, the water and the useful microorganisms and the solid medium are first contacted with each other and can be firstly heated by the heater 40.

Water and useful microorganisms and solid medium heated by the heater 40 in contact with each other in the fermentation contact tank 130 for the first time gradually rise to the fermentation culture tank 140 through the first port 111. Will move.

The water, the useful microorganisms and the solid medium moved into the fermentation culture tank 140 receive high-temperature heat from the heater 40 through the first and second compartment plates 110 and 120 to be secondly heated and cultured. Can be.

Water and useful microorganisms and solid medium cultured in the fermentation culture tank 140 gradually rises and moves into the fermentation aging tank 150 through the second moving port 121.

The water and the useful microorganisms and the solid medium moved into the fermentation aging tank 150 receives the high temperature heat from the heater 40 through the first and second compartment plates 110 and 120 to be heated and aged three times. Can be.

Fermentation by-product consisting of water and useful microorganisms and solid medium aged in the fermentation aging tank 150 can be discharged to the outside of the housing 100 through the outlet 180.

As described above, water and useful microorganisms and solid mediums are more easily moved to the fermentation contact tank 130, the fermentation culture tank 140, and the fermentation ripening tank 150 without the need for a separate pump and discharged to the outside. You can do it.

The controller 200 may control the heater 40 by comparing a temperature value in the housing 100 sensed by the temperature sensor 90 with a reference temperature value preset in the controller 200. .

When the temperature value in the housing 100 sensed by the temperature sensor 90 is less than the reference temperature value preset in the controller 200, the heater 40 controls the high temperature heat under the control of the controller 200. Will diverge.

When the temperature value in the housing 100 sensed by the temperature sensor 90 is equal to or greater than the reference temperature value preset in the control unit 200, the heater 40 is stopped by the control of the control unit 200 to be operated at a high temperature. Can not dissipate the heat.

The present invention configured as described above is able to obtain a more stable fermentation by-products by successively fermenting useful microorganisms sequentially through the fermentation contacting tank 130, the fermentation culture tank 140, and the fermentation ripening tank 150. As a result, the fermentation by-product product can be expected to be homogenized and mass-produced, and in particular, high temperature heat emitted from one heater 40 is transmitted through the first and second compartment plates 110 and 120. Since it can be more easily transferred to the fermentation contact tank 130, fermentation culture tank 140 and fermentation aging tank 150, using only one of the heaters 40 to dissipate high temperature heat more useful microorganisms There is an advantage that can be continuously fermented with high efficiency.

10; Fermenter, 20; Solid medium supply unit,
30; Agitator 40; heater,
50; Useful microbial carriers.

Claims (7)

The first partition plate 110 is vertically arranged in the front-rear direction between the housing 100, the front inner circumferential surface of the housing 100, and the rear inner circumferential surface of the housing 100, and the first moving hole 111 is formed on the rear upper part. And a second partition plate 120 which is vertically provided in a horizontal direction between the other outer peripheral surface of the first partition plate 110 and the other inner peripheral surface of the housing 100 and has a second moving hole 121 formed thereon. The fermentation contact tank 130 is formed on one side of the housing 100 to be located in one side direction of the first compartment plate 110, and the housing is located in a rear side direction of the second compartment plate 120. Fermentation culture tank 140 formed on the other inner side of the (100), and fermentation aging tank 150 formed on the other inner side of the housing 100 to be located in the front side direction of the second compartment plate 120. The microorganism and water are introduced into the fermentation contact tank 130 into the housing 100, respectively. Key and beneficial microorganisms inlet 160 and the water inlet 170 and the fermentation tank 150, the outlet 180, the fermenter 10, which is formed of a beneficial microorganism and the water inside the discharge to the outside;
A solid medium supply unit 20 for supplying a solid medium to the fermentation contacting tank 130 of the fermentation tank 10;
A stirring unit 30 for stirring water, useful microorganisms, and a solid medium contained in the fermentation contacting tank 130 of the fermentation tank 10;
A heater 40 provided in the fermentation contacting tank 130 of the fermentation tank 10 for dissipating heat;
Useful microorganisms continuous fermentation apparatus comprising a; microorganism carrier (50) provided in the fermentation contact tank 130 of the fermentation tank (10).
The method of claim 1,
Floating material 60 floating in the water accommodated in the housing 100 is the first moving port 111 of the first partition plate 110, the second moving hole 121 of the second partition plate 120. And useful microbial continuous fermentation apparatus, characterized in that the floating passage preventing portion 70 for preventing passing through the outlet 180 of the housing 100, respectively.
The method of claim 2,
The floating passage preventing portion 70 is made of a pipe member 710 extending a predetermined length in the vertical direction and the lower side is opened,
The upper side of the pipe member 710 is the outer peripheral surface of the upper side of the rear upper portion of the first partition plate 110 in the state of covering the first moving port 111, the second moving port 121 and the discharge port 180, respectively, Useful microbial continuous fermentation apparatus, characterized in that fixed to the upper side of the rear of the second compartment plate 120 and the other side of the inner peripheral surface of the housing (100).
The method of claim 3, wherein
An inclined plate 720 covering the first moving hole 111, the second moving hole 121, and the discharge hole 180 is formed on the upper side of the pipe member 710,
The inclined plate 720 is useful microbial continuous fermentation apparatus, characterized in that the inclined upward in the upper direction of the first moving port 111, the second moving port 121 and the discharge port 180 toward the upper end direction.
The method of claim 1,
The solid medium supply unit 20 is provided in the upper direction of the housing 100 and the hopper 210 is a solid medium is accommodated therein;
An upper driving member 220 provided on an upper portion of the hopper 210;
A rotating shaft 230 which is vertically provided inside the hopper 210 in a state of being axially coupled with the upper driving member 220;
Rotating blades 240 provided at equal intervals on the lower end of the rotary shaft 230;
A supply pipe 250 provided below the hopper 210 to communicate with the hopper 210 and supplying a solid medium into the fermentation contacting tank 130;
A transfer screw 260 provided in the supply pipe 250;
A useful microbial continuous fermentation device, comprising: a lower drive member (270) provided on the other side of the supply pipe (250) in a state in which the transfer screw (260) is axially coupled.
The method of claim 1,
The stirring unit 30 and the drive member 310 provided on the upper portion of the housing 100;
A rotary shaft 320 which is vertically provided in the fermentation contact tank 130 in a state in which the driving member 310 is axially coupled;
Useful microbial continuous fermentation device, characterized in that consisting of; rotating blades 330 provided at equal intervals on the lower end of the rotating shaft (320).
The method of claim 1,
A timer (80) for setting an inflow period of water flowing into the water inlet (170) of the housing (100);
Useful microorganisms continuous fermentation apparatus, characterized in that provided; temperature sensor (90) for sensing the temperature in the housing (100).

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