CN211921589U - Large-scale customized cell culture storehouse - Google Patents

Large-scale customized cell culture storehouse Download PDF

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Publication number
CN211921589U
CN211921589U CN201922476459.XU CN201922476459U CN211921589U CN 211921589 U CN211921589 U CN 211921589U CN 201922476459 U CN201922476459 U CN 201922476459U CN 211921589 U CN211921589 U CN 211921589U
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module
carbon dioxide
culture
sampling
cell culture
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庞逢祥
张博韬
张立明
温邵博
朱吉萌
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Qinhuangdao Zhaojian Biotechnology Co ltd
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Qinhuangdao Zhaojian Biotechnology Co ltd
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Abstract

The utility model relates to a large-scale customized cell culture bin, which comprises a control module, a plurality of culture modules and a storage and sampling module; the culture module cultures cells, a control system is integrated in the control module, and the storage and sampling module conveys the cells to be cultured to the culture chamber and collects the cultured cells; the control module comprises a temperature control system, a carbon dioxide concentration control system, a constant humidity control system and a touch screen, and a movable sterilization and disinfection device, a condensed water collecting device, an air purification system and a power-off protection device are further arranged in the cultivation room. The utility model has the advantages that: the cells with different conditions are cultured in the same cell culture bin by arranging a plurality of culture modules, so that the cross contamination among the cells is avoided; the full-coverage type disinfection and sterilization operation can be realized; the air circulation in the culture chamber ensures that the air in the culture chamber is uniform and condensed water generated by the equipment can be automatically discharged.

Description

Large-scale customized cell culture storehouse
Technical Field
The utility model relates to a biological incubator field especially relates to a large-scale customization cell culture storehouse.
Background
The carbon dioxide incubator realizes in-vitro culture of cells by simulating and forming a growth environment similar to that in an organism in an incubator body, and is widely applied to cell and tissue culture and culture of certain special microorganisms at present.
However, the conventional carbon dioxide incubator cannot simultaneously culture cells under different culture conditions because the internal conditions are uniform. Therefore, to culture cells under different conditions, a plurality of incubators are required, which is costly and takes up a large space. When the sterilization and disinfection operation is performed again during the culture process, the cells being cultured need to be taken out, and thus the cell culture is interrupted and is hardly affected by the fluctuation of the external environment.
In addition, the condensed water generated by the cell culture equipment in the prior art can only be removed by natural air drying or manual wiping, and the water condensed in the incubator can fall onto the culture due to the manual carelessness, so that the pollution is caused;
in the cell culture equipment in the prior art, the flow of internal gas is stopped after cell culture condition parameters meet set values, and a uniform gas space cannot be formed;
the cell culture equipment in the prior art can only carry out disinfection and sterilization through an ultraviolet lamp at a fixed position, and can not carry out disinfection and sterilization operation without dead angles and full coverage.
SUMMERY OF THE UTILITY MODEL
Technical problem to be solved
In order to solve the above problems existing in the prior art, the utility model provides a large-scale customized cell culture storehouse.
(II) technical scheme
In order to achieve the above object, the utility model discloses a main technical scheme include:
a large customized cell culture compartment comprising a control module, at least one culture module, and at least one storage and sampling module;
the culture module is used for providing corresponding environmental conditions for the cells according to the instructions of the control module;
the control module is connected with the culture module and is used for adjusting and detecting the environmental conditions of the culture module according to different cell types;
the storage and sampling module is communicated with the culture module and is used for conveying cells to be cultured to the culture module and collecting the cultured cells;
the environmental conditions include: temperature, humidity, and carbon dioxide concentration.
The sample access module comprises a sample loading system and a sampling system; the loading system delivers uncultured cells to the culture module; the sampling system sends the cultured cells back to the storage and sampling module from the culture module;
the sample loading system comprises a sample loading container, a sample loading pump and a sample loading pipeline;
the sampling system comprises a sampling container, a sampling pump and a sampling pipeline;
the storage and sampling module is communicated with the culture module through a sample loading pipeline and a sampling pipeline;
one end of the sample loading pipeline is connected with the sample loading container, the other end of the sample loading pipeline is connected with the culture module, and the sample loading pump is arranged on the sample loading pipeline;
the one end of sample pipeline is connected the sampling container, and the other end is connected and is cultivateed the module, the sample pump sets up on the sample pipeline.
The control module includes: the device comprises a temperature control system, a carbon dioxide concentration control system, a constant humidity control system and a touch screen.
The carbon dioxide concentration control system comprises a carbon dioxide air inlet, a pressure reducing valve, a carbon dioxide conveying pipe, a carbon dioxide throttle valve and a carbon dioxide concentration sensor;
the carbon dioxide conveying pipe comprises a carbon dioxide conveying main pipe and a plurality of carbon dioxide conveying branch pipes; the carbon dioxide throttle valve is arranged on the outer side of the rear wall surface of each inner cavity;
the air inlet of the carbon dioxide pipe is externally connected with a carbon dioxide source;
the carbon dioxide conveying main pipe is connected with the carbon dioxide air inlet through a pressure reducing valve;
one end of the carbon dioxide branch pipe is connected with the carbon dioxide main pipe, and the other end of the carbon dioxide branch pipe is connected with each carbon dioxide throttle valve.
An inner cavity is arranged in the culture module, the inner cavity and the control module are arranged in a non-contact manner, and the side edge of the inner cavity is hinged with an inner glass door; the incubator further comprises a case body shell;
the temperature control system comprises a copper pipe fixed on the outer side of each surface of the inner cavity and a temperature sensor inside the inner cavity, and heating gas or liquid is introduced into the copper pipe.
The constant humidity control system comprises a water inlet, an atomization generator, a mist conveying pipe, a mist throttle valve and a humidity sensor; the mist throttle valve is arranged near the carbon dioxide throttle valve;
the mist conveying pipe comprises a mist conveying main pipe and a plurality of mist conveying branch pipes;
the water inlet is externally connected with a water source;
one end of the atomization generator is connected with the water inlet, and the other end of the atomization generator is connected with the mist conveying main pipe;
the fog throttle valve is connected with the fog delivery branch pipe.
The cell culture bin further comprises a power-off protection module, the power-off protection module comprises a rechargeable lithium battery and a control circuit board, and when an external power supply is disconnected, the rechargeable lithium battery supplies power to each module.
Further, the control module also comprises an air purification system,
the air purification system comprises an air inlet, a filter, a purified air delivery pipe and a purified air throttle valve;
the purified air delivery pipe comprises a purified air delivery main pipe and a plurality of purified air delivery branch pipes;
the purified air throttle valve is arranged near the fog throttle valve;
the purified air delivery main pipe is connected with the air inlet through a filter;
one end of the purified air delivery branch pipe is connected with the purified air delivery main pipe, and the other end of the purified air delivery branch pipe is connected with the purified air throttle valve.
Further, the cell culture bin also comprises a condensed water discharge device;
the condensed water discharging device is arranged at the bottom of the inner cavity in the culture module and comprises a first inclined plane, a second inclined plane, a water level sensor and a water pump;
the first inclined plane and the second inclined plane have opposite inclination directions, the higher ends of the first inclined plane and the second inclined plane are connected with the wall surface of the inner cavity, and the lower ends of the first inclined plane and the second inclined plane are connected into a whole;
when the water level sensor detects that the condensed water level is excessive, the water pump pumps out the condensed water.
Furthermore, an ultraviolet lamp is installed in each culture module and connected with a transmission mechanism, and the transmission mechanism drives the ultraviolet lamps to move in the culture modules.
(III) advantageous effects
The utility model has the advantages that:
the utility model can be provided with a plurality of culture modules with different culture conditions according to actual needs, cultures with different conditions can be cultured in the same incubator by utilizing the existing space to the utmost extent, thereby avoiding intercellular cross contamination and saving the equipment investment cost of a plurality of incubators; and the culture can be transferred to the inner cavity with proper culture conditions in time, the cells are not influenced by the fluctuation of the external environment due to the intermediate disinfection and sterilization operation in the culture process, and the cell culture is not interrupted.
In addition, the cell culture bin of the utility model can also realize the disinfection and sterilization operation of the dead-corner-free full-coverage type by connecting the ultraviolet lamp with the transmission unit;
the cell culture bin of the utility model can automatically discharge the produced condensate water in time in the using process, and the condensate water is prevented from polluting the culture.
Drawings
FIG. 1 is a schematic view of the overall structure of a cell culture chamber according to the present invention;
FIG. 2 is a rear view of the culture module area of the present invention;
FIG. 3 is a schematic view of the overall structure of a single inner chamber of the present invention;
FIG. 4 is a rear view of the overall structure of a single inner chamber of the present invention;
fig. 5 is a schematic structural view of the condensed water discharge device of the present invention.
[ description of reference ]
101: a control module; 102: a touch screen; 103: a control button; 104: a culture module; 105: a storage and sampling module; 106: a case body shell;
201: a first fan; 202: a carbon dioxide gas inlet; 203: a water inlet; 204: an air inlet;
301: an inner cavity; 302: an inner glass door; 303: a culture tray; 304: a condensed water collecting device; 305: a water pump; 306: a transmission unit; 307: an ultraviolet lamp; 308: a copper pipe;
401: a carbon dioxide throttle valve; 402: a carbon dioxide delivery pipe; 403: a mist throttle valve; 404: a mist delivery pipe; 405: a purified air throttle valve; 406: a purified air delivery pipe; 407: a second fan;
501: a first inclined plane; 502: a second inclined plane.
Detailed Description
For a better understanding of the present invention, reference will now be made in detail to the present invention, examples of which are illustrated in the accompanying drawings.
As shown in fig. 1, a large customized cell culture bin includes a box housing 106, the box housing 106 is divided into a culture module 104, a control module 101 and a sample access module 105; the side hinged doors of the culture module 104 and the sample storage module 105;
the culture module 104 is used for providing corresponding environmental conditions for the cells according to the instructions of the control module 101;
the control module 101 is connected with the culture module 104 and is used for adjusting and detecting the environmental conditions of the culture module 104 according to different cell types;
the storage and sampling module 105 is communicated with the culture module 104 and is used for conveying cells to be cultured to the culture module 104 and collecting the cultured cells;
the environmental conditions include: temperature, humidity, and carbon dioxide concentration.
The culture module 104 and the sampling module 105 can be provided in plurality, and the sampling module 105 comprises a loading system and a sampling system; the loading system delivers uncultured cells to the culture module 104; the sampling system returns the cultured cells from the culture module 104 to the storage and sampling module 105;
the sample loading system comprises a sample loading container, a sample loading pump and a sample loading pipeline;
the sampling system comprises a sampling container, a sampling pump and a sampling pipeline;
the sample storage module 105 is communicated with the culture module 104 through a sample loading pipeline and a sampling pipeline;
one end of the sample loading pipeline is connected with the sample loading container, the other end of the sample loading pipeline is connected with the culture module 104, and the sample loading pump is arranged on the sample loading pipeline;
the one end of sample pipeline is connected the sampling container, and the other end is connected and is cultivateed module 104, the sample pump sets up on the sample pipeline.
The sample loading container is arranged on the left side of the sample storage module 105, the sampling container is arranged on the right side of the sample storage module 105, and each sample storage module can be provided with a plurality of sample loading containers and sampling containers according to actual conditions.
The control module 101 includes: a temperature control system, a carbon dioxide concentration control system, a constant humidity control system and a touch screen 102. A touch screen 102 and a control button 103 are arranged on the surface of the control module 101, and the touch screen 102 can display the condition parameters in the culture module 104 in real time; the control button 103 is used for controlling the switch of the cell culture bin and adjusting the culture conditions such as carbon dioxide, humidity, temperature and the like.
An inner cavity 301 is arranged in the culture module 104, and the inner cavity 301 and the culture module 104 are arranged in a non-contact manner; the inner cavity 301 is hinged with an inner glass door 302 at the side.
During the whole operation, the uncultured cells are placed in the sample loading container, and the sample loading pump conveys the cells in the sample loading container to the culture module 104; after the cell culture is completed, the sampling pump delivers the cultured cells to the sampling vessel. The operating personnel puts the uncultured cells into the sample loading container, the sample loading pump conveys the cells in the container and the culture solution to the corresponding culture module 104 through the sample loading pump for cell culture, in order to prevent cell pollution and pollution in the culture module 104, the utility model discloses every group sample loading and sampling container corresponds a set of pumps, and the sample storage and taking module 105 and the culture module 104 are communicated through the check valve in the sample loading process;
after the cell culture is finished, the sampling pump sends the cultured cells to a sampling container, and similarly, in order to prevent the cells and the culture module 104 from being polluted, the sample access module 105 and the culture module 104 are communicated through a one-way valve in the sample loading process; after the cell culture is completed, the operator is notified on the display screen of the control module 101 that the cultured cells can be removed.
The carbon dioxide concentration control system comprises a carbon dioxide inlet 202, a pressure reducing valve, a carbon dioxide delivery pipe 402 and a carbon dioxide throttle valve 401;
the carbon dioxide conveying pipe 402 comprises a carbon dioxide conveying main pipe and a plurality of carbon dioxide conveying branch pipes; the carbon dioxide throttle valve 401 is arranged on the outer side of the rear wall surface of each inner cavity 301;
the air inlet of the carbon dioxide pipe is externally connected with a carbon dioxide source;
the carbon dioxide delivery main pipe is connected with the carbon dioxide inlet 202 through a pressure reducing valve;
one end of each carbon dioxide branch pipe is connected with the carbon dioxide main pipe, and the other end of each carbon dioxide branch pipe is connected with each carbon dioxide throttle valve 401.
The carbon dioxide pressure reducing valve reduces the carbon dioxide in the carbon dioxide source to a proper working pressure; after flowing out of the pressure reducing valve, the carbon dioxide firstly passes through the carbon dioxide conveying main pipe and then passes through the carbon dioxide conveying branch pipe to reach the inner cavity 301; the carbon dioxide throttle valve 401 can control the circulation and the interruption of the carbon dioxide in each inner cavity 301, and is independent from each other, so that the carbon dioxide in each inner cavity 301 can be independently controlled. In addition, a carbon dioxide sensor is installed in each inner cavity 301, so that the concentration of carbon dioxide in the culture area can be monitored in real time, and the concentration of carbon dioxide in the culture area can be kept constant.
The constant humidity control system comprises a water inlet 203, an atomization generator, a mist delivery pipe 404 and a mist throttle valve 403; the mist throttle valve 403 is disposed near the carbon dioxide throttle valve 401;
the mist delivery pipe 404 comprises a mist delivery main pipe and a plurality of mist delivery branch pipes;
the water inlet 203 is externally connected with a water source;
one end of the atomization generator is connected with the water inlet 203, and the other end of the atomization generator is connected with the mist delivery main pipe;
the mist throttle valve 403 is connected to the mist delivery branch pipe.
The liquid water is changed into a fog state by the atomization generator, so that the requirement of culture conditions is met; the mist throttle valve 403 can independently control the supplement and interruption of water vapor in each inner cavity 301 according to different requirements, so as to maintain the constant humidity of one or more inner cavities 301; correspondingly, a humidity sensor is installed in each inner cavity 301 for monitoring the humidity change in the culture environment in real time and maintaining the constant state of the humidity of the carbon dioxide in the culture area.
The temperature control system comprises copper pipes 308 fixed on the outer sides of all the surfaces of the inner cavity 301, and heating gas or liquid is introduced into the copper pipes 308.
Further, an ultraviolet lamp 307 is installed in each inner cavity 301, the ultraviolet lamp 307 is connected with a transmission mechanism, and the transmission mechanism drives the ultraviolet lamp 307 to move in the inner cavity 301.
Under the condition that the culture module occupies a large volume, the ultraviolet lamp 307 often cannot achieve a comprehensive sterilization effect without dead angles during the sterilization operation; the utility model discloses be connected ultraviolet lamp 307 with drive unit 306, realized the disinfection and sterilization of no dead angle full coverage formula.
In addition, in the process of cell or tissue culture, the culture area needs to be sterilized again to prevent the external environment from polluting the culture. However, since the carbon dioxide incubator in the prior art has only one culture area, the culture is often required to be placed in the external environment when the re-sterilization and disinfection operation is performed in the culture process. Therefore, on one hand, the external environment is difficult to meet the culture conditions, so that the environment fluctuation is caused, and the culture is influenced; on the other hand, the outside environment outside the incubator is likely to contaminate the culture.
The utility model discloses in, the operator can carry out the disinfection and isolation operation at any time to arbitrary interior cavity 301, and needn't worry to cultivate that the process receives the undulant influence of environment and external pollution, and can carry out comparatively thorough disinfection and isolation to interior cavity 301. The operator only needs to transfer the cell tissue and the like being cultured into another inner cavity 301 which is carbon dioxide, has proper temperature and humidity and is sterilized, so that the culture is not interrupted, the culture is not polluted, and the quality of the culture can be improved.
A condensed water collecting device 304 is arranged at the bottom of the inner cavity 301, and the condensed water collecting device 304 comprises a first inclined plane 501, a second inclined plane 502, a water level sensor and a water pump 305;
the first inclined plane 501 and the second inclined plane 502 are opposite in inclination direction, the higher end of the first inclined plane 501 and the second inclined plane 502 is connected with the wall surface of the inner cavity 301, and the lower end of the first inclined plane 501 and the lower end of the second inclined plane 502 are connected into a whole;
when the water level sensor detects an excessive level of condensed water, the water pump 305 pumps out the condensed water.
When condensed water falls on the first inclined surface 501 or the second inclined surface 502 of the condensed water collecting device 304, the condensed water flows to the junction of the first inclined surface 501 and the second inclined surface 502 under the action of gravity. When the condensed water at the junction reaches a certain depth, the sensor and the condensed water pump 305 detect that the condensed water is excessive, the condensed water pump 305 is started to pump out the condensed water, and the condensed water is prevented from polluting the culture.
The control module 101 also includes an air purification system including an air intake 204, a filter, a purified air delivery pipe 406, and a purified air throttle valve 405;
the purified air delivery pipe 406 comprises a purified air delivery main pipe and a plurality of purified air delivery branch pipes; the purge air throttle valve 405 is provided in the vicinity of the mist throttle valve 403; the purified air delivery manifold is connected to the air intake 204 via a filter;
one end of the purified air delivery branch pipe is connected with the purified air delivery main pipe, and the other end of the purified air delivery branch pipe is connected with the purified air throttle valve 405. Through the air purification system, before cell culture, outside air enters the box body shell 106 through the air inlet 204 of the box body shell 106, is purified by the filter and then is conveyed to each inner cavity 301 through the purified air conveying branch pipe, and impurities such as dust and the like are filtered out of the air at the moment;
a first fan 201 is arranged at the rear side of the cell culture bin box body shell 106; a second fan 407 is arranged on the rear wall surface of each inner cavity 301; after the outside air is purified to reach each inner cavity 301, the clean air is mixed with carbon dioxide, water vapor, temperature and the like more uniformly through the second fan 407 at the rear side of the inner cavity 301. In addition, when the concentration of carbon dioxide fluctuates, the amount of air supplied to the inner chamber 301 by the air purification system may be increased or decreased to maintain the concentration of carbon dioxide stably, and the constant maintenance of humidity, temperature, and the like may also be achieved by increasing or decreasing the amount of air supplied to the inner chamber 301 by the air purification system.
Furthermore, cell culture storehouse still includes the power-off protection module, the power-off protection module includes rechargeable lithium cell and control circuit board, when control circuit board detects external power source disconnection, automatic switch power supply to rechargeable lithium cell power supply. When the control circuit board detects that the external power supply is switched on, the power supply is switched to the external power supply, and meanwhile, the rechargeable lithium battery is charged.
In order to adapt to different culture experiment requirements, the appearance of each module can be changed at will, and only the box shell 106 needs to be adjusted without adjusting any module.
The cell culture storehouse shape among the prior art is unchangeable, requires highly to the place, and the incubator cost of customization specific shape is high, and consuming time is long. The utility model discloses each partial modularization in large-scale customization cell culture storehouse, the user can be according to the more free customization incubator appearance in current place, can cultivate different kinds of cultures again simultaneously, needn't increase extra equipment input cost.
The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. A large-scale customized cell culture bin is characterized in that the cell culture bin comprises a control module, at least one culture module and at least one storage and sampling module;
the culture module is used for providing corresponding environmental conditions for the cells according to the instructions of the control module;
the control module is connected with the culture module and is used for adjusting and detecting the environmental conditions of the culture module according to different cell types;
the storage and sampling module is communicated with the culture module and is used for conveying cells to be cultured to the culture module and collecting the cultured cells;
the environmental conditions include: temperature, humidity, and carbon dioxide concentration.
2. The large scale customized cell culture silo of claim 1, wherein the storage and sampling module comprises a loading system and a sampling system; the loading system delivers uncultured cells to the culture module; the sampling system sends the cultured cells back to the storage and sampling module from the culture module;
the sample loading system comprises a sample loading container, a sample loading pump and a sample loading pipeline;
the sampling system comprises a sampling container, a sampling pump and a sampling pipeline;
the storage and sampling module is communicated with the culture module through a sample loading pipeline and a sampling pipeline;
one end of the sample loading pipeline is connected with the sample loading container, the other end of the sample loading pipeline is connected with the culture module, and the sample loading pump is arranged on the sample loading pipeline;
the one end of sample pipeline is connected the sampling container, and the other end is connected and is cultivateed the module, the sample pump sets up on the sample pipeline.
3. The large scale customized cell culture silo of claim 1, wherein the control module comprises: the device comprises a temperature control system, a carbon dioxide concentration control system, a constant humidity control system and a touch screen.
4. The large scale customized cell culture chamber of claim 3, wherein the carbon dioxide concentration control system comprises a carbon dioxide inlet, a pressure relief valve, a carbon dioxide delivery tube, a carbon dioxide throttle valve, and a carbon dioxide concentration sensor;
the carbon dioxide conveying pipe comprises a carbon dioxide conveying main pipe and a plurality of carbon dioxide conveying branch pipes; the carbon dioxide throttle valve is arranged on the outer side of the rear wall surface of each inner cavity;
the carbon dioxide gas inlet is externally connected with a carbon dioxide source;
the carbon dioxide conveying main pipe is connected with the carbon dioxide air inlet through a pressure reducing valve;
one end of the carbon dioxide conveying branch pipe is connected with the carbon dioxide conveying main pipe, and the other end of the carbon dioxide conveying branch pipe is connected with each carbon dioxide throttle valve.
5. The large scale customized cell culture chamber according to claim 3, wherein an inner cavity is arranged in the culture module, the inner cavity and the control module are arranged in a non-contact manner, and the side edge of the inner cavity is hinged with an inner glass door; the cell culture bin also comprises a box body shell;
the temperature control system comprises a copper pipe fixed on the outer side of each surface of the inner cavity and a temperature sensor inside the inner cavity, and heating gas or liquid is introduced into the copper pipe.
6. The large scale customized cell culture chamber of claim 4, wherein the constant humidity control system comprises a water inlet, an atomization generator, a mist delivery tube, a mist throttle valve, and a humidity sensor; the mist throttle valve is arranged near the carbon dioxide throttle valve;
the mist conveying pipe comprises a mist conveying main pipe and a plurality of mist conveying branch pipes;
the water inlet is externally connected with a water source;
one end of the atomization generator is connected with the water inlet, and the other end of the atomization generator is connected with the mist conveying main pipe;
the fog throttle valve is connected with the fog delivery branch pipe.
7. The large scale customized cell culture storehouse according to claim 3, further comprising a power-off protection module, wherein the power-off protection module comprises a rechargeable lithium battery and a control circuit board, and the rechargeable lithium battery supplies power to each module when an external power source is turned off.
8. The large scale customized cell culture silo of claim 6, wherein,
the control module further comprises an air purification system,
the air purification system comprises an air inlet, a filter, a purified air delivery pipe and a purified air throttle valve;
the purified air delivery pipe comprises a purified air delivery main pipe and a plurality of purified air delivery branch pipes;
the purified air throttle valve is arranged near the fog throttle valve;
the purified air delivery main pipe is connected with the air inlet through a filter;
one end of the purified air delivery branch pipe is connected with the purified air delivery main pipe, and the other end of the purified air delivery branch pipe is connected with the purified air throttle valve.
9. The large scale customized cell culture silo of claim 1, further comprising: a condensed water discharge device;
the condensed water discharging device is arranged at the bottom of the inner cavity in the culture module and comprises a first inclined plane, a second inclined plane, a water level sensor and a water pump;
the first inclined plane and the second inclined plane have opposite inclination directions, the higher ends of the first inclined plane and the second inclined plane are connected with the wall surface of the inner cavity, and the lower ends of the first inclined plane and the second inclined plane are connected into a whole;
when the water level sensor detects that the condensed water level is excessive, the water pump pumps out the condensed water.
10. The large scale customized cell culture module according to claim 1, wherein each of said culture modules has a uv lamp mounted therein, said uv lamp being connected to a drive mechanism that drives the uv lamp to move within said culture module.
CN201922476459.XU 2019-12-31 2019-12-31 Large-scale customized cell culture storehouse Active CN211921589U (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113088451A (en) * 2021-04-21 2021-07-09 云南中医药大学 Biological incubator for experiments
CN114369526A (en) * 2022-01-26 2022-04-19 石家庄学院 Many floras isolated culture system
WO2024041442A1 (en) * 2022-08-22 2024-02-29 国科温州研究院(温州生物材料与工程研究所) Cell culture device, system, and method

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113088451A (en) * 2021-04-21 2021-07-09 云南中医药大学 Biological incubator for experiments
CN114369526A (en) * 2022-01-26 2022-04-19 石家庄学院 Many floras isolated culture system
WO2024041442A1 (en) * 2022-08-22 2024-02-29 国科温州研究院(温州生物材料与工程研究所) Cell culture device, system, and method

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