CN212651465U - Device suitable for aspergillus flavus fermentation metabolite draws fast - Google Patents

Abstract

The utility model discloses a device suitable for Aspergillus flavus fermentation metabolite draws fast in matter separation technical field, include: a separation tank assembly; a stirring device assembly mounted on top of the separation tank assembly; the first liquid pumping assembly is arranged on a liquid outlet of the separation tank assembly; the top of the extraction tank assembly is connected with the first liquid pumping assembly; a screen drum assembly mounted within an inner cavity of the extraction tank assembly; the second liquid pumping assembly is arranged on a liquid outlet at the bottom of the extraction tank assembly; the separation tank assembly comprises: a separator tank body; first annular installation piece, first annular installation piece is installed the inner chamber lateral wall bottom of knockout drum body, the utility model discloses can be quick extract aspergillus flavus fermentation metabolite, ensured aspergillus flavus fermentation metabolite extraction efficiency.

Description

Device suitable for aspergillus flavus fermentation metabolite draws fast

Technical Field

The utility model relates to a material separation technical field specifically is a device suitable for aspergillus flavus fermentation metabolite draws fast.

Background

Aspergillus flavus, fungi imperfecti, a common saprophytic fungus. It is commonly found in mildewed grains, grain products and other mildewed organic matters. The colony grows faster, has loose structure, and has a grayish green surface and a colorless or slightly brown back surface. The bacterial cells are composed of many complex branched hyphae. The vegetative hyphae have a separation; a part of aerial hyphae forms a long and rough conidiophores peduncle, the top of the aerial hyphae forms a flask-shaped or approximately spherical top sac, a plurality of small peduncles (generally double layers) are generated on the surface, and the small peduncles form clusters of spherical conidiophores with rough surfaces. Conidiophores, apical sacs, phimosis and conidia synthesize spore heads, can be used for producing amylase, protease, phosphodiesterase and the like, and are also common strains in the brewing industry.

Fermentation refers to the process by which a person prepares the microbial cells themselves or direct or secondary metabolites by virtue of the life activities of the microorganisms under aerobic or anaerobic conditions.

The existing rapid extraction device for the aspergillus flavus fermentation metabolites is low in efficiency, and the aspergillus flavus fermentation metabolites are separated by using a natural standing mode through a separation liquid, so that the efficiency of rapidly extracting the aspergillus flavus fermentation metabolites is greatly reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a device suitable for Aspergillus flavus fermentation metabolite draws fast to solve the current quick extraction element inefficiency of Aspergillus flavus fermentation metabolite that proposes in the above-mentioned background art, utilize the mode of naturally stewing to separate Aspergillus flavus and Aspergillus flavus fermentation metabolite through the parting liquid, very big reduction the problem of the efficiency that Aspergillus flavus fermentation metabolite drawed fast.

In order to achieve the above object, the utility model provides a following technical scheme: a device suitable for Aspergillus flavus fermentation metabolite draws fast includes:

a separation tank assembly;

a stirring device assembly mounted on top of the separation tank assembly;

the first liquid pumping assembly is arranged on a liquid outlet of the separation tank assembly;

the top of the extraction tank assembly is connected with the first liquid pumping assembly;

a screen drum assembly mounted within an inner cavity of the extraction tank assembly;

the second liquid pumping assembly is arranged on a liquid outlet at the bottom of the extraction tank assembly;

and the collecting box is connected with the second liquid pumping assembly.

Preferably, the separation tank assembly comprises:

a separator tank body;

the first annular mounting block is mounted at the bottom of the inner cavity side wall of the separation tank body;

the filter screen, the filter screen is installed the top of first annular installation piece, the filter screen is in the inner chamber bottom of knockout drum body.

Preferably, the stirring device assembly comprises:

a first top cover;

the ultrasonic stirring rod is installed at the top middle end of the first top cover and penetrates through the bottom middle end of the first top cover.

Preferably, the first pumping assembly comprises:

a first water pump;

the first liquid discharge pipeline is arranged on a water inlet of the first water pump;

and the second liquid drainage pipeline is arranged on a water outlet of the first water pump.

Preferably, the extraction tank assembly comprises:

an extraction tank body;

a second top cover installed at the top of the extraction tank body;

and the second annular mounting block is mounted at the top of the side wall of the inner cavity of the extracting tank body.

Preferably, the screen drum assembly comprises:

a screen cylinder body;

and the sieve holes are uniformly formed in the side wall and the bottom of the sieve cylinder body.

Preferably, the second pumping assembly comprises:

a second water pump;

the third water drainage pipeline is arranged on the water inlet of the second water pump;

and the fourth drainage pipeline is arranged on the drainage port of the second water pump.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses can be quick draw aspergillus flavus fermentation metabolite, aspergillus flavus fermentation metabolite extraction efficiency has been ensured, ultrasonic stirring rod and raw materials and parting liquid contact, stir raw materials and parting liquid through the ultrasonic stirring rod, with aspergillus flavus and aspergillus flavus fermentation metabolite separation, the inner chamber bottom that the separating aspergillus flavus fermentation metabolite enters into the knockout drum body through the filter screen, stir the separation through the ultrasonic wave, can be quick separate aspergillus flavus and aspergillus flavus fermentation metabolite, second flowing back pipeline pegs graft in the top middle-end of second top cap and runs through the bottom middle-end of second top cap, second flowing back pipeline pegs graft in the inner chamber of drawing the jar body, a sieve section of thick bamboo body passes through the bolt and installs on second ring-shaped installation piece, a sieve section of thick bamboo body is drawing the inner chamber of jar body, the top of a sieve section of thick bamboo body is corresponding with second flowing back pipeline, through first water pump, the cooperation of first drain line and second drain line is used and is taken this internal parting liquid of knockout drum and aspergillus flavus fermentation metabolite out to a sieve section of thick bamboo originally internal, extract aspergillus flavus fermentation metabolite from the parting liquid through the sieve mesh, the parting liquid enters into the inner chamber bottom of extracting a jar body through the sieve mesh, the fourth drainage pipe other end is pegged graft at the top of collecting box, fourth drainage pipe runs through the inner chamber top of collecting box, through the second water pump, the cooperation of third drainage pipe and fourth drainage pipe is used and is taken into the parting liquid of the inner chamber bottom of extracting a jar body and take out the inner chamber of collecting box, recycle the parting liquid.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the separation tank assembly of the present invention;

FIG. 3 is a schematic structural view of the stirring device assembly of the present invention;

FIG. 4 is a schematic structural view of a first fluid pumping assembly of the present invention;

FIG. 5 is a schematic view of the structure of the extraction tank assembly of the present invention;

FIG. 6 is a schematic structural view of the screen cylinder assembly of the present invention;

fig. 7 is a schematic structural view of a second fluid pumping assembly of the present invention.

In the figure: 100 separation tank assembly, 110 separation tank body, 120 first annular mounting block, 130 filter screens, 200 stirring device assembly, 210 first top cover, 220 ultrasonic stirring rod, 300 first liquid pumping assembly, 310 first water pump, 320 first liquid drainage pipeline, 330 second liquid drainage pipeline, 400 extraction tank assembly, 410 extraction tank body, 420 second top cover, 430 second annular mounting block, 500 screen drum assembly, 510 screen drum body, 520 screen holes, 600 second liquid pumping assembly, 610 second water pump, 620 third water drainage pipeline, 630 fourth water drainage pipeline, 700 collection box.

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a device suitable for aspergillus flavus fermentation metabolite draws fast, can be quick extract aspergillus flavus fermentation metabolite, ensured aspergillus flavus fermentation metabolite extraction efficiency, please refer to figure 1, include: the separation tank assembly 100, the stirring device assembly 200, the first liquid pumping assembly 300, the extraction tank assembly 400, the screen drum assembly 500, the second liquid pumping assembly 600 and the collection box 700;

referring to fig. 1-2, a separation tank assembly 100 includes:

the raw materials and the separation liquid are put into the inner cavity of the separation tank body 110;

the first annular mounting block 120 is welded at the bottom of the inner cavity side wall of the separation tank body 110;

the filter screen 130 is installed on the top of the first annular installation block 120 through bolts, and the filter screen 130 is arranged at the bottom of the inner cavity of the separation tank body 110;

referring to fig. 1-3, a blender assembly 200 is mounted on top of the separation tank assembly 100, the blender assembly 200 comprising:

the first top cap 210 is installed on the top of the separator tank body 110 by bolts;

the ultrasonic stirring rod 220 is installed at the top middle end of the first top cover 210 through a bolt, the ultrasonic stirring rod 220 penetrates through the bottom middle end of the first top cover 210, the ultrasonic stirring rod 220 is in contact with the raw material and the separation liquid, the raw material and the separation liquid are stirred through the ultrasonic stirring rod 220, aspergillus flavus and aspergillus flavus fermentation metabolites are separated, the separated aspergillus flavus fermentation metabolites enter the bottom of the inner cavity of the separation tank body 110 through the filter screen 130, and are stirred and separated through ultrasonic waves, so that the aspergillus flavus and the aspergillus flavus fermentation metabolites can be rapidly separated;

referring to fig. 1, fig. 2 and fig. 4, a first pumping assembly 300 is installed at the liquid outlet of the separation tank assembly 100, and the first pumping assembly 300 includes:

the first water pump 310 is at the lower end of the separation tank body 110;

the first liquid discharge pipe 320 is installed on the water inlet of the first water pump 310 through a bolt, and the other end of the first liquid discharge pipe 320 is installed on the liquid discharge port at the bottom of the separation tank body 110 through a bolt;

the second liquid discharge pipeline 330 is installed on a water discharge port of the first water pump 310 through bolts, and the separation liquid and the aspergillus flavus fermentation metabolites in the separation tank body 110 are pumped out through the matching use of the first water pump 310, the first liquid discharge pipeline 320 and the second liquid discharge pipeline 330;

referring to fig. 1, 4 and 5, the top of the extracting tank assembly 400 is connected to the first pumping assembly 300, and the extracting tank assembly 400 includes:

the extraction tank body 410 is at the lower end of the first water pump 310;

the second top cover 420 is installed on the top of the extraction tank body 410 through bolts, the second liquid discharge pipe 330 is inserted into the top middle end of the second top cover 420 and penetrates through the bottom middle end of the second top cover 420, and the second liquid discharge pipe 330 is inserted into the inner cavity of the extraction tank body 410;

the second annular mounting block 430 is welded and mounted on the top of the inner cavity side wall of the extraction tank body 410;

referring to fig. 1, 4, 5 and 6, a screen drum assembly 500 is installed in the inner cavity of the extraction tank assembly 400, the screen drum assembly 500 includes:

the screen cylinder body 510 is mounted on the second annular mounting block 430 through bolts, the screen cylinder body 510 is arranged in the inner cavity of the extraction tank body 410, the top of the screen cylinder body 510 corresponds to the second liquid drainage pipeline 330, and the separation liquid and the aspergillus flavus fermentation metabolites in the separation tank body 110 are pumped into the screen cylinder body 510 through the cooperation of the first water pump 310, the first liquid drainage pipeline 320 and the second liquid drainage pipeline 330;

the plurality of sieve pores 520 are uniformly arranged on the side wall and the bottom of the sieve cylinder body 510, Aspergillus flavus fermentation metabolites are extracted from the separation liquid through the sieve pores 520, and the separation liquid enters the bottom of the inner cavity of the extraction tank body 410 through the sieve pores 520;

referring to fig. 1, 5 and 7, a second pumping assembly 600 is installed on the bottom outlet of the extracting tank assembly 400, and the second pumping assembly 600 includes:

the second water pump 610 is at the lower end of the extraction tank body 410;

the third water discharge pipeline 620 is installed on the water inlet of the second water pump 610 through a bolt, and the other end of the third water discharge pipeline 620 is installed on the bottom liquid outlet of the extraction tank body 410 through a bolt;

the fourth drain pipe 630 is installed on the drain port of the second water pump 610 by a bolt;

referring to fig. 1, 5 and 7, the other end of the fourth drainage pipe 630 is inserted into the top of the collection box 700, the fourth drainage pipe 630 penetrates the top of the inner cavity of the collection box 700, and the separation liquid entering the bottom of the inner cavity of the extraction tank body 410 is pumped into the inner cavity of the collection box 700 by the cooperation of the second water pump 610, the third drainage pipe 620 and the fourth drainage pipe 630, so as to be recycled.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (7)

1. The utility model provides a device suitable for Aspergillus flavus fermentation metabolite draws fast which characterized in that: the method comprises the following steps:

a separation tank assembly (100);

a blender assembly (200), the blender assembly (200) mounted on top of the separation tank assembly (100);

a first liquid extraction assembly (300), wherein the first liquid extraction assembly (300) is installed on a liquid outlet of the separation tank assembly (100);

an extraction tank assembly (400), the top of the extraction tank assembly (400) being connected with the first liquid extraction assembly (300);

a screen cylinder assembly (500), the screen cylinder assembly (500) mounted in an interior cavity of the extraction tank assembly (400);

a second pumping assembly (600), the second pumping assembly (600) being mounted on a bottom outlet of the extraction tank assembly (400);

a collection box (700), the collection box (700) being connected with the second pumping assembly (600).

2. The device suitable for the rapid extraction of the aspergillus flavus fermentation metabolites as claimed in claim 1, wherein the device comprises: the separation tank assembly (100) comprises:

a separator tank body (110);

a first annular mounting block (120), wherein the first annular mounting block (120) is mounted at the bottom of the inner cavity side wall of the separation tank body (110);

the filter screen (130) is installed at the top of the first annular installation block (120), and the filter screen (130) is arranged at the bottom of the inner cavity of the separation tank body (110).

3. The device suitable for the rapid extraction of the aspergillus flavus fermentation metabolites as claimed in claim 1, wherein the device comprises: the stirring device assembly (200) comprises:

a first top cover (210);

the ultrasonic stirring rod (220) is installed at the top middle end of the first top cover (210), and the ultrasonic stirring rod (220) penetrates through the bottom middle end of the first top cover (210).

4. The device suitable for the rapid extraction of the aspergillus flavus fermentation metabolites as claimed in claim 1, wherein the device comprises: the first pumping assembly (300) comprises:

a first water pump (310);

a first liquid discharge pipe (320), wherein the first liquid discharge pipe (320) is arranged on a water inlet of the first water pump (310);

a second drain line (330), the second drain line (330) being mounted on a drain of the first water pump (310).

5. The device suitable for the rapid extraction of the aspergillus flavus fermentation metabolites as claimed in claim 1, wherein the device comprises: the extraction tank assembly (400) comprises:

an extraction tank body (410);

a second top cap (420), the second top cap (420) being mounted on the top of the extraction tank body (410);

a second annular mounting block (430), the second annular mounting block (430) mounted on a top of an inner cavity sidewall of the extraction tank body (410).

6. The device suitable for the rapid extraction of the aspergillus flavus fermentation metabolites as claimed in claim 1, wherein the device comprises: the screen cylinder assembly (500) includes:

a screen cylinder body (510);

the sieve drum comprises a plurality of sieve holes (520), wherein the sieve holes (520) are uniformly formed in the side wall and the bottom of the sieve drum body (510).

7. The device suitable for the rapid extraction of the aspergillus flavus fermentation metabolites as claimed in claim 1, wherein the device comprises: the second pumping assembly (600) comprises:

a second water pump (610);

a third drain pipe (620), wherein the third drain pipe (620) is installed on a water inlet of the second water pump (610);

a fourth drain pipe (630), the fourth drain pipe (630) being installed on a drain port of the second water pump (610).

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