CN217297857U - Cultivation speed controllable microbial plant restoration experimental device - Google Patents

Abstract

The utility model provides a cultivation speed controllable microorganism phytoremediation experimental apparatus. The microorganism plant restoration experimental apparatus with controllable cultivation speed comprises: an experimental box; the top end of the liquid discharge pipe is arranged at the bottom of the experiment box; and the surface of the storage tube is fixedly arranged on the outer surface of the experimental box. The utility model provides a cultivate controllable microorganism phytoremediation experimental apparatus of speed, conveniently supply nutrient solution and moisture to the inside of experimental box through first feed subassembly and second feed subassembly, when supplying nutrient solution and moisture, the piston ring absorbs the unnecessary nutrient solution part of experimental box inside simultaneously, the dose of the nutrient solution of maintaining experimental box inside, so that to the allotment of different concentration nutrient solution, the allotment of the nutrient solution concentration of thing restoration experimentation in-process is put to the microorganism to the convenience, keep the invariant of the inside nutrient solution dose of experimental box, thereby the speed of conveniently cultivating is controlled.

Description

Cultivation speed controllable microbial plant restoration experimental device

Technical Field

The utility model relates to an experimental facilities technical field especially relates to a cultivate controllable microbial plants restoration experimental apparatus of speed.

Background

With the continuous development and progress of science and technology of people, the research and development of microorganisms are continuously advanced, the microorganisms are difficult to see by naked eyes, the microorganisms are a general term of all microorganisms which can be observed by an optical microscope or an electron microscope, the microorganisms comprise bacteria, viruses, fungi, a few algae and the like, but some microorganisms can be seen by naked eyes, such as mushrooms, lucid ganoderma and the like belonging to fungi, the viruses are non-cell organisms consisting of a few components such as nucleic acid, protein and the like, but the viruses have to live on living cells, are divided into space microorganisms, marine microorganisms and the like according to the existing different environments, and are divided into prokaryotic microorganisms and eukaryotic microorganisms according to the cell structure.

In order to enhance the understanding and research of microorganisms, the microorganisms need to be cultured autonomously, the microbial phytoremediation is completed through the growth of the microorganisms, so as to judge the optimal environment for the propagation and growth of the microorganisms, and a microbial phytoremediation experimental device is needed in the experimental process.

In prior art, current microbial plant restores experimental apparatus when installation and use, the concentration of the inside nutrient solution of experimental facilities is inconvenient to be adjusted under the invariable environment of dose, because the produced effect of the nutrient solution of different concentrations is different with the speed of cultivateing, can only be equipped with the nutrient solution in advance in the external world of experimental facilities before the cultivation, inconvenient regulation that carries out the concentration according to the user demand in the inside of experimental box.

Therefore, it is necessary to provide a experimental apparatus for repairing microorganism plants with controllable cultivation speed to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a cultivate controllable microbial plants restoration experimental apparatus of speed has solved the problem of the inconvenient regulation of the inside nutrient solution concentration of experimental box.

In order to solve the technical problem, the utility model provides a controllable microbial plant of cultivation speed restores experimental apparatus, include: an experimental box; the top end of the liquid discharge pipe is arranged at the bottom of the experiment box; the surface of the storage tube is fixedly arranged on the outer surface of the experiment box, the inner side of the storage tube is provided with a suction hole, the top of the storage tube is provided with a connecting hole, and a piston ring is arranged in the storage tube in a sliding manner; the bottom of the first feeding assembly is mounted at the top of the storage pipe, and the first feeding assembly comprises a barrel body, a feeding pipe, a conveying pump and a piston plate; the top of the spraying mechanism is arranged on the inner surface of the experimental box; a second feed assembly, the bottom of which is mounted to the top of the storage tube; the bottom of the limiting pipe is arranged on the inner surface of the experiment box, and an ascending hole and a circulating hole are formed in the limiting pipe; the adjustable motor, adjustable motor's top install in the bottom of experimental box, the transport auger is installed to adjustable motor's output, the linkage disk is installed on the top of carrying the auger, the connecting rod is installed to the bottom of linkage disk, the fixed surface of connecting rod is connected with the puddler.

Preferably, the interior of the suction hole is communicated with the interior of the experiment box, the drain pipe is provided with a control valve, and the input end of the drain pipe is communicated with the interior of the experiment box.

Preferably, the bottom of the tub is mounted to the top of the storage pipe, and the inside of the tub communicates with the inside of the connection hole.

Preferably, the output end of the feeding pipe is arranged on the barrel body, the feeding pipe is provided with a control valve, and the output end of the feeding pipe is communicated with the inside of the barrel body.

Preferably, the bottom end of the delivery pump is mounted at the top of the barrel body, the input end of the delivery pump is communicated with the interior of the barrel body, the output end of the delivery pump penetrates through the surface of the experiment box and extends to the interior of the experiment box, the output end of the delivery pump is fixedly connected with the input end of the spraying mechanism, and the surface of the piston plate is in sliding connection with the inner surface of the feeding pipe.

Preferably, the structure of the second feeding assembly is the same as that of the first feeding assembly, and the second feeding assembly and the first feeding assembly are symmetrically arranged at two sides of the experimental box.

Preferably, the ascending hole is positioned below the circulating hole, the outer surface of the conveying auger is in sliding connection with the inner surface of the limiting pipe, and the lower surface of the linkage disk is movably connected with the top of the limiting pipe.

Preferably, a contraction groove is formed in the limiting pipe, the inside of the contraction groove is communicated with the inside of the uplink hole, an expansion piece is fixedly mounted on the inner wall of the contraction groove, a sealing ring is fixedly mounted at the output end of the expansion piece, the surface of the sealing ring is in sliding connection with the inner surface of the contraction groove, and the size of the sealing ring is matched with the size of the uplink hole.

Compared with the prior art, the utility model provides a controllable microorganism phytoremediation experimental apparatus of cultivation speed has following beneficial effect:

the utility model provides a cultivate controllable microorganism phytoremediation experimental apparatus of speed, conveniently supply nutrient solution and moisture to the inside of experimental box through first feed subassembly and second feed subassembly, when supplying nutrient solution and moisture, the piston ring absorbs the inside unnecessary nutrient solution part of experimental box simultaneously, the dose of the nutrient solution of maintenance experimental box inside, so that to the allotment of different concentration nutrient solutions, the allotment of the nutrient solution concentration of thing restoration experimentation in-process is put to the microorganism to the convenience, keep the invariant of the inside nutrient solution dose of experimental box, thereby the speed of conveniently cultivating is controlled.

Drawings

FIG. 1 is a schematic structural diagram of a first embodiment of an experimental apparatus for repairing a microorganism with controllable cultivation speed according to the present invention;

FIG. 2 is a three-dimensional view of the storage tube portion shown in FIG. 1;

FIG. 3 is a cross-sectional view of the entirety shown in FIG. 2;

FIG. 4 is a schematic view of the overall structure shown in FIG. 1;

FIG. 5 is a schematic structural diagram of a second embodiment of an experimental apparatus for repairing a microorganism with a controllable cultivation speed according to the present invention;

fig. 6 is an enlarged schematic view of the portion a shown in fig. 5.

Reference numbers in the figures:

1. an experimental box;

2. a liquid discharge pipe;

3. a storage tube 31, a suction hole 32, a connecting hole 33 and a piston ring;

4. a first feeding assembly 41, a barrel body 42, a feeding pipe 43, a conveying pump 44 and a piston plate;

5. a spraying mechanism;

6. a second feed assembly;

7. a limiting pipe 71, an ascending hole 72, a circulating hole 73 and a contraction groove;

8. the device comprises an adjusting motor 81, a conveying auger 82, a linkage disc 83, a connecting rod 84 and a stirring rod;

9. telescoping piece, 91, sealing ring.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

The first embodiment:

please refer to fig. 1, fig. 2, fig. 3 and fig. 4, in which fig. 1 is a schematic structural diagram of a first embodiment of an experimental apparatus for repairing a microbial plant with a controllable cultivation speed according to the present invention; FIG. 2 is a three-dimensional view of the storage tube portion shown in FIG. 1; FIG. 3 is a cross-sectional view of the entirety shown in FIG. 2; fig. 4 is a schematic view of the overall structure shown in fig. 1.

A microorganism plant restoration experimental device with controllable cultivation speed comprises: an experimental box 1; a liquid discharge pipe 2, wherein the top end of the liquid discharge pipe 2 is installed at the bottom of the experiment box 1; the surface of the storage tube 3 is fixedly arranged on the outer surface of the experiment box 1, the inner side of the storage tube 3 is provided with a suction hole 31, the top of the storage tube 3 is provided with a connecting hole 32, and a piston ring 33 is arranged in the storage tube 3 in a sliding manner; a first feed assembly 4, the bottom of the first feed assembly 4 being mounted on the top of the storage pipe 3, the first feed assembly 4 comprising a barrel 41, a feed pipe 42, a transfer pump 43 and a piston plate 44; the top of the spraying mechanism 5 is arranged on the inner surface of the experimental box 1; a second feeding assembly 6, wherein the bottom of the second feeding assembly 6 is arranged at the top of the storage pipe 3; the bottom of the limiting pipe 7 is mounted on the inner surface of the experiment box 1, and an ascending hole 71 and a circulating hole 72 are formed in the limiting pipe 7; adjusting motor 8, adjusting motor 8's top install in the bottom of experimental box 1, the transport auger 81 is installed to adjusting motor 8's output, carry the top of auger 81 to install linkage disk 82, connecting rod 83 is installed to linkage disk 82's bottom, the outer fixed surface of connecting rod 83 is connected with puddler 84.

Through first feed subassembly 4 and 6 convenient inside supplementary nutrient solution and moisture to experimental box 1 of second feed subassembly, during supplementary nutrient solution and moisture, piston ring 33 absorbs experimental box 1 inside unnecessary nutrient solution part simultaneously, maintain the dose of experimental box 1 inside nutrient solution, so that to the allotment of different concentration nutrient solutions, the allotment of the nutrient solution concentration in the experiment process is restoreed to the convenient thing of putting to the microorganism, keep the invariant of experimental box 1 inside nutrient solution dose, thereby the speed of conveniently cultivating is controlled.

The conveying auger 81 at the output end of the adjusting motor 8 is matched with the limiting pipe 7 to conveniently carry out circulating turbulence on the culture solution in the experiment box 1, so that the culture solution can be fully stirred, microbial plants are fully mixed and contacted with the nutrient solution, and the cultivation speed is controlled;

the conveying auger 81 can circularly flow the nutrient solution at the bottom to the position above the liquid level through the ascending hole 71 and the circulating hole 72 on the limiting pipe 7 to form uniform flow, so that the distribution of the nutrient solution is more uniform and reliable.

The conveying auger 81 can drive the stirring rod 84 to rotate while rotating, so that the power consumption is reduced, and an independent power source is not required for a stirring structure.

The interior of the sucking hole 31 is communicated with the interior of the experimental box 1, the liquid discharge pipe 2 is provided with a control valve, and the input end of the liquid discharge pipe 2 is communicated with the interior of the experimental box 1.

The liquid discharge pipe 2 is used for discharging nutrient solution and microorganisms after the experiment.

The bottom of the tub 41 is mounted on the top of the storage tube 3, and the inside of the tub 41 and the inside of the connection hole 32 communicate with each other.

The output end of the feeding pipe 42 is installed on the barrel body 41, and a control valve is installed on the feeding pipe 42, and the output end of the feeding pipe 42 is communicated with the inside of the barrel body 41.

The bottom end of the delivery pump 43 is mounted on the top of the barrel 41, the input end of the delivery pump 43 is communicated with the interior of the barrel 41, the output end of the delivery pump 43 penetrates the surface of the experimental box 1 and extends to the interior of the experimental box 1, the output end of the delivery pump 43 is fixedly connected with the input end of the spraying mechanism 5, and the surface of the piston plate 44 is slidably connected with the inner surface of the feeding pipe 42.

The structure of the second feeding assembly 6 is the same as that of the first feeding assembly 4, and the second feeding assembly 6 and the first feeding assembly 4 are symmetrically arranged at two sides of the experimental box 1.

The first feeding assembly 4 and the second feeding assembly 6 are used for conveying two different raw materials to the spraying mechanism 5, and the spraying mechanism 5 uniformly sprays the raw materials in the inner part of the experimental box 1.

The ascending hole 71 is positioned below the circulating hole 72, the outer surface of the conveying auger 81 is in sliding connection with the inner surface of the limiting pipe 7, and the lower surface of the linkage disc 82 is movably connected with the top of the limiting pipe 7.

The utility model provides a cultivation speed controllable microorganism phytoremediation experimental apparatus's theory of operation as follows:

when the nutrient solution in the experiment box 1 needs to be regulated, the first feeding component 4 is started;

the conveying pump 43 pumps the raw materials in the barrel body 41 to convey the raw materials to the interior of the spraying mechanism 5, the piston plate 44 slides upwards, the piston plate 44 drives the piston ring 33 to slide upwards, and when the piston ring 33 moves upwards, the nutrient solution in the experiment box 1 is extracted through the suction hole 31, so that the concentration of the internal nutrient solution is adjusted;

when the device works, the adjusting motor 8 is started, the adjusting motor 8 drives the conveying auger 81 to rotate, and the conveying auger 81 drives the nutrient solution in the limiting pipe 7 to be circularly conveyed upwards;

meanwhile, the conveying auger 81 drives the linkage disc 82 to rotate, the linkage disc 82 drives the stirring rod 84 to rotate through the connecting rod 83, and the stirring rod 84 drives the nutrient solution on the inner side to be mixed and stirred.

Compared with the prior art, the utility model provides a controllable microorganism phytoremediation experimental apparatus of cultivation speed has following beneficial effect:

through first feed subassembly 4 and 6 convenient inside supplementary nutrient solution and moisture to experimental box 1 of second feed subassembly, during supplementary nutrient solution and moisture, piston ring 33 absorbs experimental box 1 inside unnecessary nutrient solution part simultaneously, maintain the dose of experimental box 1 inside nutrient solution, so that to the allotment of different concentration nutrient solutions, the allotment of the nutrient solution concentration in the experiment process is restoreed to the convenient thing of putting to the microorganism, keep the invariant of experimental box 1 inside nutrient solution dose, thereby the speed of conveniently cultivating is controlled.

Second embodiment:

referring to fig. 5 and fig. 6, based on the experimental apparatus for repairing a microorganism with a controllable cultivation speed provided in the first embodiment of the present application, the second embodiment of the present application provides another experimental apparatus for repairing a microorganism with a controllable cultivation speed. The second embodiment is only the preferred mode of the first embodiment, and the implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, the difference of the experimental apparatus for repairing a microorganism with a controllable cultivation speed provided by the second embodiment of the present application lies in that the experimental apparatus for repairing a microorganism with a controllable cultivation speed further includes:

the limiting pipe 7 is provided with a contraction groove 73, the inside of the contraction groove 73 is communicated with the inside of the upward hole 71, an expansion piece 9 is fixedly mounted on the inner wall of the contraction groove 73, a sealing ring 91 is fixedly mounted at the output end of the expansion piece 9, the surface of the sealing ring 91 is in sliding connection with the inner surface of the contraction groove 73, and the size of the sealing ring 91 is matched with the size of the upward hole 71.

Conveniently drive sealing ring 91 through extensible member 9 and carry out lift adjustment, when sealing ring 91 rose, the hole 71 that goes up was opened, evenly stir when the inside culture solution of experimental box 1 can upper and lower circulation flow, when sealing ring 91 descends, the hole 71 that goes up was closed, the inside culture solution of experimental box 1 can stir alone and handle to the convenience is adjusted the mixed degree of culture solution according to the demand that uses, satisfies the demand that the culture speed under the different environment was adjusted.

The extensible member 9 adopts hydraulic telescoping rod, is equipped with hydraulic equipment and controlgear during the use, does water repellent during the installation, ensures the stability of extensible member 9 installation use.

The utility model provides a theory of operation of second embodiment:

when the conveying auger part needs to be used, the telescopic piece 9 is started, the telescopic piece 9 drives the sealing ring 91 to move upwards, the sealing ring 91 moves upwards to the inside of the contraction groove 73, and the ascending hole 71 is opened;

when the adjusting motor 8 is started, the adjusting motor 8 drives the conveying auger 81 to rotate, and simultaneously, the conveying auger 81 drives the culture solution to be conveyed from bottom to top to form circular flow;

the conveying auger 81 drives the linkage disc 82 to rotate, the linkage disc 82 drives the connecting rod 83 to rotate when rotating, and the connecting rod 83 drives the stirring rod 84 to rotate, so that the culture solution is stirred and mixed while circulating flow is formed, and the culture solution is in contact with the microbial plant components;

when the conveying auger part is not needed, the expansion piece 9 is started, the expansion piece 9 drives the sealing ring 91 to move downwards, the sealing ring 91 is unfolded and closed to shield the ascending hole 71, and only the stirring rod 84 can stir the culture solution.

The utility model provides a beneficial effect of second embodiment:

conveniently drive sealing ring 91 through extensible member 9 and carry out lift adjustment, when sealing ring 91 rose, the hole 71 that goes up was opened, evenly stir when the inside culture solution of experimental box 1 can upper and lower circulation flow, when sealing ring 91 descends, the hole 71 that goes up was closed, the inside culture solution of experimental box 1 can stir alone and handle to the convenience is adjusted the mixed degree of culture solution according to the demand that uses, satisfies the demand that the culture speed under the different environment was adjusted.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a cultivation speed controllable microorganism phytoremediation experimental apparatus which characterized in that includes:

an experimental box;

the top end of the liquid discharge pipe is arranged at the bottom of the experiment box;

the surface of the storage tube is fixedly arranged on the outer surface of the experiment box, the inner side of the storage tube is provided with a suction hole, the top of the storage tube is provided with a connecting hole, and a piston ring is arranged in the storage tube in a sliding manner;

the bottom of the first feeding assembly is mounted at the top of the storage pipe, and the first feeding assembly comprises a barrel body, a feeding pipe, a conveying pump and a piston plate;

the top of the spraying mechanism is arranged on the inner surface of the experimental box;

a second feed assembly, the bottom of the second feed assembly being mounted to the top of the storage tube;

the bottom of the limiting pipe is arranged on the inner surface of the experiment box, and an ascending hole and a circulating hole are formed in the limiting pipe;

the adjusting motor, the top of adjusting motor install in the bottom of experimental box, the transport auger is installed to the output of adjusting motor, the linkage disk is installed on the top of carrying the auger, the connecting rod is installed to the bottom of linkage disk, the outer fixed surface of connecting rod is connected with the puddler.

2. The experimental device for repairing a microorganism with a controllable cultivation speed as claimed in claim 1, wherein the interior of the sucking hole is communicated with the interior of the experimental box, the drain pipe is provided with a control valve, and the input end of the drain pipe is communicated with the interior of the experimental box.

3. The experimental apparatus for repairing a microorganism with a controlled cultivation speed as claimed in claim 1, wherein the bottom of the bucket is installed at the top of the storage tube, and the inside of the bucket is communicated with the inside of the connection hole.

4. The experimental apparatus for repairing microorganism with controllable cultivation speed as claimed in claim 3, wherein the output end of the feeding pipe is installed on the barrel body, and a control valve is installed on the feeding pipe, and the output end of the feeding pipe is communicated with the inside of the barrel body.

5. The experimental apparatus for repairing a microorganism with a controllable cultivation speed as claimed in claim 4, wherein the bottom end of the delivery pump is installed on the top of the barrel, the input end of the delivery pump is communicated with the inside of the barrel, the output end of the delivery pump penetrates through the surface of the experimental box and extends to the inside of the experimental box, the output end of the delivery pump is fixedly connected with the input end of the spraying mechanism, and the surface of the piston plate is slidably connected with the inner surface of the feeding pipe.

6. The experimental apparatus for repairing a microorganism with a controllable incubation speed as claimed in claim 1, wherein the second feeding module has the same structure as the first feeding module, and the second feeding module and the first feeding module are symmetrically installed at both sides of the experimental box.

7. The experimental device for repairing microorganism plants with controllable cultivation speed as claimed in claim 1, wherein the ascending hole is located below the circulation hole, the outer surface of the conveying auger is slidably connected with the inner surface of the limiting pipe, and the lower surface of the linkage disk is movably connected with the top of the limiting pipe.

8. The experimental apparatus for repairing a microorganism with a controllable cultivation speed as claimed in claim 1, wherein the limiting pipe is provided with a shrinking groove, the inside of the shrinking groove is communicated with the inside of the ascending hole, an expansion member is fixedly mounted on the inner wall of the shrinking groove, a sealing ring is fixedly mounted on the output end of the expansion member, the surface of the sealing ring is slidably connected with the inner surface of the shrinking groove, and the size of the sealing ring is matched with the size of the ascending hole.

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