CN215975809U - Deodorizing device for autotrophic microorganisms - Google Patents

Abstract

The utility model discloses a deodorizing device for autotrophic microorganisms, relates to the field of microorganism culture, and aims to solve the problems that in the prior art, the temperature of autotrophic microorganisms in a culture dish is too high in the culture process, and odor generated in the internal gas is inconvenient to discharge in the long-term experimental culture process. The scavenger fan is installed to the top of device casing, just active carbon deodorization layer is installed to the inside top of device casing, the filter core is installed to the below of active carbon deodorization layer, the connecting sleeve is installed to the lower extreme of device casing, the microorganism culture dish is installed to the lower extreme of connecting sleeve, the upset cooling plate is all installed to the both sides of device casing, the inboard of upset cooling plate is provided with the cooling plate, the cooling plate laminates with the microorganism culture dish, just one side of cooling plate extends to the cooling water and deposits intracavity portion and upset cooling plate sealing connection, the internally mounted of cooling plate has the circulative cooling pipe.

Description

Deodorizing device for autotrophic microorganisms

Technical Field

The utility model relates to the technical field of microorganism culture, in particular to a deodorizing device for autotrophic microorganisms.

Background

Autotrophic microorganisms are microorganisms that use carbon dioxide as a main or sole carbon source and inorganic nitrides as a nitrogen source to obtain energy through bacterial photosynthesis or chemosynthesis. Autotrophic microorganisms are increasingly emphasized by people due to the practical application of the autotrophic microorganisms in the aspects of agricultural production, energy development, metallurgy, mining and the like and the importance of the autotrophic microorganisms in the aspects of theoretical research of energy production metabolism, molecular genetics and the like, and the experiment takes nitrifying bacteria as a representative and introduces the separation and purification of the chemoautotrophic microorganisms.

In the existing autotrophic microorganism culture process, the temperature in a culture dish is overhigh, and odor generated by internal gas is inconvenient to discharge in the long-term experimental culture process; therefore, there is an urgent need in the market to develop a deodorizing device for autotrophic microorganisms to help people solve the existing problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a deodorizing device for autotrophic microorganisms, and aims to solve the problems that in the prior art, the temperature in a culture dish is too high during the culture process of the autotrophic microorganisms, and the odor generated in the internal gas during the long-term experimental culture process is inconvenient to exhaust.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a deodorizing device for autotrophic microorganism, includes the device casing, the scavenger fan is installed to the top of device casing, just activated carbon deodorization layer is installed to the inside top of device casing, the filter core is installed to the below of activated carbon deodorization layer, connecting sleeve is installed to the lower extreme of device casing, microorganism culture dish is installed to connecting sleeve's lower extreme, the upset cooling plate is all installed to the both sides of device casing, the inboard of upset cooling plate is provided with the cooling plate, the laminating of cooling plate and microorganism culture dish, the inside of upset cooling plate is provided with the cooling water and deposits the chamber, just one side of cooling plate extends to the cooling water and deposits intracavity portion and upset cooling plate sealing connection, the internally mounted of cooling plate has the cooling pipe that circulates.

Preferably, the lower end of the ventilation fan extends into the device shell and is hermetically connected with the device shell, an exhaust fan is installed in the ventilation fan, and a filter screen is installed on the upper end face of the ventilation fan.

Preferably, the outer surface mounting of device casing has the temperature display screen, the lower extreme of temperature display screen is provided with shift knob, the internally mounted of device casing has temperature and humidity sensor, and temperature and humidity sensor and temperature display screen electric connection.

Preferably, the internally mounted of connecting sleeve has sealed splint, sealed splint pass through screw thread and microorganism culture dish fixed connection, just the internal surface mounting of sealed splint has the seal cushion, just sealed splint pass through seal cushion and microorganism culture dish sealing connection.

Preferably, connecting sleeve is installed to the upper end of upset cooling plate, connecting sleeve's inside is run through there is the connecting axle, connecting axle and connecting sleeve fixed connection, just spacing bearing is all installed to the both sides of device casing, just the one end of connecting axle is passed through spacing bearing and is connected with the rotation of device casing, the protection casing is installed to the rear end of upset cooling plate, the internally mounted of protection casing has step motor, the other end of connecting axle extends to the protection casing inside and is connected with the protection casing rotation, step motor passes through the hold-in range and is connected with the connecting axle transmission.

Preferably, circulating pumps are installed at the upper end and the lower end of the inside of the turnover cooling plate, and the two circulating pumps are respectively in sealing connection with the two ends of the circulating cooling pipe.

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

the utility model is connected with the device shell through the connecting sleeve and the sealing splint, thereby sealing the device shell and the microorganism culture dish, after sealing, sensing the temperature and the humidity inside the microorganism culture dish according to the temperature and the humidity sensor inside the device shell, driving the overturning cooling plate to overturn through the singlechip control stepping motor, leading the cooling plate to be tightly attached with the microorganism culture dish, leading the cooling liquid inside the cooling water storage cavity into the circulating cooling pipe through the circulating pump, thereby reducing the surface temperature of the cooling plate, reducing the temperature of the outer surface of the microorganism culture dish through the cooling plate, reducing the environmental temperature of the autotrophic microorganisms inside the microorganism culture dish, achieving the best culture effect, leading the air after the autotrophic microorganisms are cultured into the device shell through the ventilating fan, absorbing the odor gas through the filter element and the active carbon deodorization layer, thereby avoiding the gas pollution environment generated by autotrophic microorganism cultivation, improving the working quality, having simple structure, convenient installation and disassembly and being suitable for different working environments.

Drawings

Fig. 1 is an overall schematic view of the present invention.

Fig. 2 is an internal structural view of the present invention.

Fig. 3 is an internal structural view of the protection cover and the turnover cooling plate of the present invention.

In the figure: 1. a device housing; 2. a ventilator; 3. a filter screen; 4. a temperature display screen; 5. a switch button; 6. a protective cover; 7. turning over the cooling plate; 8. a connecting sleeve; 9. a connecting shaft; 10. a cooling plate; 11. a connecting sleeve; 12. a microorganism culture dish; 13. a limit bearing; 14. an exhaust fan; 15. an activated carbon deodorizing layer; 16. a filter element; 17. sealing the clamping plate; 18. a stepping motor; 19. a circulating cooling pipe; 20. a cooling water storage cavity; 21. and a circulating pump.

Detailed Description

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

Referring to fig. 1-3, an embodiment of the present invention is shown: a deodorizing device for autotrophic microorganisms comprises a device shell 1, a ventilating fan 2 is installed above the device shell 1, an active carbon deodorizing layer 15 is installed above the interior of the device shell 1, a filter element 16 is installed below the active carbon deodorizing layer 15, a connecting sleeve 11 is installed at the lower end of the device shell 1, a microorganism culture dish 12 is installed at the lower end of the connecting sleeve 11, turnover cooling plates 7 are installed on two sides of the device shell 1, a cooling plate 10 is arranged on the inner side of the turnover cooling plate 7, the cooling plate 10 is attached to the microorganism culture dish 12, a cooling water storage cavity 20 is arranged inside the turnover cooling plate 7, one side of the cooling plate 10 extends into the cooling water storage cavity 20 and is hermetically connected with the turnover cooling plate 7, a circulating cooling pipe 19 is installed inside the cooling plate 10, cooling liquid in the cooling water storage cavity 20 is guided into the circulating cooling pipe 19 through a circulating pump 21, so that the temperature of the surface of the cooling plate 10 is lowered, and the temperature of the outer surface of the microorganism culture dish 12 is lowered through the cooling plate 10, so that the environmental temperature of autotrophic microorganisms inside the microorganism culture dish 12 is lowered, and the optimal cultivation effect is achieved.

Further, the lower extreme of scavenger fan 2 extends to the inside and device casing 1 sealing connection of device casing 1, and the internally mounted of scavenger fan 2 has extraction fan 14, and the up end of scavenger fan 2 installs filter screen 3, inside scavenger fan 2 can be with the air introduction device casing 1 after the autotrophy microorganism is cultivated, adsorbs smelly gas through filter core 16 and active carbon deodorization layer 15 to can avoid the gaseous polluted environment that the autotrophy microorganism was cultivated and produce, improve work quality.

Further, the outer surface of the device shell 1 is provided with a temperature display screen 4, the lower end of the temperature display screen 4 is provided with a switch button 5, the inside of the device shell 1 is provided with a temperature and humidity sensor, the temperature and humidity sensor is electrically connected with the temperature display screen 4, the temperature and the humidity inside the microorganism culture dish 12 can be sensed according to the temperature and humidity sensor inside the device shell 1 and displayed on the outer surface of the temperature display screen 4, and the temperature and humidity sensor is a PT-100 temperature and humidity sensor.

Further, the internally mounted of adapter sleeve 11 has sealed splint 17, and sealed splint 17 passes through screw thread and microorganism culture dish 12 fixed connection, and the interior surface mounting of sealed splint 17 has a seal cushion, and sealed splint 17 passes through seal cushion and microorganism culture dish 12 sealing connection, and accessible adapter sleeve 11 and sealed splint 17 are connected with device casing 1 to can seal device casing 1 and microorganism culture dish 12.

Further, connecting sleeve 8 is installed to the upper end of upset cooling plate 7, connecting sleeve 8's inside is run through there is connecting axle 9, connecting axle 9 and connecting sleeve 8 fixed connection, and install spacing bearing 13 in the both sides of device casing 1, and the one end of connecting axle 9 is passed through spacing bearing 13 and is connected with device casing 1 rotation, protection casing 6 is installed to the rear end of upset cooling plate 7, the internally mounted of protection casing 6 has step motor 18, the other end of connecting axle 9 extends to the inside and protection casing 6 rotation of protection casing 6 and is connected, step motor 18 passes through the hold-in range and is connected with the transmission of connecting axle 9, through single chip microcomputer control step motor 18, drive upset cooling plate 7 upset, make cooling plate 10 and microorganism culture dish 12 closely laminate.

Further, circulation pumps 21 are installed at the upper end and the lower end of the inside of the turnover cooling plate 7, the two circulation pumps 21 are respectively connected with the two ends of the circulation cooling pipe 19 in a sealing manner, and cooling liquid in the cooling water storage cavity 20 is led into the circulation cooling pipe 19 through the circulation pumps 21, so that the surface temperature of the cooling plate 10 can be reduced, and the temperature of the outer surface of the microorganism culture dish 12 can be reduced through the cooling plate 10.

The working principle is as follows: when the device is used, the microorganism culture dish 12 can be connected with the device shell 1 through the connecting sleeve 11 and the sealing clamp plate 17 during the cultivation work, so that the device shell 1 and the microorganism culture dish 12 can be sealed, after the sealing, the temperature and the humidity inside the microorganism culture dish 12 can be sensed according to the temperature and humidity sensor inside the device shell 1, the stepping motor 18 is controlled through the single chip microcomputer to drive the overturning cooling plate 7 to overturn, so that the cooling plate 10 is tightly attached to the microorganism culture dish 12, the cooling liquid inside the cooling water storage cavity 20 is led into the circulating cooling pipe 19 through the circulating pump 21, so that the surface temperature of the cooling plate 10 can be reduced, the temperature of the outer surface of the microorganism culture dish 12 can be reduced through the cooling plate 10, the environmental temperature of autotrophic microorganisms inside the microorganism culture dish 12 is reduced, the optimal cultivation effect is achieved, the ventilator 2 can lead the air after the autotrophic microorganisms are cultivated into the device shell 1, through filter core 16 and active carbon deodorization layer 15 with smelly gas adsorb to can avoid autotrophy microorganism to cultivate the gaseous polluted environment who produces, improve operating mass with simple structure, easy to assemble and dismantlement are applicable to different operational environment.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. A deodorizing device for autotrophic microorganisms comprising a device casing (1), characterized in that: a ventilation fan (2) is arranged above the device shell (1), an active carbon deodorization layer (15) is arranged above the interior of the device shell (1), a filter element (16) is arranged below the active carbon deodorization layer (15), a connecting sleeve (11) is arranged at the lower end of the device shell (1), the lower end of the connecting sleeve (11) is provided with a microorganism culture dish (12), both sides of the device shell (1) are provided with turnover cooling plates (7), the inner side of the turnover cooling plate (7) is provided with a cooling plate (10), the cooling plate (10) is jointed with a microorganism culture dish (12), a cooling water storage cavity (20) is arranged inside the turnover cooling plate (7), and one side of the cooling plate (10) extends to the inside of the cooling water storage cavity (20) and is hermetically connected with the turnover cooling plate (7), and a circulating cooling pipe (19) is installed inside the cooling plate (10).

2. A deodorizing means for autotrophic microorganisms according to claim 1, characterized in that: the lower end of the ventilation fan (2) extends into the device shell (1) and is connected with the device shell (1) in a sealing mode, an exhaust fan (14) is installed inside the ventilation fan (2), and a filter screen (3) is installed on the upper end face of the ventilation fan (2).

3. A deodorizing means for autotrophic microorganisms according to claim 1, characterized in that: the temperature display device is characterized in that a temperature display screen (4) is mounted on the outer surface of the device shell (1), a switch button (5) is arranged at the lower end of the temperature display screen (4), a temperature and humidity sensor is mounted inside the device shell (1), and the temperature and humidity sensor is electrically connected with the temperature display screen (4).

4. A deodorizing means for autotrophic microorganisms according to claim 1, characterized in that: the internally mounted of connecting sleeve (11) has sealed splint (17), sealed splint (17) pass through screw thread and microorganism culture dish (12) fixed connection, just the interior surface mounting of sealed splint (17) has the seal cushion layer, just sealed splint (17) are through seal cushion layer and microorganism culture dish (12) sealing connection.

5. A deodorizing means for autotrophic microorganisms according to claim 1, characterized in that: connecting sleeve (8) are installed to the upper end of upset cooling plate (7), connecting axle (9) has been run through to the inside of connecting sleeve (8), connecting axle (9) and connecting sleeve (8) fixed connection, just spacing bearing (13) are all installed to the both sides of device casing (1), just the one end of connecting axle (9) is passed through spacing bearing (13) and is rotated with device casing (1) and be connected, protection casing (6) are installed to the rear end of upset cooling plate (7), the internally mounted of protection casing (6) has step motor (18), the other end of connecting axle (9) extends to protection casing (6) inside and is rotated with protection casing (6) and be connected, step motor (18) are connected through hold-in range and connecting axle (9) transmission.

6. A deodorizing means for autotrophic microorganisms according to claim 1, characterized in that: circulating pumps (21) are installed at the upper end and the lower end of the interior of the turnover cooling plate (7), and the circulating pumps (21) are respectively connected with two ends of the circulating cooling pipe (19) in a sealing mode.

Images