CN211339455U - Fermenting installation of bacillus subtilis microbial preparation - Google Patents
Fermenting installation of bacillus subtilis microbial preparation Download PDFInfo
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- CN211339455U CN211339455U CN201921851888.4U CN201921851888U CN211339455U CN 211339455 U CN211339455 U CN 211339455U CN 201921851888 U CN201921851888 U CN 201921851888U CN 211339455 U CN211339455 U CN 211339455U
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Abstract
The utility model provides a fermentation device of bacillus subtilis microbial preparation, which comprises a main fermentation chamber, a material cracking chamber, a material saccharification chamber, a strain culture chamber, a bacteria liquid separation chamber, a nutrient solution allocation chamber, an oxygen supply device, a spray drying chamber and an intelligent digital control device; the utility model discloses a material saccharification, nutrient solution preparation, fungus liquid separator, oxygen supply apparatus intercommunication, main fermentation room and spray drying room pipeline intercommunication, be provided with terahertz generator, first braking baffle and first humidification device in the material cracking room, the material cracking room with material saccharification room intercommunication, be provided with color sensor, third ultraviolet sterilizing equipment and second braking baffle in the fungus culture room, the fungus culture room with fungus liquid separator intercommunication, main fermentation room and material saccharification, nutrient solution allotment room, fungus liquid separator the oxygen supply apparatus intercommunication, main fermentation room and spray drying room pipeline intercommunication. The fermentation device of the bacillus subtilis microbial preparation has the advantages of simple structure, intuitive operation, lower cost, environmental protection, energy conservation, industrial production and strong practicability.
Description
Technical Field
The utility model relates to a microbial fermentation equipment technical field, concretely relates to fermenting installation of bacillus subtilis microbial preparation.
Background
The bacillus subtilis microbial preparation is a biological environment-friendly product with great development prospect and application value. At present, the research on bacillus subtilis in China mainly focuses on the aspects of screening, separation and identification, bacteriostasis effect and culture medium chemical composition optimization analysis of strains, the existing fermentation equipment cannot completely meet the fermentation requirement of the bacillus subtilis, the aseptic and automatic conditions are low, a large amount of manpower and material resources are needed in the fermentation production process, and the problems of long fermentation period, low viable count and easy infectious microbe infection commonly exist in the bacillus subtilis fermentation production process due to the complex raw material components.
SUMMERY OF THE UTILITY MODEL
The utility model aims to overcome the defects in the prior art and provide a fermentation device for a bacillus subtilis microbial preparation.
In order to achieve the above purpose, the utility model adopts the following technical scheme: a fermentation device for a bacillus subtilis microbial preparation comprises a main fermentation chamber, a material cracking chamber, a material saccharification chamber, a strain culture chamber, a bacteria liquid separation chamber, a nutrient solution preparation chamber, an oxygen supply device, a spray drying chamber and an intelligent digital control device;
the device comprises a material cracking chamber, a material saccharification chamber, a first brake baffle and a first humidifying device, wherein the material cracking chamber is communicated with the material saccharification chamber, the first brake baffle is used for opening or closing a channel between the material cracking chamber and the material saccharification chamber, and the first brake baffle is driven by a brake controller to open or close the channel between the material cracking chamber and the material saccharification chamber;
a first nanometer far infrared heating plate is arranged on the periphery of the outer wall of the material saccharification chamber, and a first temperature sensor, a humidity sensor, a second humidifying device and a first stirring device are arranged in the material saccharification chamber;
the strain culture chamber is communicated with the bacteria liquid separation chamber, the second movable baffle is used for opening or closing a channel between the strain culture chamber and the bacteria liquid separation chamber, the second brake baffle is driven by the brake controller to open or close the channel between the strain culture chamber and the bacteria liquid separation chamber, a titanium dioxide flat plate is fixed on the upper surface of the second brake baffle, and a culture medium layer is fixed on the upper surface of the titanium dioxide flat plate;
the bacteria liquid separation chamber is provided with a microporous filter plate and a leaching head, the leaching head is communicated with a water supply tank through a pipeline, leaching drivers are arranged on the leaching head and the water supply tank, the leaching head is arranged above the microporous filter plate, the bacteria liquid separation chamber is provided with a discharge port, and the discharge port is arranged below the microporous filter plate;
a second stirring device is arranged in the nutrient solution blending chamber;
a second ultraviolet sterilization device is arranged on an air outlet pipeline of the oxygen supply device;
the outer wall of the main fermentation chamber is provided with a second nano far infrared heating plate, a first ultraviolet sterilization device, a dissolved oxygen monitor and a second temperature sensor are arranged in the main fermentation chamber, the top of the main fermentation chamber is provided with a feed inlet and an oxygen supply inlet, the feed inlet at the top of the main fermentation chamber is communicated with a discharge port pipeline of the material saccharification chamber, the feed inlet at the top of the main fermentation chamber is communicated with a discharge port pipeline of the nutrient solution blending chamber, the feed inlet at the top of the main fermentation chamber is communicated with a discharge port pipeline of the bacteria liquid separation chamber, the oxygen supply inlet at the top of the main fermentation chamber is communicated with an air outlet pipeline of the oxygen supply device, the bottom of the main fermentation chamber is provided with a discharge port, and the discharge port of the main fermentation chamber is communicated with;
the intelligent digital control device is electrically connected with the first nanometer far infrared heating plate and controls the start and the close of the first nanometer far infrared heating plate, the intelligent digital control device is electrically connected with the second nanometer far infrared heating plate and controls the start and the close of the second nanometer far infrared heating plate, the intelligent digital control device is electrically connected with the first temperature sensor, the intelligent digital control device is electrically connected with the second temperature sensor, the intelligent digital control device is electrically connected with the oxygen supply device and controls the start and the close of the oxygen supply device, the intelligent digital control device is electrically connected with the dissolved oxygen monitor, the intelligent digital control device is electrically connected with the humidity sensor, the intelligent digital control device is electrically connected with the terahertz generator, the intelligent digital control device is electrically connected with the color sensor, the intelligent digital control device is electrically connected with the leaching driver, the intelligent digital control device is electrically connected with the brake controller, the intelligent digital control device is electrically connected with the first humidifying device, the intelligent digital control device is electrically connected with the second humidifying device, the intelligent digital control device is electrically connected with the first stirring device, the intelligent digital control device is electrically connected with the second stirring device, the intelligent digital control device is electrically connected with the first ultraviolet sterilizing device, the intelligent digital control device is electrically connected with the second ultraviolet sterilizing device, and the intelligent digital control device is electrically connected with the third ultraviolet sterilizing device.
The operation process of the fermentation device for the bacillus subtilis microbial preparation comprises the following steps: in a material cracking chamber, a terahertz generator emits 0.1-10 THz electromagnetic radiation, so that the electromagnetic radiation generates same-frequency resonance with the self inherent vibration frequency of material molecular groups with the same frequency band, carbon-hydrogen bonds and hydrogen bonds among macromolecules of materials with different properties can be cracked, long chains are opened into short chains, the materials are humidified by a first humidifying device during cracking, the cracked materials are conveyed into a material saccharifying chamber through a braking baffle, and the braking baffle can be washed by the first humidifying device; after the material treated in the material cracking chamber enters the material saccharification chamber, the material is heated and saccharified by using a first nano far infrared heating plate, and a first stirring device keeps stirring to ensure the uniformity of saccharification; the bacillus subtilis is cultured on a culture medium layer of a strain culture chamber, when an indicator lamp of a color sensor lights or sends a signal in other modes to indicate that the strain culture is successful, the color sensor is closed, a third ultraviolet sterilization device enables a fixed-waveband ultraviolet lamp fixed on an electric push rod to move in parallel to the upper side of a bacterial colony for sterilization treatment, the ultraviolet rays in the waveband can kill staphylococcus aureus, candida albicans, escherichia coli and other bacteria which are frequently generated in the culture process while the bacillus subtilis strain is not influenced, the ultraviolet lamp is closed after the sterilization is finished, a second braking baffle is opened to enable the cultured strain culture to be transferred to a microporous filter plate in a bacteria liquid separation chamber, a strain driver rinses the strain culture, impurities are intercepted on the microporous filter plate, and the bacillus subtilis colony passes through the microporous filter plate along with water flow to complete the separation of bacteria liquid, and (3) feeding the separated bacteria liquid into a main fermentation tank for fermentation of bacillus subtilis microbial preparation, inputting the nutrient solution prepared by a nutrient solution preparation chamber into the main fermentation chamber, starting an oxygen supply device to input oxygen, starting a second nanometer far infrared heating plate controller, heating and fermenting, controlling an ultraviolet lamp controller of a second ultraviolet sterilization device to start a fixed-waveband ultraviolet lamp after biological fermentation is completed in the main fermentation chamber, killing mixed bacteria, and then feeding the microbial preparation into a spray drying chamber for spray drying.
Preferably, the intelligent digital control device comprises an intelligent digital control box and a power control box.
Preferably, the terahertz generator can emit electromagnetic radiation of 0.1THz to 10 THz.
The terahertz generator emits electromagnetic radiation of 0.1 THz-10 THz, so that the terahertz generator and the intrinsic vibration frequency of material molecular groups with the same frequency band generate same-frequency resonance, and carbon-hydrogen bonds and hydrogen bonds among macromolecules of materials with different properties can be cracked.
Preferably, the third ultraviolet sterilization device comprises ultraviolet lamps with fixed wave bands, an electric push rod and a third ultraviolet sterilization device controller, the ultraviolet lamps with the fixed wave bands are fixed on the electric push rod, and the third ultraviolet sterilization device controller controls the electric push rod to further push the ultraviolet lamps with the fixed wave bands to perform reciprocating translational motion in the strain culture chamber.
Preferably, an tourmaline layer is arranged between the outer wall of the material saccharification chamber and the first nanometer far infrared heating plate.
Preferably, the main fermentation chamber outer wall with be provided with tourmaline layer and graphite alkene heat-conducting plate between the second nanometer far infrared hot plate, tourmaline layer with the second nanometer far infrared hot plate is adjacent, graphite alkene heat-conducting plate with the main fermentation chamber outer wall is adjacent.
Tourmaline releases far infrared and a large amount of heat under the effect of second far infrared hot plate thermal power, and the rethread graphite alkene conduction board passes to the main fermentation room with the heat fast, makes the quick even rise of ambient temperature in the main fermentation room.
Preferably, the graphene heat-conducting plate is loaded with nano titanium dioxide serving as a photocatalyst.
Preferably, the material cracking chamber and the material saccharifying chamber are connected to form a tank body, the first braking baffle is horizontally arranged in the tank body to divide the tank body into the material cracking chamber and the material saccharifying chamber, the material cracking chamber is located above the first braking baffle, and the material saccharifying chamber is located below the first braking baffle.
The material cracking chamber and the material saccharification chamber form a tank body, so that the structure is simple, and the material cracking chamber is positioned above the material saccharification chamber, so that the application is more convenient.
Preferably, the strain culture chamber and the bacteria liquid separation chamber are connected to form a tank body, the second brake baffle is horizontally arranged in the tank body to divide the tank body into the strain culture chamber and the bacteria liquid separation chamber, the strain culture chamber is located above the second brake baffle, and the bacteria liquid separation chamber is located below the second brake baffle.
The strain culture chamber and the bacteria liquid separation chamber form a tank body, so that the structure is simple, and the strain culture chamber is positioned above the bacteria liquid separation chamber, so that the application is more convenient.
Preferably, a plurality of color sensors are arranged in the strain culture chamber, and the color sensors are uniformly and respectively arranged above the culture medium layer.
Be provided with a plurality of color sensor, the different colony area of color sensor response that can make, it is more accurate to the successful judgement of bacterial cultivation.
The beneficial effects of the utility model reside in that: the utility model provides a fermenting installation of bacillus subtilis microbial preparation, the utility model discloses a bacillus subtilis microbial preparation's fermenting installation has promoted the work efficiency of bacillus subtilis microbial preparation fermentation production greatly, has shortened the cycle of fermentation production, has improved the bacterial strain activity of bacillus subtilis and the live bacteria quantity of preparation simultaneously, has got rid of miscellaneous fungus's pollution, has guaranteed bacillus subtilis microbial preparation's product quality. The fermentation device of the bacillus subtilis microbial preparation has the advantages of simple structure, intuitive operation, lower cost, environmental protection, energy conservation, industrial production and strong practicability.
Drawings
FIG. 1 is a schematic structural view of a fermentation apparatus for preparing a microorganism preparation of Bacillus subtilis according to an embodiment of the present invention.
The device comprises a material cracking chamber, a material saccharification chamber, a humidity sensor, a 4 intelligent digital control box, a 5 second nanometer far infrared heating plate, a 6 graphene heat conducting plate, a 7 main fermentation chamber, a 8 dissolved oxygen monitor, a 9 spray drying chamber, a 10 electric control box, a 11 bacteria liquid separation chamber, a 12 micro-pore filter plate, a 13 shower head, a 14 strain culture chamber, a 15 national fixed band ultraviolet lamp, a 16 color sensor, a 17 third ultraviolet sterilization device controller, a 18 second stirring device, a 19 oxygen supply device, a 20 nutrient solution preparation chamber, a 21 first humidifying device, a 22 terahertz generator, a 23 first braking baffle, a 24 second braking baffle, a 25 electric stone layer, a 26, a second temperature sensor, a 27 first nanometer far infrared heating plate, a 28 and a first stirring device.
FIG. 2 is a diagram showing the effect of the fermentation apparatus for preparing the microbial preparation of Bacillus subtilis according to the embodiment of the present invention.
Detailed Description
For better illustrating the objects, technical solutions and advantages of the present invention, the present invention will be further described with reference to the following embodiments.
Example 1
As the fermentation device of the bacillus subtilis microbial preparation provided by the embodiment of the utility model, the fermentation device comprises a main fermentation chamber 7, a material cracking chamber 1, a material saccharification chamber 2, a strain culture chamber 14, a bacteria liquid separation chamber 11, a nutrient solution preparing chamber 20, an oxygen supply device 19, a spray drying chamber 9 and an intelligent digital control device;
a terahertz generator 22, a first braking baffle 23 and a first humidifying device 21 are arranged in the material cracking chamber 1, the terahertz generator 22 can emit electromagnetic radiation of 0.1 THz-10 THz, the material cracking chamber 1 is communicated with the material saccharifying chamber 2, the first braking baffle 23 is used for opening or closing a channel between the material cracking chamber and the material saccharifying chamber, the first braking baffle is driven by a braking controller to open or close the channel between the material cracking chamber and the material saccharifying chamber, a first nano far infrared heating plate 27 is arranged on the periphery of the outer wall of the material saccharifying chamber 2, a tourmaline layer is arranged between the outer wall of the material saccharifying chamber and the first nano far infrared heating plate 27, a first temperature sensor, a humidity sensor 3, a second humidifying device and a first stirring device 28 are arranged in the material saccharifying chamber, the material cracking chamber 1 and the material saccharifying chamber 2 are connected to form a tank body, the first brake baffle plate 23 is horizontally arranged in the tank body to divide the tank body into the material cracking chamber and the material saccharifying chamber, the material cracking chamber is positioned above the first brake baffle plate, and the material saccharifying chamber is positioned below the first brake baffle plate;
the strain culture chamber 14 is internally provided with a plurality of color sensors 16, a third ultraviolet sterilization device and a second brake baffle 24, the strain culture chamber 14 is communicated with the bacteria liquid separation chamber 11, the second brake baffle 24 is used for opening or closing a channel between the strain culture chamber 14 and the bacteria liquid separation chamber 11, the second brake baffle is driven by a brake controller to open or close the channel between the strain culture chamber 14 and the bacteria liquid separation chamber 11, the upper surface of the second brake baffle is fixed with a titanium dioxide flat plate, the upper surface of the titanium dioxide flat plate is fixed with a culture medium layer, the plurality of color sensors 16 are uniformly and respectively arranged above the culture medium layer, the bacteria liquid separation chamber is provided with a microporous filter plate 12 and a leaching head 13, the leaching head 13 is communicated with a water supply tank pipeline, and the leaching head and the water supply tank are provided with a leaching driver, the shower head is arranged above the microporous filter plate 12, the bacteria liquid separation chamber 12 is provided with a discharge hole, the discharge port is arranged below the microporous filter plate, the strain culture chamber 14 and the bacteria liquid separation chamber 11 are connected to form a tank body, the second brake baffle 24 is horizontally arranged in the tank body to divide the tank body into the strain culture chamber 14 and the bacteria liquid separation chamber 11, the strain culture chamber 14 is positioned above the second brake baffle 24, the bacteria liquid separation chamber 11 is positioned below the second brake baffle 24, the third ultraviolet sterilization device comprises an ultraviolet lamp 15 with a fixed waveband, an electric push rod and a third ultraviolet sterilization device controller 17, the ultraviolet lamps 15 with fixed wave bands are fixed on the electric push rod, and the controller of the third ultraviolet sterilization device 17 controls the electric push rod to further push the ultraviolet lamps 15 with fixed wave bands to perform reciprocating translational motion in the strain culture chamber 14;
a second stirring device 18 is arranged in the nutrient solution blending chamber 20;
a second ultraviolet sterilization device is arranged on an air outlet pipeline of the oxygen supply device 19;
the 7 outer walls of main fermentation chamber are provided with second nanometer far infrared heating plate 5, main fermentation chamber outer wall with be provided with tourmaline layer 25 and graphite alkene heat-conducting plate 6 between the second nanometer far infrared heating plate, the load has the nanometer titanium dioxide as the photocatalyst on the graphite alkene heat-conducting plate, tourmaline layer with the second nanometer far infrared heating plate is adjacent, graphite alkene heat-conducting plate with main fermentation chamber outer wall is adjacent, be provided with first ultraviolet sterilizing equipment, dissolved oxygen monitor 8 and second temperature sensor 26 in the main fermentation chamber, main fermentation chamber top is provided with feed inlet and oxygen suppliment air inlet, the feed inlet at main fermentation chamber top with the discharge gate pipeline intercommunication of material saccharification room, the feed inlet at main fermentation chamber top with the discharge gate pipeline intercommunication of nutrient solution allotment room, the feed inlet at main fermentation chamber top and the discharge gate pipeline intercommunication of fungus liquid separating chamber, an oxygen supply air inlet at the top of the main fermentation chamber is communicated with an air outlet pipeline of the oxygen supply device, a discharge hole is formed in the bottom of the main fermentation chamber, and the discharge hole of the main fermentation chamber is communicated with the spray drying chamber pipeline;
the intelligent digital control device comprises an intelligent digital control box 4 and an electric control box 10, the intelligent digital control device is electrically connected with the first nanometer far infrared heating plate and controls the starting and closing of the first nanometer far infrared heating plate, the intelligent digital control device is electrically connected with the second nanometer far infrared heating plate and controls the starting and closing of the second nanometer far infrared heating plate, the intelligent digital control device is electrically connected with the first temperature sensor, the intelligent digital control device is electrically connected with the second temperature sensor, the intelligent digital control device is electrically connected with the oxygen supply device and controls the starting and closing of the oxygen supply device, the intelligent digital control device is electrically connected with the dissolved oxygen monitor, the intelligent digital control device is electrically connected with the humidity sensor, the intelligent digital control device is electrically connected with the terahertz generator, the intelligent digital control device is electrically connected with the color sensor, the intelligent digital control device is electrically connected with the drip washing driver, the intelligent digital control device is electrically connected with the brake controller, the intelligent digital control device is electrically connected with the first humidifying device, the intelligent digital control device is electrically connected with the second humidifying device, the intelligent digital control device is electrically connected with the first stirring device, the intelligent digital control device is electrically connected with the second stirring device, the intelligent digital control device is electrically connected with the first ultraviolet sterilizing device, the intelligent digital control device is electrically connected with the second ultraviolet sterilizing device, and the intelligent digital control device is electrically connected with the third ultraviolet sterilizing device.
The fermenting installation of the bacillus subtilis microbial preparation of this embodiment bacillus subtilis microbial preparation the work efficiency of the production of bacillus subtilis microbial preparation fermentation is high, and the cycle of fermentation production is short, and the bacterial strain activity of bacillus subtilis and the viable count height of preparation have got rid of the pollution of mixed fungus, have guaranteed the product quality of bacillus subtilis microbial preparation.
Effect example 1
The fermentation is carried out by using the fermentation device of the bacillus subtilis microbial preparation in the embodiment 1 and the fermentation device of the traditional bacillus subtilis microbial preparation, the fermentation device of the embodiment 1 is an experimental group, the fermentation device of the traditional bacillus subtilis microbial preparation is a control group, the fermentation device of the traditional bacillus subtilis microbial preparation adopts humidification, heating, condensation, ventilation, stirring, inoculation and disinfection and sterilization processes, strains cultured by a culture tank are introduced into a main fermentation tank for inoculation, disinfection and sterilization are carried out by carrying out conventional ultraviolet lamp disinfection on a culture fermented by the main fermentation tank, and humidification, heating, condensation, ventilation and stirring are all carried out in one main fermentation tank.
1. Fermentation period
The result is shown in fig. 2, the temperature curve of the main fermentation chamber of the experimental group begins to be gentle when the fermentation is carried out to the 22 nd day, the change fluctuation of the temperature monitoring value is not large, and the fermentation is completed; when the control group is fermented for 30 days, the temperature monitoring value begins to tend to stably complete the fermentation; the temperature of the experimental group is increased quickly after the fermentation of the materials is started, and the temperature reaches the peak value of the first temperature increase when the fermentation is carried out to the 5 th day; the temperature of the control group is slowly increased after the fermentation of the materials is started, and the temperature reaches the peak value at the 10th day; the temperature of the experimental group is slowly reduced after the temperature peak value is reached for the first time, the secondary temperature rise is carried out when the fermentation is carried out to the 11 th day, and the secondary temperature rise peak value is reached when the fermentation is carried out to the 13 th day; the control group started to continuously cool after reaching the peak value of the first temperature rise, and there was no sign of the secondary fermentation, decomposition and temperature rise. The results of the binding experiments can give: the fermentation device of embodiment 1 can rapid heating up and make the material enter into high-efficient thoroughly decomposed fermentation state to can impel the material to enter the secondary heating up phase and carry out saturated fermentation, whole fermentation cycle experimental group has shortened 8 days compared with the control group, is showing the fermentation efficiency who has improved the material.
2. Quality of the product
Table 1: bacillus subtilis content (cfu/ml) in substrate under different fermentation devices
| Item | Microbial count (cfu/ml) |
| Substrate raw material | 3.20*103 |
| Control fermentation substrate | 2.81*1010 |
| Experimental group fermentation substrate | 5.37*1010 |
As can be seen from Table 1, the Bacillus subtilis preparation obtained by fermenting the same substrate material in the fermentation apparatus of example 1 has a higher bacterial count than that in the fermentation apparatus of the control group, and thus has better quality.
3. Substrate utilization
Table 2: the nutrient components in the substrate under different fermentation devices are%
| Item | Crude protein | Crude fat | Low molecular weight peptides |
| Substrate raw material | 18.11 | 12.56 | 4.61 |
| Control fermentation substrate | 21.87 | 8.25 | 7.11 |
| Experimental group fermentation substrate | 24.40 | 4.82 | 11.64 |
It can be seen from table 2 that the fermentation apparatus of example 1 has high efficiency of decomposing high molecular weight protein in the substrate by the protease produced by the microorganism during fermentation, and the fermentation apparatus of example 1 has significantly higher content of low molecular weight peptides than the conventional fermentation, and meanwhile, the decrease of the crude fat indicates that the crude fat in the material is degraded and utilized to become nutrient substances for growth of the bacteria during fermentation.
Table 3: the content of amino acid and vitamin in the material before and after fermentation in different fermentation devices is%
It can be seen from table 3 that the fermentation apparatus of example 1 can significantly increase the contents of amino acid active substances and vitamin B group elements after fermentation of the substrate raw material compared with the fermentation apparatus of the control group, the fermentation apparatus of example 1 can make the content of crude protein after fermentation higher, and the increase of the contents of amino acid and vitamin after fermentation of the substrate directly indicates that the utilization rate of the substrate by the fermentation apparatus of example 1 is greater than that of the fermentation apparatus of the control group.
Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention.
Claims (10)
1. A fermentation device for a bacillus subtilis microbial preparation is characterized by comprising a main fermentation chamber, a material cracking chamber, a material saccharification chamber, a strain culture chamber, a bacteria liquid separation chamber, a nutrient solution preparation chamber, an oxygen supply device, a spray drying chamber and an intelligent digital control device;
the device comprises a material cracking chamber, a material saccharification chamber, a first brake baffle and a first humidifying device, wherein the material cracking chamber is communicated with the material saccharification chamber, the first brake baffle is used for opening or closing a channel between the material cracking chamber and the material saccharification chamber, and the first brake baffle is driven by a brake controller to open or close the channel between the material cracking chamber and the material saccharification chamber;
a first nanometer far infrared heating plate is arranged on the periphery of the outer wall of the material saccharification chamber, and a first temperature sensor, a humidity sensor, a second humidifying device and a first stirring device are arranged in the material saccharification chamber;
the strain culture chamber is communicated with the bacteria liquid separation chamber, the second brake baffle is used for opening or closing a channel between the strain culture chamber and the bacteria liquid separation chamber, the second brake baffle is driven by a brake controller to open or close the channel between the strain culture chamber and the bacteria liquid separation chamber, a titanium dioxide flat plate is fixed on the upper surface of the second brake baffle, and a culture medium layer is fixed on the upper surface of the titanium dioxide flat plate;
the bacteria liquid separation chamber is provided with a microporous filter plate and a leaching head, the leaching head is communicated with a water supply tank through a pipeline, leaching drivers are arranged on the leaching head and the water supply tank, the leaching head is arranged above the microporous filter plate, the bacteria liquid separation chamber is provided with a discharge port, and the discharge port is arranged below the microporous filter plate;
a second stirring device is arranged in the nutrient solution blending chamber;
a second ultraviolet sterilization device is arranged on an air outlet pipeline of the oxygen supply device;
the outer wall of the main fermentation chamber is provided with a second nano far infrared heating plate, a first ultraviolet sterilization device, a dissolved oxygen monitor and a second temperature sensor are arranged in the main fermentation chamber, the top of the main fermentation chamber is provided with a feed inlet and an oxygen supply air inlet, the feed inlet at the top of the main fermentation chamber is communicated with a discharge port pipeline of the material saccharification chamber, the feed inlet at the top of the main fermentation chamber is communicated with a discharge port pipeline of the nutrient solution blending chamber, the feed inlet at the top of the main fermentation chamber is communicated with a discharge port pipeline of the bacteria liquid separation chamber, an air outlet pipeline of the oxygen supply device is communicated with the oxygen supply air inlet pipeline at the top of the main fermentation chamber, the bottom of the main fermentation chamber is provided with a discharge port, and the discharge port of the main fermentation chamber;
the intelligent digital control device is electrically connected with the first nanometer far infrared heating plate and controls the start and the close of the first nanometer far infrared heating plate, the intelligent digital control device is electrically connected with the second nanometer far infrared heating plate and controls the start and the close of the second nanometer far infrared heating plate, the intelligent digital control device is electrically connected with the first temperature sensor, the intelligent digital control device is electrically connected with the second temperature sensor, the intelligent digital control device is electrically connected with the oxygen supply device and controls the start and the close of the oxygen supply device, the intelligent digital control device is electrically connected with the dissolved oxygen monitor, the intelligent digital control device is electrically connected with the humidity sensor, the intelligent digital control device is electrically connected with the terahertz generator, the intelligent digital control device is electrically connected with the color sensor, the intelligent digital control device is electrically connected with the leaching driver, the intelligent digital control device is electrically connected with the brake controller, the intelligent digital control device is electrically connected with the first humidifying device, the intelligent digital control device is electrically connected with the second humidifying device, the intelligent digital control device is electrically connected with the first stirring device, the intelligent digital control device is electrically connected with the second stirring device, the intelligent digital control device is electrically connected with the first ultraviolet sterilizing device, the intelligent digital control device is electrically connected with the second ultraviolet sterilizing device, and the intelligent digital control device is electrically connected with the third ultraviolet sterilizing device.
2. The fermentation apparatus of claim 1, wherein the intelligent digital control apparatus comprises an intelligent digital control box and a power control box.
3. The fermentation device according to claim 1, wherein the terahertz generator can emit electromagnetic radiation of 0.1-10 THz.
4. The fermentation apparatus according to claim 1, wherein the third UV sterilization device comprises a fixed-band UV lamp, an electric push rod, and a third UV sterilization device controller, the fixed-band UV lamp is fixed on the electric push rod, and the third UV sterilization device controller controls the electric push rod to further push the fixed-band UV lamp to perform reciprocating translational motion in the strain cultivation room.
5. The fermentation apparatus according to claim 1, wherein a tourmaline layer is disposed between the outer wall of the material saccharification chamber and the first nano far infrared heating plate.
6. The fermentation device of claim 1, wherein a tourmaline layer and a graphene heat conducting plate are arranged between the outer wall of the main fermentation chamber and the second nanometer far infrared heating plate, the tourmaline layer is adjacent to the second nanometer far infrared heating plate, and the graphene heat conducting plate is adjacent to the outer wall of the main fermentation chamber.
7. The fermentation apparatus according to claim 6, wherein the graphene thermal conductive plate is loaded with nano titanium dioxide as a photocatalyst.
8. The fermentation device of claim 1, wherein the material cracking chamber and the material saccharifying chamber are connected to form a tank, the first braking baffle is horizontally arranged in the tank to divide the tank into the material cracking chamber and the material saccharifying chamber, the material cracking chamber is positioned above the first braking baffle, and the material saccharifying chamber is positioned below the first braking baffle.
9. The fermentation apparatus according to claim 1, wherein the strain culture chamber and the bacteria liquid separation chamber are connected to form a tank, the second brake baffle is horizontally disposed inside the tank to divide the tank into the strain culture chamber and the bacteria liquid separation chamber, the strain culture chamber is located above the second brake baffle, and the bacteria liquid separation chamber is located below the second brake baffle.
10. The fermenter according to claim 1, wherein a plurality of color sensors are provided in the seed culture chamber, the color sensors being uniformly and respectively above the culture medium layer.
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114107003A (en) * | 2021-11-25 | 2022-03-01 | 山东蔚蓝绿源生物科技有限公司 | Bacillus subtilis fermentation equipment for plants |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114107003A (en) * | 2021-11-25 | 2022-03-01 | 山东蔚蓝绿源生物科技有限公司 | Bacillus subtilis fermentation equipment for plants |
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