CN211847921U - Compound photodynamic bacterium agent production system device - Google Patents

Abstract

The utility model discloses a compound photodynamic fungus agent production system device, including agitator tank, cultivation jar and three support frame, be equipped with agitating unit on the agitator tank, the lower extreme of agitator tank is connected with the discharging pipe, the one end of discharging pipe is connected with the circulating pump, one side of circulating pump is connected with the conveying pipeline, be connected with the ejector on the cultivation jar, the one end of conveying pipeline is connected on the ejector, and the both sides of three support frame are all fixed with the multilayer circulating pipe through equidistant U type card. The utility model discloses reach and make the purpose of ancient fungus crowd photosynthetic bacteria fast development and recycle to whole process is simple, and operating procedure is few, makes things convenient for the grasp of planting personnel, thereby moves the biotechnology to the field end of a land, and the balanced liquid production of microorganism and application are independently controlled by the peasant, solves the problem of non-point source pollution from the source, lets soil return fertile health, nutrition balance's this source, from more this solution food safety problem.

Description

Compound photodynamic bacterium agent production system device

Technical Field

The utility model relates to a microbial fertilizer cultivates technical field, especially relates to a compound photodynamic fungus agent production system device.

Background

The microbial fertilizer is a biological fertilizer prepared by industrially culturing and fermenting one or more beneficial microorganisms, has higher yield and quality than the conventional applied fertilizer under the condition of reducing the using amount of the fertilizer and simultaneously mixing seeds with the biological bacterial fertilizer, and can improve the soil environment, such as enriching soil microbial populations, loosening the soil, improving the soil aggregate structure and the like. Photosynthetic bacteria are prokaryotes which appear earliest on the earth, commonly exist in the nature and have an original light energy synthesis system, are a general name of bacteria which do not emit oxygen and perform photosynthesis under anaerobic conditions, are gram-negative bacteria without the capability of forming spores, and are microorganisms which take light as energy and can perform photosynthesis by using organic matters, sulfides, ammonia and the like in the nature as hydrogen donor and carbon source under anaerobic illumination or aerobic dark conditions.

The composite photodynamic flora provides various physiological nutrients for plants, provides nutrients and synergistic symbiosis for various microorganisms in the soil environment, shows the inclusion and symbiosis of the archaea flora, ensures that various microbial flora play a role in promoting and improving the soil environment where the microbial flora lives in the whole life activity cycle, changes the soil aggregate structure, increases the organic matters and the adhesive property of the soil, and is more favorable for the growth and development of crops.

However, when the microorganism is used as a fertilizer at present, the steps are complex, the cost is high, and when the microorganism is used by a grower, the operation cannot be skillfully performed, so that errors occur in the process of culturing flora, the flora grows slowly and even dies, the problem of soil pollution cannot be solved, and the requirement of the growth of plants cannot be met, so that the improvement is needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the existing composite photodynamic flora is more in operation steps and slow in learning, can not be used for rapidly culturing the composite photodynamic flora, is not suitable for being popularized on a large scale, and provides a composite photodynamic bacterial agent production system device.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a composite photodynamic bacterium agent production system device comprises an agitator tank, a culture tank and three support frames, wherein the agitator tank is provided with an agitating device, the lower end of the agitator tank is connected with a discharge pipe, one end of the discharge pipe is connected with a circulating pump, one side of the circulating pump is connected with a feed delivery pipe, the culture tank is connected with an ejector, one end of the feed delivery pipe is connected with the ejector, two sides of the three support frames are respectively and equidistantly fixed with a plurality of circulating pipes through U-shaped clamps, two circulating pipes on the same side form a group, the two circulating pipes in the same group are connected through a U-shaped elbow, the circulating pipe at the lower end of the support frame is connected with the culture tank through a third connecting pipe, the circulating pipe at the upper end of the support frame is connected with a second connecting pipe, one end of the second connecting pipe is connected, the upper end both sides of agitator tank all are connected with the inlet pipe, and one of them first connecting tube is connected on the inlet pipe.

Preferably, agitating unit is including installing the support frame on the agitator tank, install the motor on the support frame, the output shaft end of motor runs through the lateral wall of support frame and extends to the lower extreme of support frame, the output shaft end of motor has the puddler through the coupling joint, the lower extreme of puddler runs through the agitator tank and extends to in the agitator tank, equidistant a plurality of stirring leaves of installing on the puddler.

Preferably, one side of each of the three support frames is fixed with a connecting rod, and one end of each of the three connecting rods is fixed with a reflector.

Preferably, the lower ends of the three support frames are all fixed with a base.

Preferably, the circulation pipe is made of a transparent glass pipe or a transparent polycarbonate pipe material.

Preferably, the diameter of the circulation tube is 90-110 mm.

Preferably, the U-shaped elbow is made of stainless steel elbow material.

Preferably, the joint of the U-shaped elbow and the circulating pipe is hermetically connected by a special silicon rubber sealing ring.

Preferably, all be equipped with the recess on the three support frame, the second connecting pipe is located the recess.

Preferably, a sensor such as a pressure gauge and a thermometer is mounted on the culture tank.

Compared with the prior art, the beneficial effects of the utility model are that:

1. through the matching among the plurality of circulating pipes, the stirring tank and the culture tank, the stirring tank uniformly stirs the materials, so that the sufficient nutrition of the archaea group photosynthetic bacteria can be ensured, the archaea group photosynthetic bacteria can grow quickly, and the slow growth of the archaea group photosynthetic bacteria caused by the insufficient nutrition of the culture solution can be avoided;

2. through the matching between the culture tank and the jet pump, the jet pump can control the inflow of oxygen, can realize aerobic, anaerobic and facultative multi-mode fermentation, has low power source consumption, full fermentation, low cost and convenient use;

in conclusion, the device achieves the purpose of rapidly developing and recycling the photosynthetic bacteria of the archaea group, is simple in whole process, few in operation steps and convenient for the farmers to master, so that the biotechnology is moved to the field, the farmers independently control the production and application of the microbial balance liquid, the problem of non-point source pollution is solved from the source, the soil returns to the original source of fertile health and balanced nutrition, and the food safety problem is solved from the source.

Drawings

FIG. 1 is a front view of a composite photodynamic bacterial agent production system device provided by the utility model;

FIG. 2 is a schematic view of a reflector structure of a composite photodynamic bacterial agent production system device provided by the utility model;

fig. 3 is a top view of the composite photodynamic bacterial agent production system device provided by the utility model.

In the figure: 1 stirring tank, 2 stirring blades, 3 stirring rods, 4 discharging pipes, 5 conveying pipes, 6 circulating pumps, 7 feeding pipes, 8 motors, 9 pressure meters, 10 jet pumps, 11 first connecting pipes, 12 second connecting pipes, 13 supporting frames, 14U-shaped elbows, 15U-shaped clamps, 16 collecting tanks, 17 circulating pipes, 18 third connecting pipes, 19 culture tanks, 20 grooves, 21 connecting rods, 22 reflecting plates and 23 bases.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, a composite photodynamic bacterial agent production system device comprises an agitator tank 1, a culture tank 19 and three support frames 13, wherein the three support frames 13 are all made of hot galvanizing groove type plate materials, grooves 20 are arranged on the three support frames 13, the second connecting pipe 12 is positioned in the groove 20, the groove 20 supports the second connecting pipe 12, a pressure gauge 9 is arranged on the culture tank 19, the pressure gauge 9 is convenient for workers to check the pressure in the culture tank 19 and exhaust and add oxygen according to needs, a base 23 is fixed at the lower ends of the three support frames 13, the base 23 is fixed on the ground when in use, the support frames 13 are firmly fixed, so that a circulating pipe 17 is fixed, connecting rods 21 are fixed on one side of each of the three support frames 13, a reflecting plate 22 is fixed at one end of each of the three connecting rods 21, the reflecting plate 22 is arranged obliquely, and sunlight is reflected to the circulating pipe 17, guarantee the illumination of fungus crowd sufficient, be equipped with agitating unit on agitator tank 1, agitating unit stirs the material in agitator tank 1, with the material stirring, guarantees that fungus crowd nutrition is sufficient, makes fungus crowd normal growth, can install corresponding 60W incandescent lamp on three support frame 13 simultaneously and carry out illumination, utilizes outer fringe supplementary light source, supplementary illumination night.

Referring to fig. 1-3, the lower end of a stirring tank 1 is connected with a discharge pipe 4, one end of the discharge pipe 4 is connected with a circulating pump 6, the circulating pump 6 controls the operation of culture solution in the whole device, so that flora passes through a circulating pipe 17 for illumination, a closed-loop self-circulation system is formed by driving, one side of the circulating pump 6 is connected with a feed pipe 5, a jet pump 10 is connected on a culture tank 19, the jet pump 10 is connected with air in a sterile room, when oxygen is needed to be fed, the jet device 10 is controlled, aerobic, anaerobic and facultative multi-mode fermentation can be realized, one end of the feed pipe 5 is connected on the jet device 10, a plurality of circulating pipes 17 are fixed on two sides of three support frames 13 at equal intervals through U-shaped clamps 15, the diameter of the circulating pipe 17 is 90-110mm, the circulating pipe 17 is made of transparent glass pipe or transparent poly-carbon pipe material, the, ensuring sufficient illumination, forming two circulating pipes 17 on the same side into a group, connecting the two circulating pipes 17 in the same group through a U-shaped elbow 14, wherein the U-shaped elbow 14 is made of stainless steel elbow material and is used for increasing system heat energy supplement, installing a sensor component, installing a temperature and pressure gauge device, the joint of the U-shaped elbow 14 and the circulating pipes 17 is hermetically connected by a special silicon rubber sealing ring, a quick-connection flange is arranged on the circulating pipe 17 and is directly connected with the quick-connection through the U-shaped elbow 14 through a pair of quick-connection flanges, so that the opening and the cleaning are convenient, the circulating pipe 17 at the lower end of a support frame 13 is connected with a culture tank 19 through a third connecting pipe 18, the circulating pipe 17 at the upper end of the support frame 13 is connected with a second connecting pipe 12, one end of the second connecting pipe 12 is connected with a collection tank 16, and after, when carrying, the bacterial is kept in succession in two circulating pipes 17, make things convenient for the later stage to cultivate, store, later add nutrient material in agitator tank 1, make the fungus crowd breed once more, can directly carry the field when using, be connected with first connecting pipe 11 on the second connecting pipe 12, agitator tank 1's upper end both sides all are connected with inlet pipe 7, one of them first connecting pipe 11 is connected on inlet pipe 7, first connecting pipe 11 can make the fungus crowd form normal circulation, guarantee that the fungus crowd shines through sufficient light, guarantee the growth of fungus crowd, whole step is simple, the input cost is less, the planting personnel only need regularly add nutrient material can.

Referring to fig. 1, agitating unit is including installing the support frame on agitator tank 1, install motor 8 on the support frame, motor 8's output shaft end runs through the lateral wall of support frame and extends to the lower extreme of support frame, motor 8's output shaft end has puddler 3 through the coupling joint, motor 8 drives puddler 3 and rotates, agitator tank 1 is run through and extends to agitator tank 1 to the lower extreme of puddler 3, equidistant a plurality of stirring leaves 2 of installing on the puddler 3, puddler 3 drives the rotation of stirring leaf 2, guarantee that the nutrient material stirring in agitator tank 1, make the fungus crowd nutrition sufficient.

In the utility model, when in use, the material that will be used is firstly dissolved and poured into the stirring tank 1, at this moment, the motor 8 drives the shaft coupling and the stirring rod 3 to rotate, the stirring rod 3 drives the stirring blade 2 to rotate, the stirring blade 2 puts the archaea group photosynthetic bacteria that need to be cultured into the stirring tank 1, at this moment, the circulating pump 6 is started, the material and the archaea group photosynthetic bacteria are conveyed into the culture tank 19, the culture tank 19 is provided with the jet pump 10, the jet pump 10 is connected with the aseptic chamber, the aseptic chamber filters the air and then conveys the air into the culture tank 19, oxygen is conveyed to the archaea group photosynthetic bacteria, the solution is conveyed into the circulating pipe 17 through the third connecting pipe 18, because the circulating pipe 17 is made of transparent glass pipe or transparent carbon gathering pipe material, the U-shaped elbow 14 and PVC quick-connection are adopted between the circulating pipes 17, a plurality of circulating pipes 17 are provided, the flora photosynthetic bacteria slowly flow in the circulating pipe 17, sufficient illumination is provided for the archaea group photosynthetic bacteria, the normal growth of the archaea group photosynthetic bacteria is ensured, meanwhile, a reflector 22 is fixed on one side of each of three support frames 13 through a connecting rod 21, an aluminum film reflector is paved on the reflector 22, the reflector is reflected to a circulating pipe 17 when in sunlight irradiation, then the flora group photosynthetic bacteria are conveyed to a stirring tank 1 through a second connecting pipe 12 and a first connecting pipe 11, then the flora group photosynthetic bacteria are conveyed to the circulating pipe 17 again through a circulating pump 6, the normal propagation of the flora group photosynthetic bacteria is ensured through repeated sunlight irradiation, after the flora group photosynthetic bacteria are propagated, the flora group photosynthetic bacteria are conveyed to a collecting tank 16 through the second connecting pipe 12 until culture solution remains in the two circulating pipes 17, then raw materials are continuously added into the stirring tank 1, the culture solution in the remaining two circulating pipes 17 is conveyed to the stirring tank 1 again, and the propagation is continuously carried out through the circulating pipe 17, when the culture medium circulation type stirring tank is used, the culture medium in the collection tank 16 is used, after the culture medium is used, the culture medium in the circulation pipes 17 is used until the culture medium remains in the two circulation pipes 17, and then the raw materials can be continuously added into the stirring tank 1 for culture, so that the circulation use can be realized, the processing steps can be reduced when the stirring tank is used, and the application range is wide.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (10)

1. The utility model provides a compound photodynamic fungus agent production system device, includes agitator tank (1), culture tank (19) and three support frame (13), its characterized in that: the stirring device is characterized in that a stirring device is arranged on the stirring tank (1), the lower end of the stirring tank (1) is connected with a discharging pipe (4), one end of the discharging pipe (4) is connected with a circulating pump (6), one side of the circulating pump (6) is connected with a conveying pipe (5), the culture tank (19) is connected with an ejector (10), one end of the conveying pipe (5) is connected onto the ejector (10), a plurality of circulating pipes (17) are fixed on two sides of three support frames (13) at equal intervals through U-shaped clamps (15), the two circulating pipes (17) on the same side are in a group, the two circulating pipes (17) in the same group are connected through U-shaped elbows (14), the circulating pipe (17) at the lower end of the support frame (13) is connected with the culture tank (19) through a third connecting pipe (18), and the circulating pipe (17) at the upper end of the support frame (13, the one end of second connecting pipe (12) is connected with holding vessel (16), be connected with first connecting pipe (11) on second connecting pipe (12), the upper end both sides of agitator tank (1) all are connected with inlet pipe (7), and one of them first connecting pipe (11) are connected on inlet pipe (7).

2. The composite photodynamic bacterial agent production system device of claim 1, wherein the stirring device comprises a support frame installed on a stirring tank (1), a motor (8) is installed on the support frame, the tail end of an output shaft of the motor (8) penetrates through the side wall of the support frame and extends to the lower end of the support frame, the tail end of the output shaft of the motor (8) is connected with a stirring rod (3) through a coupler, the lower end of the stirring rod (3) penetrates through the stirring tank (1) and extends into the stirring tank (1), and a plurality of stirring blades (2) are installed on the stirring rod (3) at equal intervals.

3. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein connecting rods (21) are fixed on one sides of the three support frames (13), and a reflector (22) is fixed at one end of each of the three connecting rods (21).

4. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein the bases (23) are fixed at the lower ends of the three support frames (13).

5. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein the circulating pipe (17) is made of a transparent glass pipe or a transparent poly-carbon pipe material.

6. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein the diameter of the circulating pipe (17) is 90-110 mm.

7. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein the U-shaped elbow (14) is made of stainless steel elbow material.

8. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein the joint of the U-shaped elbow (14) and the circulating pipe (17) is hermetically connected by a special silicone rubber sealing ring.

9. The composite photodynamic bacterial agent production system device according to claim 1, wherein grooves (20) are formed in all three support frames (13), and the second connecting pipe (12) is located in the grooves (20).

10. The composite photodynamic bacterial agent production system device as claimed in claim 1, wherein a pressure gauge (9) is mounted on the culture tank (19).

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