CN214612487U - Fungus liquid culture system with structure of heating - Google Patents

Abstract

The utility model discloses a fungus liquid culture system with structure of heating, including the fermentation cylinder, the top center fixedly connected with motor of fermentation cylinder, and the output fixedly connected with (mixing) shaft of motor, the (mixing) shaft bottom runs through the fermentation cylinder, and the (mixing) shaft lateral surface is fixed with the stirring leaf, top one side fixedly connected with feed inlet of fermentation cylinder, and the fermentation cylinder includes first tank shell and is located the second tank shell of first tank shell, be equipped with the heat insulating chamber between first tank shell and the second tank shell, and the lateral surface fixedly connected with electric heat membrane of second tank shell, fermentation cylinder bottom center fixedly connected with delivery port. The utility model can adjust the water inlet flow velocity and the injection direction through the arranged water inlet connecting component, thereby quickly and effectively cleaning the inner wall of the fermentation device; the height of the fermentation tank can be adjusted rapidly and accurately through the lifting adjusting assembly, and bacteria after culture can be taken out conveniently.

Description

Fungus liquid culture system with structure of heating

Technical Field

The utility model relates to a bacterial culture technical field specifically is a fungus liquid culture system with structure of heating.

Background

Bacterial culture is a technique in which bacteria are grown and propagated artificially. The bacteria are widely distributed in nature, large in quantity and multiple in types, can benefit mankind, and can also become a cause of diseases. Most bacteria can be cultured artificially by inoculating them on a culture medium and allowing them to grow and propagate. The cultured bacteria are used for research, identification and application. Bacterial culture is a complex technique.

In the prior art, a bacterial liquid culture system with a heating structure (publication No. CN210048758U) includes a raw water filtering device, a fermentation device and a stirring device. The raw water filtering device comprises a water storage tank and a filter cylinder which are communicated with each other, and a filter material is arranged in the filter cylinder. The fermentation device comprises a fermentation tank, the fermentation tank is communicated with the water storage tank through a pipeline, a water pump and an on-off valve are arranged on the pipeline, the fermentation tank comprises a first tank shell and a second tank shell positioned in the first tank shell, an interval is arranged between the first tank shell and the second tank shell so as to form a heat insulation cavity between the first tank shell and the second tank shell, and a first electric heating film is attached to the outer wall of the second tank shell. The stirring device comprises a rotary driving device and a stirring paddle which are connected together, the rotary driving device is arranged on the fermentation tank, a second electric heating film and a conductive sliding ring are arranged on the stirring paddle, and the second electric heating film is electrically connected with the conductive sliding ring.

The prior art has the following problems: 1. after the bacteria are cultured, the bacteria are generally taken out of the fermentation device, but the height of the existing fermentation device cannot be effectively adjusted, so that the cultured bacteria are inconvenient for workers to take out; 2. after the bacteria are cultured, some bacteria liquid can be remained in the fermentation device, the interior of the fermentation device needs to be cleaned for ensuring the next normal use, water is generally and directly injected through a water inlet for cleaning, but the cleaning mode cannot adjust the water inlet flow rate and the injection direction, and further the cleaning of the inner wall of the fermentation device is not good enough.

Therefore, a bacterial liquid culture system with a heating structure is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a bacteria liquid culture system with a heating structure, which can adjust the water inlet flow velocity and the injection direction through the arranged water inlet connecting component, thereby quickly and effectively cleaning the inner wall of a fermentation device; through the height of the quick accurate regulation fermentation cylinder of lift adjustment subassembly that sets up, be convenient for take out the bacterium after the cultivation to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a fungus liquid culture system with structure of heating, includes the fermentation cylinder, the top center fixedly connected with motor of fermentation cylinder, and the output fixedly connected with (mixing) shaft of motor, the (mixing) shaft bottom runs through the fermentation cylinder, and the (mixing) shaft lateral surface is fixed with the stirring leaf, top one side fixedly connected with feed inlet of fermentation cylinder, and the fermentation cylinder includes first shell and is located the second shell of first shell, be equipped with the heat insulating chamber between first shell and the second shell, and the lateral surface fixedly connected with electric heat membrane of second shell, fermentation cylinder bottom center fixedly connected with delivery port, the top opposite side of fermentation cylinder is equipped with into water coupling assembling and is used for adjusting the inflow and kicks into the direction, and is equipped with the bacterium that the high convenient for of lift adjustment subassembly on the fermentation cylinder lateral surface takes out after the cultivation.

The water inlet connecting assembly can adjust the water inlet flow rate and the injection direction, so that the inner wall of the fermentation device can be quickly and effectively cleaned; the height of the fermentation tank can be adjusted rapidly and accurately through the lifting adjusting assembly, and bacteria after culture can be taken out conveniently.

Preferably, the lift adjustment subassembly includes a plurality of connecting rods, the even fixed connection of a plurality of connecting rods is on the fermentation cylinder lateral surface, and the bottom fixedly connected with hydraulic lifting cylinder of a plurality of connecting rods, fermentation cylinder bottom border fixedly connected with frame, and frame bottom one side fixedly connected with lift height observation subassembly.

The hydraulic lifting cylinder is connected with an external hydraulic oil station to control the lifting of the connecting rod.

Preferably, the lifting height observation assembly comprises a lifting rod, the top end of the lifting rod is fixed on one side of the bottom end of the frame, the bottom end of the lifting rod is movably connected with a loop bar, a lifting groove is formed in the top end of the loop bar, the bottom end of the lifting rod is movably connected inside the lifting groove, and a side face of the lifting rod is provided with first scales.

The setting of first scale is convenient for the staff to observe the concrete height that the lifter goes up and down in the lift groove.

Preferably, the water inlet connecting assembly comprises a rotary ball, the rotary ball is embedded in a caulking groove formed in the top end of the fermentation tank movably, an outer sleeve is fixedly connected inside the rotary ball, an inner sleeve is arranged inside the outer sleeve, a first water inlet is formed in the bottom end of the outer sleeve, and a second water inlet matched with the first water inlet is formed in the bottom end of the inner sleeve.

The water inlet flow speed is controlled by controlling the size of the superposition area of the second water inlet and the first water inlet.

Preferably, the outer side surface of the inner sleeve is fixedly connected with an annular clamping block, and the annular clamping block is movably embedded in an annular clamping groove formed in the inner side surface of the outer sleeve.

The annular clamping block and the annular clamping groove are arranged to prevent the inner sleeve from being separated from the outer sleeve.

Preferably, the top end of the rotating ball and the top end edge of the outer sleeve are provided with second scales.

The setting of second scale is convenient for the staff accurate control second water inlet and first water inlet coincidence area's size.

Preferably, the top end of the feed inlet is detachably and fixedly connected with a cover.

The setting of lid is avoided external impurity to get into the fermentation cylinder through the feed inlet.

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

1. through the water inlet connecting assembly arranged, the water inlet flow speed and the injection direction can be adjusted, and then the inner wall of the fermentation device is quickly and effectively cleaned.

2. The height of the fermentation tank can be adjusted rapidly and accurately through the lifting adjusting assembly, and bacteria after culture can be taken out conveniently.

3. Through the lifting height observation assembly, the staff of being convenient for observes the concrete height that the lifter goes up and down in the lift groove, improves the lift precision.

4. Through the inner sleeve and the outer sleeve that set up, rotatory inner sleeve control second water inlet and the size of first water inlet coincidence area come to control into the velocity of flow.

5. The matching of the caulking groove and the rotating ball facilitates the adjustment of the water inlet and injection direction.

Drawings

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

FIG. 2 is an internal view of the fermentation tank of the present invention;

FIG. 3 is an enlarged view of A in FIG. 2 according to the present invention;

FIG. 4 is a view of the combination of the elevating height observation assembly and the frame;

FIG. 5 is a view of the combination of the rotary ball and the outer sleeve of the present invention;

fig. 6 is a combination view of the inner sleeve and the annular fixture block of the present invention.

In the figure: 1. a fermentation tank; 101. a first can shell; 102. a thermal insulation cavity; 103. a second can shell; 104. an electrothermal film; 2. a motor; 3. a feed inlet; 4. a frame; 5. a connecting rod; 6. a hydraulic lift cylinder; 7. a lifting height observation assembly; 701. a loop bar; 702. a lifting groove; 703. a lifting rod; 704. a first scale; 8. a water inlet connection assembly; 801. caulking grooves; 802. rotating the ball; 803. an outer sleeve; 804. an inner sleeve; 805. an annular fixture block; 806. a first water inlet; 807. a second scale; 808. a second water inlet; 9. a stirring shaft; 10. stirring blades; 11. and (7) a water outlet.

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.

Referring to fig. 1 to 6, the present invention provides a technical solution:

a bacterial liquid culture system with a heating structure is shown in figures 1 and 2 and comprises a fermentation tank 1, wherein a motor 2 is fixedly connected to the center of the top end of the fermentation tank 1, and a stirring shaft 9 is fixedly connected to the output end of the motor 2. The bottom end of the stirring shaft 9 penetrates through the fermentation tank 1, and a stirring blade 10 is fixed on the outer side surface of the stirring shaft 9. The stirring blade 10 and the stirring shaft 9 are driven by the motor 2 to rotate to stir the bacteria liquid in the fermentation tank 1. One side of the top end of the fermentation tank 1 is fixedly connected with a feed inlet 3, and the fermentation tank 1 comprises a first tank shell 101 and a second tank shell 103 positioned in the first tank shell 101. A heat insulation cavity 102 is arranged between the first tank shell 101 and the second tank shell 103, an electric heating film 104 is fixedly connected to the outer side surface of the second tank shell 103 and used for heating the bacteria liquid, and a water outlet 11 is fixedly connected to the center of the bottom end of the fermentation tank 1 and used for discharging the bacteria liquid. The other side of the top end of the fermentation tank 1 is provided with a water inlet connecting assembly 8 for adjusting the water inlet flow and the injection direction. The outer side surface of the fermentation tank 1 is provided with a lifting adjusting component for adjusting the height of the fermentation tank 1 so as to take out the cultured bacteria. The water inlet connecting assembly 8 can adjust the water inlet flow speed and the injection direction, and further can quickly and effectively clean the inner wall of the fermentation device. The height of the fermentation tank 1 can be quickly and accurately adjusted through the arranged lifting adjusting assembly, so that bacteria after culture can be taken out conveniently.

As shown in figure 1, the lifting adjusting component comprises a plurality of connecting rods 5, the connecting rods 5 are uniformly and fixedly connected to the outer side surface of the fermentation tank 1, and the bottom ends of the connecting rods 5 are fixedly connected with hydraulic lifting cylinders 6. The bottom edge of the fermentation tank 1 is fixedly connected with a frame 4, and one side of the bottom end of the frame 4 is fixedly connected with a lifting height observation assembly 7. The hydraulic lifting cylinder 6 is connected with an external hydraulic oil station to control the lifting of the connecting rod 5.

As shown in fig. 4, the elevation height observation unit 7 includes an elevation rod 703, and a top end of the elevation rod 703 is fixed to a side of a bottom end of the frame 4. The bottom end of the lifting rod 703 is movably connected with a loop bar 701, and the top end of the loop bar 701 is provided with a lifting groove 702. The bottom end of the lifting rod 703 is movably connected inside the lifting groove 702, and a first scale 704 is arranged on one side surface of the lifting rod 703. The first scale 704 is provided to facilitate the staff to observe the specific height of the lifting rod 703 in the lifting groove 702.

As shown in fig. 3, fig. 5 and fig. 6, the water inlet connecting assembly 8 includes a rotating ball 802, and the rotating ball 802 is movably inserted into an insertion groove 801 formed at the top end of the fermentation tank 1. An outer sleeve 803 is fixedly connected inside the rotating ball 802, and an inner sleeve 804 is arranged inside the outer sleeve 803. The bottom end of the outer sleeve 803 is provided with a first water inlet 806, and the bottom end of the inner sleeve 804 is provided with a second water inlet 808 matched with the first water inlet 806. The flow rate of the inlet water is controlled by controlling the size of the area of the second water inlet 808 coinciding with the first water inlet 806. An annular clamping block 805 is fixedly connected to the outer side surface of the inner sleeve 804, and the annular clamping block 805 is movably embedded in an annular clamping groove formed in the inner side surface of the outer sleeve 803. The annular fixture blocks 805 and the annular fixture grooves are arranged to prevent the inner sleeve 804 from being separated from the outer sleeve 803. The top end of the rotating ball 802 and the top edge of the outer sleeve 803 are provided with a second scale 807. The second scale 807 is set to facilitate the staff to accurately control the size of the overlapping area of the second water inlet 808 and the first water inlet 806.

As shown in FIG. 1, a cover is detachably and fixedly connected to the top end of the feed port 3. The setting of lid avoids external impurity to get into fermentation cylinder 1 through feed inlet 3.

The working principle is as follows: when the bacterial liquid culture system with the heating structure is used, firstly, an external water pipe is connected with the inner sleeve 804 of the water inlet connecting assembly 8, and water is injected into the fermentation tank 1. Then, the strain and the nutrient solution are injected into the fermentation tank 1 through the feed port 3. And finally, starting the electric heating film 104 on the second tank shell 103 to heat the bacteria liquid, and operating the motor 2 to drive the stirring shaft 9 and the stirring blade 10 to stir the bacteria liquid. At this time, the strain can be fermented. The thermal insulation cavity 102 between the first tank shell 101 and the second tank shell 103 effectively prevents heat from passing through during production.

After the bacteria culture is finished, the worker takes out the cultured bacteria liquid through the water outlet 11. At this moment, staff's accessible lift adjustment subassembly can be fast accurate adjust fermentation cylinder 1's height, and then be convenient for take out the bacterium fungus liquid after the cultivation. The method specifically comprises the following steps: the hydraulic lifting cylinder 6 is started to drive the fermentation tank 1 to ascend, so that the height of the water outlet 11 rises, and the worker can open the water outlet 11 to take out the bacteria liquid conveniently. In the ascending process, the worker can also observe the ascending and descending height accurately through the ascending and descending height observing assembly 7. The method specifically comprises the following steps: the fermentation tank 1 is lifted to drive the frame 4 to lift, the frame 4 is lifted to drive the lifting rod 703 to lift in the lifting groove 702, and the worker observes the first scale 704 value exposed out of the lifting groove 702 to know the specific height of the lifting. After the use, the staff need wash fermentation cylinder 1 inner wall. In the cleaning process, staff's accessible inlet coupling assembling 8 adjusts the velocity of flow of intaking and jets out the direction, and then carries out quick effectual washing to 1 inner wall of fermentation cylinder. The method specifically comprises the following steps: the inner rotating sleeve 804 controls the overlapping area of the second water inlet 808 and the first water inlet 806 to control the water inflow flow rate, and the water inflow and outflow direction is adjusted by the angle of the rotating ball 802 in the rotating caulking groove 801. The inner wall of the fermentation tank 1 is flushed in an all-round way by adopting high-flow-rate water flow, so that the cleaning degree is improved. In this embodiment, the motor 2 is 42CM06, and the hydraulic lift cylinder 6 is MOB50 × 100.

The utility model discloses a first tank 101, heat-insulating chamber 102, second tank 103 and electric heat membrane 104 all adopt the prior art who discloses in the background art, so do not explain in detail.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a fungus liquid culture system with structure of heating which characterized in that: including the fermentation cylinder, the top center fixedly connected with motor of fermentation cylinder, and the output fixedly connected with (mixing) shaft of motor, the (mixing) shaft bottom runs through the fermentation cylinder, and the (mixing) shaft lateral surface is fixed with the stirring leaf, top one side fixedly connected with feed inlet of fermentation cylinder, and the fermentation cylinder includes first shell and the second shell that is located first shell, be equipped with the heat-insulating chamber between first shell and the second shell, and the lateral surface fixedly connected with electric heat membrane of second shell, fermentation cylinder bottom center fixedly connected with delivery port, the top opposite side of fermentation cylinder is equipped with into water coupling assembling and is used for adjusting the inflow and kicks into the direction, and is equipped with the bacterium after highly being convenient for take out the cultivation that lift adjustment subassembly is used for adjusting the fermentation cylinder on the fermentation cylinder lateral surface.

2. The bacterial liquid culture system with the warming structure according to claim 1, wherein: the lifting adjusting assembly comprises a plurality of connecting rods, the connecting rods are uniformly and fixedly connected to the outer side face of the fermentation tank, the bottom ends of the connecting rods are fixedly connected with a hydraulic lifting cylinder, the bottom end of the fermentation tank is fixedly connected with a frame along the edge, and one side of the bottom end of the frame is fixedly connected with a lifting height observing assembly.

3. The bacterial liquid culture system with the warming structure according to claim 2, wherein: the lifting height observation assembly comprises a lifting rod, the top end of the lifting rod is fixed on one side of the bottom end of the frame, the bottom end of the lifting rod is movably connected with a loop bar, a lifting groove is formed in the top end of the loop bar, the bottom end of the lifting rod is movably connected inside the lifting groove, and a side face of the lifting rod is provided with first scales.

4. The bacterial liquid culture system with the warming structure according to claim 1, wherein: the inlet connection subassembly includes the roating ball, and the roating ball inlays movably in the caulking groove of seting up on the fermentation cylinder top, the inside fixedly connected with outer sleeve of roating ball, and the inside inner skleeve that is equipped with of outer sleeve, first water inlet has been seted up to the outer sleeve bottom, the inner skleeve bottom seted up with first water inlet assorted second water inlet.

5. The bacteria liquid culture system with heating structure of claim 4, characterized in that: the outer side surface of the inner sleeve is fixedly connected with an annular clamping block, and the annular clamping block is movably embedded in an annular clamping groove formed in the inner side surface of the outer sleeve.

6. The bacteria liquid culture system with heating structure of claim 4, characterized in that: and second scales are arranged at the top end of the rotary ball and the edge of the top end of the outer sleeve.

7. The bacterial liquid culture system with the warming structure according to claim 1, wherein: the top end of the feed inlet is detachably and fixedly connected with a cover.

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