CN212199278U - Microbial incubator - Google Patents

Abstract

The utility model discloses a microbial cultivation case, include: cultivate the room, cultivate the structure of indoor culture frame and include: the tray comprises at least one layer, each layer of tray comprises a plurality of independent fan-shaped tray units, each fan-shaped tray unit is provided with a culture dish placing part for placing a culture dish, the axial direction of the outer wall of the rotating shaft is provided with a plurality of circles of clamping grooves, the number of circles of the clamping grooves corresponds to the number of layers of the tray, and the clamping grooves of the same circle are arranged at intervals in the circumferential direction of the rotating shaft; every fan-shaped tray unit in each layer of tray all can dismantle the support and correspond a joint groove of round in the pivot, the lower extreme of pivot passes interior casing movable support on the shells, the pivot be connected with rotary driving mechanism, the pivot can drive the tray rotation on it under rotary driving mechanism's drive. The utility model has the advantages that: greatly increased the quantity of placing of culture dish, the flexibility of tray improves greatly, and the cultivation environmental stability in the culture chamber is good.

Description

Microbial incubator

Technical Field

The utility model relates to a microorganism experimental facilities technical field, concretely relates to microorganism incubator.

Background

Microbial testing is a clinical medical testing tool and plays a critical role in epidemiological diagnosis. In microbiological experiments, it is often necessary to perform culture observations on microorganisms before subsequent immunotherapy studies, medical care studies, and the like are performed. Therefore, efficient culture of microorganisms is extremely important.

The incubator is provided with an incubation chamber, and the incubation of the microorganisms is usually performed in the incubation chamber of the microorganism incubator. The microbial incubator has the following functions: giving the microorganism a suitable, uniform and stable culture environment. However, the current microorganism incubators have the following disadvantages: the number of culture dishes which can be placed in the culture chamber at one time is limited, the stability of the environment in the culture box is poor, and the uniformity is poor.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that needs to solve is: provided is a microorganism incubator which can accommodate more culture dishes and can provide a stable and uniform culture environment.

In order to achieve the purpose, the adopted technical scheme comprises the following steps: a microbial incubator comprising: outer casing and interior casing, the inside of interior casing is for cultivateing the room, and the front end of cultivateing the room is provided with the operating door, and the hinged joint of operating door is on the outer casing, forms the equipment room between the outer casing of operating door one side and the interior casing, cultivates indoor being provided with and cultivates the frame, cultivates the structure of frame and includes: the tray comprises at least one layer, each layer of tray comprises a plurality of independent fan-shaped tray units, each fan-shaped tray unit is provided with a culture dish placing part for placing a culture dish, the axial direction of the outer wall of the rotating shaft is provided with a plurality of circles of clamping grooves, the number of circles of the clamping grooves corresponds to the number of layers of the tray, the clamping grooves of the same circle are arranged at intervals in the circumferential direction of the rotating shaft, and the number of the clamping grooves in the circle corresponds to the number of the fan-shaped tray units in one layer of tray; every fan-shaped tray unit in each layer of tray all can be dismantled and support in a joint groove that corresponds the round in the pivot, and the connection structure between every fan-shaped tray unit and the joint groove includes: the clamping and blocking block is arranged at the inner end of the fan-shaped tray unit and protrudes outwards, and comprises a body and clamping and blocking parts, and the clamping and blocking parts are positioned at the end part of the body and protrude towards the two sides of the body respectively; the clamping groove comprises a groove body, an upper notch and a lower notch which are communicated up and down are arranged outside the groove body, the circumferential width of the upper notch is larger than that of the lower notch, the circumferential width of the lower notch just can accommodate a body of the clamping stop block, clamping stop walls are arranged on two sides of the lower notch, a clamping stop area is formed between each clamping stop wall and the groove body, a clamping stop part of each clamping stop block can only enter the groove body through the upper notch, the clamping stop block positioned in the groove body downwards enables the body to be clamped in the lower notch, and the clamping stop part is clamped in the clamping stop area on the inner side of the clamping stop wall, so that the fan-shaped tray unit is clamped and installed in the clamping groove; the lower end of the rotating shaft penetrates through the inner shell and is movably supported on the outer shell, the rotating shaft is connected with the rotary driving mechanism, and the rotating shaft can drive the tray on the rotating shaft to rotate under the driving of the rotary driving mechanism.

Further, aforementioned microbial cultivation case, wherein, the top of cultivateing the indoor cultivation frame of cultivateing is provided with a plurality of first nozzles, and a plurality of first nozzles are connected with steam generator through the pipeline, steam generator set up in the equipment room, the equipment room still is provided with the water tank, steam generator on be connected with the steam generator inlet tube, the steam generator inlet tube passes through pump and water tank intercommunication.

Furthermore, in the microorganism incubator, a downward-recessed drainage groove is formed in the bottom of the inner shell, a drainage pipe is connected to the bottom of the drainage groove, the bottom of the inner shell is inclined to the drainage groove from high to low, and the drainage pipe is communicated with the discharge port in the bottom of the outer shell.

Furthermore, in the microbial incubator, a second nozzle with a mixing chamber is arranged in the incubator and fixedly mounted on the inner housing, the second nozzle is located above the water tank, the mixing chamber of the second nozzle is connected with a humidifying water inlet pipeline and an air inlet pipe, and the humidifying water inlet pipeline is communicated with the water tank through a humidifying control valve; the air inlet pipe is connected with an air inlet control valve, the air inlet control valve is communicated with an air inlet on the outer shell, and the air inlet is used for being connected with an air source input into the culture chamber.

Still further, in the microbial cultivation box, a temperature sensor and a humidity sensor are arranged at the top of the cultivation room.

Further, according to the microbial incubator, a vacuum pump is arranged in the equipment chamber, one end of the vacuum pump vacuumized is communicated with the incubation chamber, and the exhaust end of the vacuum pump is communicated with the atmosphere through the outer shell.

Further, aforementioned microbial cultivation case, wherein, be provided with temperature regulation apparatus in the equipment room, temperature regulation apparatus include: temperature regulation pipeline, temperature regulation pipeline fixed mounting on interior casing and with cultivate the room and be linked together, the fan is installed to the other end of temperature regulation pipeline, fan and circulating line be linked together, circulating line and the circulation wind gap intercommunication of seting up on interior casing, temperature regulation pipeline in be provided with cooling tube and electric heater, under the effect of fan, the indoor gas of cultivateing can constantly pass through circulating line and reentry to cultivateing indoor through temperature regulation pipeline.

Further, in the above-mentioned microorganism incubator, the structure of the rotation driving mechanism includes: a driving shaft is horizontally arranged between the bottom of the inner shell and the bottom of the outer shell, the driving shaft is movably supported in a bearing at the bottom of the outer shell, a driving bevel gear is arranged at one end of the driving shaft and meshed with a driven bevel gear, the driven bevel gear is arranged on a rotating shaft, and the driving shaft extends into the equipment room and is connected with an output shaft of a motor arranged in the equipment room.

Further, according to the microbial incubator, a control panel with a display screen is arranged on the outer shell outside the equipment room, and the control panel is located on one side key of the operation door.

Further, aforementioned microbial cultivation case, wherein, the inner end of every fan-shaped tray unit still is provided with curved positioning baffle, and positioning baffle is located the inboard of card dog and downward protrusion in fan-shaped tray unit, and when fan-shaped tray unit joint was installed in the joint groove, positioning baffle laminating card kept off on the outer wall of pivot.

The utility model has the advantages that: firstly, the placing number of culture dishes in the culture room is greatly increased. The fan-shaped tray units are detachably supported with the rotating shaft, so that the flexibility of the tray is greatly improved, the workers can place the fan-shaped tray units with corresponding quantity in the rotating shaft as required, and can select proper placement positions as required. The vacant fan-shaped tray unit can be detached, so that microbial pollution is avoided. And thirdly, the heating self-circulation mode and the cooling self-circulation mode in the culture chamber can promote the gas flow in the culture chamber, thereby greatly improving the uniformity and the stability of the culture environment in the culture chamber. Fifthly, the rotatable structure of the rotating shaft enables each culture dish not to be influenced by the placing position by controlling the intermittent rotation of the rotating shaft in the culture process, namely: each culture dish is in a uniform culture environment, so that the microbial culture effect is greatly improved.

Drawings

FIG. 1 is a schematic view of the microorganism incubator according to the present invention in a top view.

FIG. 2 is a schematic view of the structure of FIG. 1 taken along the sectional line A-A.

FIG. 3 is a schematic view of the structure in the sectional direction B-B in FIG. 1.

Fig. 4 is a schematic structural view of a fan-shaped tray unit.

Fig. 5 is a schematic structural view of the rotating shaft.

Fig. 6 is an enlarged schematic view of a portion E of fig. 2.

Detailed Description

The invention will be described in further detail with reference to the drawings and preferred embodiments.

As shown in fig. 1, 2 and 3, the microorganism incubator comprises: the inside of shell body 1 and interior casing 2, interior casing 2 is for cultivateing room 3, and the top in cultivateing room 3 is provided with LED lamp 33, and the top in cultivateing room 3 still is provided with temperature sensor 31 and humidity transducer 32. The front end of the culture chamber 3 is provided with an operation door 4, the operation door 4 is hinged on the outer shell 1, an equipment chamber 9 is formed between the outer shell 1 and the inner shell 2 on one side of the operation door 4, and a culture frame is arranged in the culture chamber 3.

The structure of culture shelf includes: the tray comprises a rotating shaft 6 and trays 5, wherein at least one layer of tray 5 is arranged, each layer of tray 5 comprises a plurality of independent fan-shaped tray units 51, each fan-shaped tray unit 51 is provided with a culture dish placing part 511 for placing a culture dish 10, a plurality of circles of clamping grooves 61 are arranged in the axial direction of the outer wall of the rotating shaft 6, the number of circles of the clamping grooves 61 corresponds to the number of layers of the tray 5, the clamping grooves 61 in the same circle are uniformly arranged at intervals in the circumferential direction of the rotating shaft 6, and the number of the clamping grooves 61 in the circle corresponds to the number of the fan-shaped tray units 51 in one layer of tray 5; each of the fan-shaped tray units 51 in each layer of trays 5 is detachably supported in one of the catching grooves 61 of the corresponding turn on the rotary shaft 6.

In this embodiment, as shown in fig. 4, 5 and 6, the connection structure between each fan-shaped tray unit 51 and the snap-in groove 61 includes: the clamping block 7 is arranged at the inner end of the fan-shaped tray unit 51 and protrudes outwards, the clamping block 7 comprises a body 71 and a clamping part 72, and the clamping part 72 is positioned at the end part of the body 71 and protrudes towards the two sides of the body 71 respectively. The clamping groove 61 comprises a groove body 611, an upper notch 612 and a lower notch 613 which are through up and down are arranged outside the groove body 611, the circumferential width of the upper notch 612 is larger than that of the lower notch 613, the circumferential width of the lower notch 613 just can accommodate the body 71 of the clamping block 7, two sides of the lower notch 613 are provided with clamping walls 614, a clamping area is formed between each clamping wall 614 and the groove body 611, the clamping part 72 of each clamping block 7 can only enter the groove body 611 through the upper notch 612, the clamping block 7 in the groove body 611 can downwards enable the body 71 to be tightly clamped in the lower notch 613, and enable the clamping part 72 to be tightly clamped in the clamping area on the inner side of the clamping wall 614, so that the fan-shaped tray unit 51 is clamped and installed in the clamping groove 61. In this embodiment, the inner end of each fan-shaped tray unit 51 is further provided with an arc-shaped positioning baffle 512, the positioning baffle 512 is located inside the clamping stop 7 and protrudes downwards from the fan-shaped tray unit 51, and when the fan-shaped tray unit 51 is clamped and installed in the clamping groove 61, the positioning baffle 512 is attached to the outer wall of the rotating shaft 6.

When detaching, the fan-shaped tray unit 51 is simply lifted up so that the body 71 of the catch 7 is separated from the lower notch 613 and the catch portion 72 is separated from the catch area between the catch wall 614 and the groove body 611, and the catch 7 of the fan-shaped tray unit 51 can be separated from the catch groove 61 through the upper notch 612.

The lower end of the rotating shaft 6 penetrates through the bottom of the inner shell 2 and is movably supported at the bottom of the outer shell 1, the rotating shaft 6 is connected with a rotary driving mechanism, and the rotating shaft 6 can drive the tray 5 on the rotating shaft to rotate under the driving of the rotary driving mechanism. In this embodiment, the structure of the rotation driving mechanism includes: a driving shaft 8 is horizontally arranged between the bottom of the inner shell 2 and the bottom of the outer shell 1, the driving shaft 8 is movably supported in a bearing at the bottom of the outer shell 1, a driving bevel gear 81 is arranged at one end of the driving shaft 8, the driving bevel gear 81 is meshed with a driven bevel gear 82, the driven bevel gear 82 is arranged on the rotating shaft 6, and the driving shaft 8 extends into the equipment room 9 and is connected with an output shaft of a motor 83 arranged in the equipment room 9.

The culture shelf with the structure has the advantages that: firstly, the space in the culture chamber 3 is fully utilized, and the number of culture dishes 10 which can be placed is increased. And secondly, the detachable connection structure between each fan-shaped tray unit 51 and the rotating shaft 6 is simple, the installation and the detachment are very convenient, and the use by workers is convenient. Meanwhile, the cleaning is greatly facilitated, and the fan-shaped tray units 51 with corresponding quantity can be installed according to actual needs during microorganism culture, so that the pollution of microorganisms to the vacant fan-shaped tray units 51 is avoided. Thirdly, the rotatable structure of pivot 6, this can realize rotating at 6 intermittence of microorganism culture process pivot to the position of culture dish 10 in culture chamber 3 on the intermittent type nature transform culture shelf avoids same culture dish 10 rigidity, thereby makes all culture dishes 10 can both not receive the influence of placing the position under the stable cultivation environment of homogeneous.

In order to sterilize and clean the inside of the cultivation room 3, a plurality of first nozzles 11 are arranged above the cultivation shelves in the cultivation room 3 in the present embodiment, and the number of the first nozzles 11 may be generally 1-3. The first nozzle 11 is connected with a steam generator 12 through a pipeline, the steam generator 12 is arranged in the equipment room 9, a water tank 13 is further arranged in the equipment room 9, a steam generator water inlet pipe 121 is connected to the steam generator 12, and the steam generator water inlet pipe 121 is communicated with the water tank 13 through a pump 14.

In order to discharge water generated during cleaning or steam sterilization, in the embodiment, a downward concave drainage groove 21 is formed at the bottom of the inner shell 2, a drainage pipe 22 is connected to the bottom of the drainage groove 21, the bottom of the inner shell 2 is inclined from high to low to the drainage groove 21, and the drainage pipe 22 is communicated with a discharge port 103 at the bottom of the outer shell 1.

In this embodiment, the second nozzle 15 with the mixing chamber 151 is arranged in the cultivation room 3, the second nozzle 15 is fixedly installed on the inner casing 2, the second nozzle 15 is located above the water tank 13, the mixing chamber 151 of the second nozzle 15 is connected with the humidification water inlet pipeline 16 and the air inlet pipe 17, and the humidification water inlet pipeline 16 is communicated with the water tank 13 through the humidification control valve 161. Air inlet pipe 17 is connected to air inlet control valve 18, air inlet control valve 18 is connected to air inlet port 101 of outer case 1, and air inlet port 101 is used for connecting to an external air source supplied into culture chamber 3. The culture chamber 3 is supplied with air through an air supply, an air supply control valve 18, and a second nozzle 15.

In this embodiment, a vacuum pump 91 is provided in the apparatus chamber 9, one end of the vacuum pump 91 for evacuation is communicated with the culture chamber 3, and an exhaust end of the vacuum pump 91 is communicated with the atmosphere through the outer casing 1. The evacuation function in the culture chamber 3 is realized by the vacuum pump 91.

In order to adjust the temperature in the incubation chamber 3 well, a temperature adjustment device is provided in the equipment chamber 9, the temperature adjustment device including: the temperature adjusting pipeline 92 is fixedly arranged on the inner shell 2 and communicated with the culture chamber 3, the other end of the temperature adjusting pipeline 92 is provided with a fan 93, the fan 93 is communicated with a circulating pipeline 94, and the circulating pipeline 94 is communicated with a circulating air port 21 formed in the inner shell 2. The temperature adjusting pipe 92 is provided with a cooling pipe 95 and an electric heater 96, and the cooling pipe 95 is communicated with a cooling medium, which may be ice water or the like. Under the action of the fan 93, the gas in the culture chamber 3 can continuously enter the culture chamber 3 through the circulation pipe 94 and the temperature adjusting pipe 92. The temperature adjusting device can realize a heating self-circulation mode and a cooling self-circulation mode. Heating self-circulation mode: the fan 93 and the electric heater 96 are started, and under the action of the fan 93, the gas in the culture chamber 3 continuously passes through the circulating air port 21, the circulating pipeline 94 and the electric heater 96, is heated, and then enters the culture chamber 3 through the temperature adjusting pipeline 92. When the temperature sensor 31 detects that the temperature reaches a set temperature required for culturing microorganisms, the heating self-circulation is stopped. A cooling self-circulation mode: the fan 93 and the cooling pipe 95 are turned on. Under the action of the fan 93, the gas in the culture chamber 3 continuously flows through the circulating air port 21, the circulating pipeline 94 and the cooling pipe 95 to be cooled and then flows into the culture chamber 3 through the temperature adjusting pipeline 92. When the temperature sensor 31 detects that the temperature reaches a set temperature required for culturing microorganisms, the cooling self-circulation is stopped. The heating and cooling of the internal self-circulation of the culture chamber 3 are adopted, and the aim is as follows: the uniformity of the environment inside the culture chamber 3 is greatly improved by the airflow.

For the convenience of control, a control panel 102 with a display screen is provided on the outer case 1 outside the equipment room 9, and the control panel 102 is located on one side of the operation door 4. All functions in the use process, such as air intake, heating self-circulation, cooling self-circulation, steam sterilization, water drainage, air exhaust and the like, can be integrated on the control panel 102, so that the operation and control of workers are facilitated.

The working principle is as follows: high temperature steam sterilization of the culture chamber 3 is required prior to the microbial culture. The high-temperature steam sterilization step comprises the following steps: the operation door 4 is closed, the steam generator 12 is operated, and high-temperature steam generated by the steam generator 12 is sprayed into the cultivation room 3 through the first nozzle 11, so that the cultivation room 3 is sterilized by the high-temperature steam. The temperature sensor 31 monitors the temperature in the culture chamber 3 in real time to ensure that the culture chamber 3 maintains the sterilization temperature within a set sterilization time, thereby achieving effective sterilization. Water generated by liquefaction of the high-temperature steam is collected in the drain groove 21 and then discharged to the outside through the drain pipe 22.

Subsequently, the vacuum pump 91 is turned on, and the vacuum pump 91 evacuates the gas in the incubation chamber 3.

Then, a gas suitable for culturing the microorganism, typically a mixed gas of 5% oxygen, 10% carbon dioxide and 85% nitrogen, is introduced into the culture chamber 3. The mixed gas enters the mixing chamber 151 of the second nozzle 15 from the gas inlet 101 through the gas inlet control valve 18 from the gas inlet pipe 17, the humidifying water inlet pipe 16 is opened as required, so that the water in the water tank 14 enters the mixing chamber 151 under the adsorption of the negative pressure in the mixing chamber 151, and the water and the mixed gas are mixed in the mixing chamber 151 and sprayed into the culture chamber 3 through the second nozzle 15. When the humidity sensor 32 detects that the humidity in the incubation chamber 3 reaches a set value, the humidification control valve 161 of the humidification water inlet line 16 is closed. The intake control valve 18 is closed after a certain period of time.

Then, the heating self-circulation mode is started. When the temperature sensor 31 detects that the temperature reaches a set temperature required for culturing microorganisms, the heating self-circulation is stopped.

Then, each of the culture dishes 10 loaded with the culture is placed in the dish placing part 511 of the fan-shaped tray unit 51 on the culture shelf, so that the cultivation of the microorganism is started.

In the culture process, when the temperature sensor 31 detects that the temperature in the culture chamber 3 is low, the heating self-circulation mode is restarted, and if the temperature in the culture chamber 3 is high, the cooling self-circulation mode is started. In addition, the rotation shaft 6 intermittently rotates, thereby intermittently changing the position of the culture dish 10 on the culture rack within the culture chamber 3.

The utility model has the advantages that: one, the number of the culture dishes 10 in the culture chamber 3 is greatly increased. Second, can dismantle the support between fan-shaped tray unit 51 and the pivot 6 for tray 5's flexibility improves greatly, and the staff can place the fan-shaped tray unit 51 of corresponding quantity on pivot 6 as required, and can select suitable the position of placing as required. The empty fan tray unit 51 can be removed to avoid microbial contamination. And thirdly, the heating self-circulation mode and the cooling self-circulation mode in the culture chamber 3 can promote the gas in the culture chamber 3 to flow, thereby greatly improving the uniformity and the stability of the culture environment in the culture chamber 3. Fourthly, the rotatable structure of pivot 6 makes the cultivation in-process, makes each culture dish not receive the influence of placing the position through control pivot 6 intermittent type nature rotation, promptly: each culture dish 10 is in a uniform culture environment, so that the microorganism culture effect is greatly improved.

Claims (10)

1. A microbial incubator comprising: outer casing and interior casing, the inside of interior casing is for cultivateing the room, and the front end of cultivateing the room is provided with the operating door, and the hinged joint of operating door is on the outer casing, forms the equipment room between the outer casing of operating door one side and the interior casing, cultivates indoor being provided with and cultivates frame, its characterized in that: the structure of culture shelf includes: the tray comprises at least one layer, each layer of tray comprises a plurality of independent fan-shaped tray units, each fan-shaped tray unit is provided with a culture dish placing part for placing a culture dish, the axial direction of the outer wall of the rotating shaft is provided with a plurality of circles of clamping grooves, the number of circles of the clamping grooves corresponds to the number of layers of the tray, the clamping grooves of the same circle are arranged at intervals in the circumferential direction of the rotating shaft, and the number of the clamping grooves in the circle corresponds to the number of the fan-shaped tray units in one layer of tray; every fan-shaped tray unit in each layer of tray all can be dismantled and support in a joint groove that corresponds the round in the pivot, and the connection structure between every fan-shaped tray unit and the joint groove includes: the clamping and blocking block is arranged at the inner end of the fan-shaped tray unit and protrudes outwards, and comprises a body and clamping and blocking parts, and the clamping and blocking parts are positioned at the end part of the body and protrude towards the two sides of the body respectively; the clamping groove comprises a groove body, an upper notch and a lower notch which are communicated up and down are arranged outside the groove body, the circumferential width of the upper notch is larger than that of the lower notch, the circumferential width of the lower notch just can accommodate a body of the clamping stop block, clamping stop walls are arranged on two sides of the lower notch, a clamping stop area is formed between each clamping stop wall and the groove body, a clamping stop part of each clamping stop block can only enter the groove body through the upper notch, the clamping stop block positioned in the groove body downwards enables the body to be clamped in the lower notch, and the clamping stop part is clamped in the clamping stop area on the inner side of the clamping stop wall, so that the fan-shaped tray unit is clamped and installed in the clamping groove; the lower end of the rotating shaft penetrates through the inner shell and is movably supported on the outer shell, the rotating shaft is connected with the rotary driving mechanism, and the rotating shaft can drive the tray on the rotating shaft to rotate under the driving of the rotary driving mechanism.

2. The microbiological incubator according to claim 1, wherein: cultivate the indoor top of cultivateing the frame and be provided with a plurality of first nozzles, a plurality of first nozzles are connected with steam generator through the pipeline, steam generator set up in the equipment room, still be provided with the water tank in the equipment room, steam generator on be connected with the steam generator inlet tube, the steam generator inlet tube passes through pump and water tank intercommunication.

3. A microbiological incubator as claimed in claim 2, wherein: the bottom of the inner shell is provided with a drainage groove which is sunken downwards, the bottom of the drainage groove is connected with a drainage pipe, the bottom of the inner shell is inclined to the drainage groove from high to low, and the drainage pipe is communicated with a discharge port at the bottom of the outer shell.

4. A microbiological incubator as claimed in claim 2 or 3, wherein: a second nozzle with a mixing cavity is arranged in the culture chamber, the second nozzle is fixedly arranged on the inner shell and positioned above the water tank, the mixing cavity of the second nozzle is connected with a humidifying water inlet pipeline and an air inlet pipe, and the humidifying water inlet pipeline is communicated with the water tank through a humidifying control valve; the air inlet pipe is connected with an air inlet control valve, the air inlet control valve is communicated with an air inlet on the outer shell, and the air inlet is used for being connected with an air source input into the culture chamber.

5. A microbiological incubator as claimed in claim 4, wherein: the top in the culture room is provided with a temperature sensor and a humidity sensor.

6. A microbiological incubator as claimed in claim 2 or 3, wherein: the equipment chamber is internally provided with a vacuum pump, one end of the vacuum pump for vacuumizing is communicated with the culture chamber, and the exhaust end of the vacuum pump is communicated with the atmosphere through the outer shell.

7. A microbiological incubator as claimed in claim 2 or 3, wherein: the indoor temperature regulation device that is provided with of equipment, temperature regulation device include: temperature regulation pipeline, temperature regulation pipeline fixed mounting on interior casing and with cultivate the room and be linked together, the fan is installed to the other end of temperature regulation pipeline, fan and circulating line be linked together, circulating line and the circulation wind gap intercommunication of seting up on interior casing, temperature regulation pipeline in be provided with cooling tube and electric heater, under the effect of fan, the indoor gas of cultivateing can constantly pass through circulating line and reentry to cultivateing indoor through temperature regulation pipeline.

8. A microbiological incubator as claimed in claim 2 or 3, wherein: the structure of the rotary drive mechanism includes: a driving shaft is horizontally arranged between the bottom of the inner shell and the bottom of the outer shell, the driving shaft is movably supported in a bearing at the bottom of the outer shell, a driving bevel gear is arranged at one end of the driving shaft and meshed with a driven bevel gear, the driven bevel gear is arranged on a rotating shaft, and the driving shaft extends into the equipment room and is connected with an output shaft of a motor arranged in the equipment room.

9. A microbiological incubator according to claim 1 or 2 or 3 wherein: and a control panel with a display screen is arranged on the outer shell outside the equipment room.

10. A microbiological incubator according to claim 1 or 2 or 3 wherein: the inner end of each fan-shaped tray unit is also provided with an arc-shaped positioning baffle, the positioning baffle is positioned on the inner side of the clamping stop block and protrudes out of the fan-shaped tray unit downwards, and when the fan-shaped tray units are clamped and installed in the clamping grooves, the positioning baffle is attached to the clamping stop block on the outer wall of the rotating shaft.

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