CN116910424A - Fluorescence staining solution transfer device based on internet of things technology - Google Patents

Abstract

The invention discloses a fluorescence dye transfer device based on the technology of the Internet of things, which comprises a first storage module, a control module, a sensor module, a data analysis module and a communication module. The fluorescence staining solution transfer device based on the Internet of things technology disclosed by the invention can monitor the storage environment of the fluorescence staining solution in real time through the current storage environment evaluation index, is favorable for keeping the stability of the fluorescence staining solution, and marks the target fluorescence staining solution as a to-be-used state or a to-be-abandoned state based on the current storage environment evaluation index, so that related personnel can select the fluorescence staining solution with good stability to ensure the use effect of the fluorescence staining solution.

Description

Fluorescence staining solution transfer device based on internet of things technology

Technical Field

The invention relates to the technical field of medicament storage devices, in particular to a fluorescence staining solution transfer device based on the technology of the Internet of things.

Background

Patent CN209490835U discloses a fungal fluorescent stain storage device comprising a lifting rod, a glass frame, an incubator, a glass plate, a stain, a switch, a temperature regulating knob, a temperature display, an ultraviolet lamp and a gasket. The glass frame is provided with a rotary clamping block; a pushing groove rod and a round groove are arranged on the incubator; the lifting rod is positioned on the upper end face of the glass frame, the glass frame is in sliding connection with the incubator, the glass plate is in adhesive connection with the incubator, the colorant is positioned in the circular groove of the incubator, two gaskets are arranged between the colorant and the circular groove, a spring is arranged between the gaskets and the circular groove, and the spring provides pressure. According to the fungus fluorescent dye storage device, the dye is placed in the incubator tank provided with the ultraviolet LED lamp, and the incubator is placed in the portable glass frame, so that fungi in the air in the incubator can be killed when the user goes out to carry the dye, and pollution is prevented.

However, the above-described storage device does not provide real-time monitoring of the storage environment of the fluorescent dye, which is disadvantageous in maintaining the stability of the fluorescent dye.

Therefore, how to design a storage environment capable of monitoring the fluorescent dye in real time to maintain the stability of the fluorescent dye is a technical problem to be solved.

Disclosure of Invention

The invention aims to solve the technical problem of providing a fluorescence staining solution transfer device based on the internet of things technology, which is beneficial to monitoring the storage environment of the fluorescence staining solution in real time so as to keep the stability of the fluorescence staining solution.

In order to solve the technical problems, the invention discloses a fluorescence dye transfer device based on the technology of the Internet of things, which comprises a first storage module, a control module, a sensor module, a data analysis module and a communication module, wherein the first storage module comprises a plurality of containers for storing fluorescence dye and a first storage cavity for storing the containers, the sensor module comprises a temperature sensor for detecting the temperature of the first storage cavity, a humidity sensor for detecting the humidity of the first storage cavity and a brightness sensor for detecting the brightness of the first storage cavity, the communication module is used for establishing communication connection with external equipment and realizing data interaction, the external equipment comprises a management platform for remotely monitoring the transfer device, the sensor module, the data analysis module and the communication module are respectively and electrically connected with the control module,

the control module performs the steps of:

the control module performs sampling operation on a current storage environment parameter on a first storage cavity storing a target fluorescent dye through the sensor module so as to obtain a current storage environment parameter data set corresponding to a current stage, wherein the current storage environment parameter comprises a current temperature value, a current humidity value and a current brightness value of the first storage cavity for storing the target fluorescent dye;

the control module establishes communication connection with the management platform through the communication module and acquires a storage environment standard parameter related to the target fluorescent staining solution and an environment evaluation index threshold range corresponding to the target fluorescent staining solution from the management platform, wherein the storage environment standard parameter comprises a temperature threshold, a humidity threshold and a brightness threshold of a storage environment for storing the target fluorescent staining solution;

the control module controls the data analysis module to determine a current storage environment evaluation index according to the current storage environment parameter data set and the storage environment standard parameter;

the control module judges whether the current storage environment evaluation index belongs to the environment evaluation index threshold range, if yes, the control module sends first feedback information to the management platform through the communication module, if not, the control module sends second feedback information to the management platform through the communication module, wherein the first feedback information comprises first marking information for marking the state of the target fluorescent dye as a to-be-used state, and the second feedback information comprises second marking information for marking the state of the target fluorescent dye as a to-be-discarded state.

The fluorescence staining solution transfer device based on the Internet of things technology disclosed by the invention can monitor the storage environment of the fluorescence staining solution in real time through the current storage environment evaluation index, is favorable for keeping the stability of the fluorescence staining solution, and marks the target fluorescence staining solution as a to-be-used state or a to-be-abandoned state based on the current storage environment evaluation index, so that related personnel can select the fluorescence staining solution with good stability to ensure the use effect of the fluorescence staining solution.

In an alternative embodiment, the transfer device further comprises a transmission mechanism and a second storage module, wherein the second storage module comprises a second storage cavity, the input end of the transmission mechanism is communicated with the first storage cavity, the first output end of the transmission mechanism is communicated with the second storage cavity,

and the steps executed by the control module further include:

when the control module judges that the current storage environment evaluation index does not belong to the environment evaluation index threshold range, the control module controls the transmission mechanism to transmit the target container corresponding to the target fluorescent staining solution from the first storage cavity to the second storage cavity.

In an alternative embodiment, the transfer device further comprises an output cavity, the second output end of the transmission mechanism is communicated with the output cavity,

and the steps executed by the control module further include:

when the control module judges that the current storage environment evaluation index belongs to the environment evaluation index threshold range, the control module controls the transmission mechanism to transmit a target container corresponding to the target fluorescent staining solution from the first storage cavity to the output cavity.

In an alternative embodiment, the control module controls the data analysis module to determine the current storage environment evaluation index according to the current storage environment parameter data set and the storage environment standard parameter, and the adopted algorithm is as follows:

,

in the method, in the process of the invention,indicating the current storage environment evaluation index corresponding to the target fluorescent dye,/->Sample number indicating the current storage environment parameter of the first storage chamber for storing the target fluorescent dye,/->A total number of samples representing a current storage environment parameter of a first storage chamber for storing said target fluorescent staining solution, <>A first storage chamber for storing the target fluorescent staining solution is shown>Current temperature value of individual samples,/->A first storage chamber for storing the target fluorescent staining solution is shown>Current humidity value of individual samples,/->A first storage chamber for storing the target fluorescent staining solution is shown>Current luminance value of individual samples,/->A temperature threshold value representing a storage environment for storing the target fluorescent staining solution,/for>A humidity threshold value representing a storage environment for storing the target fluorescent staining solution,/a>A brightness threshold value representing a storage environment for storing the target fluorescent staining solution.

In an alternative embodiment, the transfer device further comprises a humidity control module electrically connected with the control module, wherein the humidity control module is used for controlling the internal humidity of the first storage cavity,

and the steps executed by the control module further include:

the control module obtains instantaneous humidity values of a plurality of detection points in the first storage cavity storing the target fluorescent dye through the sensor module;

the control module controls the data analysis module to determine a plurality of humidity gradient vectors in the first storage cavity according to the instantaneous humidity value and the position of the corresponding detection area;

the control module controls the data analysis module to determine the current humidity gradient evaluation index of the interior of the first storage cavity according to the humidity gradient vector;

the control module establishes communication connection with the management platform through the communication module and acquires a humidity gradient evaluation index threshold range related to the interior of the first storage cavity from the management platform;

the control module judges whether the current humidity gradient evaluation index belongs to a humidity gradient evaluation index threshold range, if yes, the control module sends third feedback information to the management platform to enable the management platform to record the current humidity gradient evaluation index, and if not, the control module controls the humidity regulation module to operate to enable the humidity gradient evaluation index of the next stage to belong to the humidity gradient evaluation index threshold range.

In an alternative embodiment, the control module controls the data analysis module to determine the current humidity gradient evaluation index of the interior of the first storage cavity according to the humidity gradient vector, and the algorithm is as follows:

in the method, in the process of the invention,a current humidity gradient evaluation index indicating the interior of said first storage chamber,/>A serial number, < > -representing the humidity gradient vector of the interior of the first storage chamber determined by the data analysis module>Representing the number of humidity gradient vectors, < > -of the interior of the first storage chamber determined by the data analysis module>Representing the first part of the interior of the first storage chamber determined by the data analysis module>Coordinate values of the end point of each humidity gradient vector in the X-axis direction of the second space rectangular coordinate system constructed in advance, +>Representing the first part of the interior of the first storage chamber determined by the data analysis module>Coordinate values of the end point of each humidity gradient vector in the Y-axis direction of the second space rectangular coordinate system constructed in advance, +>Representing the first part of the interior of the first storage chamber determined by the data analysis module>The end point of each humidity gradient vector is in a second space rectangular coordinate constructed in advanceCoordinate values in the Z-axis direction of the system, wherein the pre-constructed second space rectangular coordinate system comprises an X-axis representing a humidity variation in the horizontal direction, a Y-axis representing a humidity variation in the vertical direction and a Z-axis representing a humidity variation in the vertical direction, two of the X-axis, the Y-axis and the Z-axis are orthogonal to an O-point, and a zero vector in the second space rectangular coordinate system corresponding to the O-point is a humidity reference vector.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a fluorescence dye transfer device based on the internet of things technology according to an embodiment of the invention;

FIG. 2 is a flowchart illustrating steps performed by the control module according to an embodiment of the present invention;

FIG. 3 is another flow chart of steps performed by the control module of an embodiment of the present invention;

FIG. 4 is a flowchart illustrating steps performed by the control module according to an embodiment of the present invention.

Detailed Description

In order that those skilled in the art will better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms first, second and the like in the description and in the claims, are used for distinguishing between different objects and not for describing a particular sequential order. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, apparatus, article, or device that comprises a list of steps or elements is not limited to the list of steps or elements but may, in the alternative, include other steps or elements not expressly listed or inherent to such process, method, article, or device.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the invention. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

Embodiment one: the invention discloses a fluorescence dye transfer device based on the technology of the Internet of things, which comprises a first storage module, a control module, a sensor module, a data analysis module and a communication module, wherein the first storage module comprises a plurality of containers for storing fluorescence dye and a first storage cavity for storing the containers, the sensor module comprises a temperature sensor for detecting the temperature of the first storage cavity, a humidity sensor for detecting the humidity of the first storage cavity and a brightness sensor for detecting the brightness of the first storage cavity, the communication module is used for establishing communication connection with external equipment and realizing data interaction, and the external equipment comprises a management platform for remotely monitoring the transfer device, and the sensor module, the data analysis module and the communication module are respectively and electrically connected with the control module. It can be understood that when the transfer device establishes network communication connection with the management platform through the communication module and realizes data interaction, the management platform can realize remote monitoring on the transfer device based on the internet of things technology. Alternatively, the communication module may include a 5G communication device, and then the management platform and the relay device may implement data interaction based on a 5G communication network.

As shown in fig. 2, the control module performs the steps of:

s101, the control module performs sampling operation on the current storage environment parameters on the first storage cavity storing the target fluorescent dye through the sensor module so as to obtain a current storage environment parameter data set corresponding to the current stage. The current storage environment parameters comprise a current temperature value, a current humidity value and a current brightness value of a first storage cavity for storing the target fluorescent staining solution. Alternatively, the sampling operation of the current storage environment parameter may be a sampling operation of the current storage parameter at a certain time interval on a detection point disposed in the first storage cavity, so as to obtain the current storage parameter at the detection point corresponding to the sampling time, and then the current storage environment parameter data set may include a plurality of sample data, where the content of the sample data may include the sampling time, the detection point and the corresponding current storage parameter.

S102, the control module establishes communication connection with the management platform through the communication module and acquires storage environment standard parameters related to the target fluorescent staining solution and an environment evaluation index threshold range corresponding to the target fluorescent staining solution from the management platform. The storage environment standard parameters comprise a temperature threshold value, a humidity threshold value and a brightness threshold value of a storage environment for storing the target fluorescent staining solution. Optionally, the storage environment standard parameter may be a preferred storage environment parameter which is predetermined by a person skilled in the art according to the nature of the composition in the target fluorescent staining solution and can ensure the stability of the target fluorescent staining solution, and the threshold range of the environment evaluation index corresponding to the target fluorescent staining solution may be an empirical value preset by a person skilled in the art.

S103, the control module controls the data analysis module to determine the current storage environment evaluation index according to the current storage environment parameter data set and the storage environment standard parameters. The current storage environment evaluation index can be used for representing the matching degree of the current storage environment parameter and the storage environment standard parameter of the target fluorescent staining solution, and the more the current storage environment parameter and the storage environment standard parameter are matched, the more the stability of the target fluorescent staining solution is guaranteed.

S104, the control module judges whether the current storage environment evaluation index belongs to the environment evaluation index threshold range, if so, the step S105a is executed, and if not, the step S105b is executed. By determining whether the current stored environmental evaluation index belongs to the environmental evaluation index threshold range, whether the target fluorescent staining solution is stored properly can be deduced whether the target fluorescent staining solution remains stable.

S105a, the control module sends first feedback information to the management platform through the communication module. The first feedback information comprises first marking information for marking the state of the target fluorescent staining solution as a state to be used. The state to be used may indicate that the target fluorescent dye is stored properly to be able to maintain stability.

And S105b, the control module sends second feedback information to the management platform through the communication module. The second feedback information comprises second marking information for marking the state of the target fluorescent staining solution as a state to be abandoned. The state of being discarded may indicate that the target fluorescent dye is not properly stored such that its stability is not guaranteed and that the target fluorescent dye will not be used normally.

In the fluorescence staining solution transfer device based on the Internet of things technology, the control module controls the data analysis module to determine the current storage environment evaluation index according to the current storage environment parameter data set and the storage environment standard parameter, the current storage environment evaluation index can be used for representing the matching degree of the current storage environment parameter and the storage environment standard parameter of the target fluorescence staining solution, and whether the target fluorescence staining solution is stored properly can be distinguished based on the current storage evaluation index, so that whether the target fluorescence staining solution keeps stability is deduced. Therefore, the fluorescence staining solution transferring device based on the Internet of things technology disclosed by the invention can monitor the storage environment of the fluorescence staining solution in real time through the current storage environment evaluation index, is favorable for keeping the stability of the fluorescence staining solution, and marks the target fluorescence staining solution as a to-be-used state or a to-be-discarded state based on the current storage environment evaluation index, so that related personnel can select the fluorescence staining solution with better stability to ensure the use effect.

Embodiment two: in order to further improve the convenience that related personnel can select fluorescent dye with better stability, the target fluorescent dye in a to-be-discarded state and the target fluorescent dye in a to-be-used state can be subjected to split treatment.

Optionally, as shown in fig. 1, the transferring device further includes a transmission mechanism and a second storage module, where the second storage module includes a second storage cavity, an input end of the transmission mechanism is communicated with the first storage cavity, and a first output end of the transmission mechanism is communicated with the second storage cavity.

And the control module performs the steps of:

when the control module determines that the current storage environment evaluation index does not belong to the environment evaluation index threshold range, the control module controls the transmission mechanism to transmit the target container corresponding to the target fluorescent dye from the first storage cavity to the second storage cavity, that is, performs step S106b shown in fig. 3.

Further optionally, as shown in fig. 1, the transferring device further includes an output cavity, and the second output end of the transmission mechanism is communicated with the output cavity.

And the steps executed by the control module further include:

when the control module determines that the current storage environment evaluation index belongs to the environment evaluation index threshold range, the control module controls the transmission mechanism to transmit the target container corresponding to the target fluorescent dye from the first storage cavity to the output cavity, namely, step S106a shown in fig. 3 is executed.

Embodiment III: in order to simplify the operation step of the process of determining the current storage environment evaluation index in step S103 and to improve the execution efficiency of the step, the position of the detection point in the first storage cavity may be represented by the coordinates of the detection point in the first storage cavity for constructing the three-dimensional first spatial rectangular coordinate system with respect to the first storage cavity. Then, during the sampling operation of the current storage environment parameter, the current storage environment parameter of a plurality of detection points in the first storage cavity can be detected at a certain moment to obtain relevant sample data, wherein the total number of samples corresponds to the number of detection points. For example, the current storage environment parameters of 5 detection points in the first storage cavity are detected at a certain moment, and 5 groups of sample data are obtained to form a current storage environment parameter data set corresponding to the moment. In addition, the current storage environment parameters of a certain detection point in the first storage cavity can be detected at a specific time interval in a certain time period to obtain relevant sample data, wherein the total number of samples corresponds to the detection times in the time period. For example, the duration corresponding to a certain time period is 20s, and the current storage environment parameters of a certain detection point are detected at time intervals of 4s in the time period, so that 5 groups of sample data are obtained to form a current storage environment parameter data set corresponding to the time period.

Optionally, the control module controls the data analysis module to determine the current storage environment evaluation index according to the current storage environment parameter dataset and the storage environment standard parameter, that is, step S103, and the adopted algorithm is as follows:

,

in the method, in the process of the invention,indicating the current storage environment evaluation index corresponding to the target fluorescent dye,/->Sample number, </u >, representing the current storage environment parameter of the first storage chamber for storing the target fluorescent dye>Total number of samples representing current storage environment parameter of first storage chamber for storing target fluorescent staining solution,/->A first storage chamber for storing the fluorescent dye of interest is shown>Current temperature value of individual samples,/->A first storage chamber for storing the fluorescent dye of interest is shown>Current humidity value of individual samples,/->A first storage chamber for storing the fluorescent dye of interest is shown>Current luminance value of individual samples,/->A temperature threshold value representing a storage environment for storing the target fluorescent staining solution, +.>Humidity threshold value representing a storage environment for storing the target fluorescent staining solution, +.>A brightness threshold value representing a storage environment for storing the target fluorescent dye. Alternatively, the storage environment evaluation index threshold range may be (0, 2).

In order to enable the storage environment of the target fluorescent staining solution to have a controllable function, the transfer device can be provided with a control module. The control module can control the operation of the regulation and control module according to the detected instantaneous environment parameters in the first storage cavity so as to realize the regulation and control function, thereby optimizing the storage environment of the target fluorescent dye to further ensure the stability of the target fluorescent dye. The storage environment parameter mainly related to the invention is a temperature value, a humidity value and a brightness value of the first storage cavity for storing the target fluorescent dye, and then it can be understood that the control module can control the operation of the regulation module according to the instantaneous temperature value, the humidity value and the brightness value of the interior of the first storage cavity detected by the sensor module so as to regulate and control the temperature, the humidity and the brightness of the interior of the first storage cavity respectively. The present invention will now be described with respect to the implementation of the above-described regulation function by taking the humidity regulation process inside the first storage chamber as an example, and it will be understood that the temperature regulation process and the brightness regulation process inside the first storage chamber may be implemented with reference to the humidity regulation process inside the first storage chamber.

Optionally, as shown in fig. 1, the transferring device further includes a humidity control module electrically connected to the control module, where the humidity control module is configured to control the internal humidity of the first storage cavity. And, as shown in fig. 4, the steps executed by the control module further include:

s201, the control module obtains instantaneous humidity values of a plurality of detection points in the first storage cavity storing the target fluorescent dye through the sensor module.

S202, the control module controls the data analysis module to determine a plurality of humidity gradient vectors in the first storage cavity according to the instantaneous humidity value and the positions of the corresponding detection points.

S203, the control module controls the data analysis module to determine the current humidity gradient evaluation index of the interior of the first storage cavity according to the humidity gradient vector.

S204, the control module establishes communication connection with the management platform through the communication module and acquires a humidity gradient evaluation index threshold range related to the interior of the first storage cavity from the management platform. Alternatively, the humidity gradient evaluation index threshold range may be set in advance by those skilled in the art based on empirical data.

S205, the control module judges whether the current humidity gradient evaluation index belongs to the humidity gradient evaluation index threshold range, if yes, the step S206a is executed, and if not, the step S206b is executed.

S206a, the control module sends third feedback information to the management platform so that the management platform records the current humidity gradient evaluation index.

S206b, the control module controls the humidity regulation module to operate so that the humidity gradient evaluation index of the next stage belongs to the humidity gradient evaluation index threshold range.

In order to simplify the operation step of determining the current humidity gradient evaluation index of the interior of the first storage chamber in step S203 and to improve the execution efficiency of the step, the control module controls the data analysis module to determine the current humidity gradient evaluation index of the interior of the first storage chamber according to the humidity gradient vector, that is, step S203, the adopted algorithm is as follows:

in the method, in the process of the invention,a current humidity gradient evaluation index representing the interior of the first storage chamber,/a>A serial number indicating the humidity gradient vector of the interior of the first storage chamber determined by the data analysis module,/->Representing the number of humidity gradient vectors in the first storage cavity determined by the data analysis module, +.>Indicating the first memory space defined by the data analysis module>Coordinate values of the end point of each humidity gradient vector in the X-axis direction of the second space rectangular coordinate system constructed in advance, +>Indicating the first memory space defined by the data analysis module>Coordinate values of the end point of each humidity gradient vector in the Y-axis direction of the second space rectangular coordinate system constructed in advance, +>Indicating the first memory space defined by the data analysis module>Coordinate values of the end points of the humidity gradient vectors in the Z-axis direction of a second pre-constructed space rectangular coordinate system, wherein the second pre-constructed space rectangular coordinate system comprises an X-axis representing humidity variation in the horizontal direction, a Y-axis representing humidity variation in the vertical direction and a Z-axis representing humidity variation in the vertical direction, two pairs of the X-axis, the Y-axis and the Z-axis are orthogonal to an O point, and zero vectors in the second space rectangular coordinate system corresponding to the O point are humidity reference vectors.

Finally, it should be noted that: in the fluorescence dye transfer device based on the internet of things disclosed by the embodiment of the invention, the disclosed embodiment is only a preferred embodiment of the invention, and is only used for illustrating the technical scheme of the invention, but not limiting the technical scheme; although the invention has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art will understand that; the technical scheme described in the foregoing embodiments can be modified or some of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (6)

1. The fluorescence dye transfer device based on the technology of the Internet of things is characterized by comprising a first storage module, a control module, a sensor module, a data analysis module and a communication module, wherein the first storage module comprises a plurality of containers for storing fluorescence dye and a first storage cavity for storing the containers, the sensor module comprises a temperature sensor for detecting the temperature of the first storage cavity, a humidity sensor for detecting the humidity of the first storage cavity and a brightness sensor for detecting the brightness of the first storage cavity, the communication module is used for establishing communication connection with external equipment and realizing data interaction, the external equipment comprises a management platform for remotely monitoring the transfer device, the sensor module, the data analysis module and the communication module are respectively and electrically connected with the control module,

the control module performs the steps of:

the control module performs sampling operation on a current storage environment parameter on a first storage cavity storing a target fluorescent dye through the sensor module so as to obtain a current storage environment parameter data set corresponding to a current stage, wherein the current storage environment parameter comprises a current temperature value, a current humidity value and a current brightness value of the first storage cavity for storing the target fluorescent dye;

the control module establishes communication connection with the management platform through the communication module and acquires a storage environment standard parameter related to the target fluorescent staining solution and an environment evaluation index threshold range corresponding to the target fluorescent staining solution from the management platform, wherein the storage environment standard parameter comprises a temperature threshold, a humidity threshold and a brightness threshold of a storage environment for storing the target fluorescent staining solution;

the control module controls the data analysis module to determine a current storage environment evaluation index according to the current storage environment parameter data set and the storage environment standard parameter;

the control module judges whether the current storage environment evaluation index belongs to the environment evaluation index threshold range, if yes, the control module sends first feedback information to the management platform through the communication module, if not, the control module sends second feedback information to the management platform through the communication module, wherein the first feedback information comprises first marking information for marking the state of the target fluorescent dye as a to-be-used state, and the second feedback information comprises second marking information for marking the state of the target fluorescent dye as a to-be-discarded state.

2. The fluorescence dye transfer device based on the Internet of things technology according to claim 1, wherein the transfer device further comprises a transmission mechanism and a second storage module, the second storage module comprises a second storage cavity, the input end of the transmission mechanism is communicated with the first storage cavity, the first output end of the transmission mechanism is communicated with the second storage cavity,

and the steps executed by the control module further include:

when the control module judges that the current storage environment evaluation index does not belong to the environment evaluation index threshold range, the control module controls the transmission mechanism to transmit the target container corresponding to the target fluorescent staining solution from the first storage cavity to the second storage cavity.

3. The fluorescence dye transfer device based on the technology of the Internet of things according to claim 2, wherein the transfer device further comprises an output cavity, a second output end of the transmission mechanism is communicated with the output cavity,

and the steps executed by the control module further include:

when the control module judges that the current storage environment evaluation index belongs to the environment evaluation index threshold range, the control module controls the transmission mechanism to transmit a target container corresponding to the target fluorescent staining solution from the first storage cavity to the output cavity.

4. The fluorescence dye transfer device based on the internet of things technology according to claim 3, wherein the control module controls the data analysis module to determine a current storage environment evaluation index according to the current storage environment parameter dataset and the storage environment standard parameter, and an algorithm is adopted as follows:

,

in the method, in the process of the invention,indicating the current storage environment evaluation index corresponding to the target fluorescent dye,/->Sample number indicating the current storage environment parameter of the first storage chamber for storing the target fluorescent dye,/->A total number of samples representing a current storage environment parameter of a first storage chamber for storing said target fluorescent staining solution, <>A first storage chamber for storing the target fluorescent staining solution is shown>Current temperature value of individual samples,/->A first storage chamber for storing the target fluorescent staining solution is shown>Current humidity value of individual samples,/->A first storage chamber for storing the target fluorescent staining solution is shown>Current luminance value of individual samples,/->A temperature threshold value representing a storage environment for storing the target fluorescent staining solution,/for>A humidity threshold value representing a storage environment for storing the target fluorescent staining solution,/a>A brightness threshold value representing a storage environment for storing the target fluorescent staining solution.

5. The fluorescence dye transfer device based on the Internet of things technology according to claim 4, further comprising a humidity control module electrically connected with the control module, wherein the humidity control module is used for controlling the internal humidity of the first storage cavity,

and the steps executed by the control module further include:

the control module obtains instantaneous humidity values of a plurality of detection points in the first storage cavity storing the target fluorescent dye through the sensor module;

the control module controls the data analysis module to determine a plurality of humidity gradient vectors in the first storage cavity according to the instantaneous humidity value and the position of the corresponding detection area;

the control module controls the data analysis module to determine the current humidity gradient evaluation index of the interior of the first storage cavity according to the humidity gradient vector;

the control module establishes communication connection with the management platform through the communication module and acquires a humidity gradient evaluation index threshold range related to the interior of the first storage cavity from the management platform;

the control module judges whether the current humidity gradient evaluation index belongs to a humidity gradient evaluation index threshold range, if yes, the control module sends third feedback information to the management platform to enable the management platform to record the current humidity gradient evaluation index, and if not, the control module controls the humidity regulation module to operate to enable the humidity gradient evaluation index of the next stage to belong to the humidity gradient evaluation index threshold range.

6. The fluorescence staining transfer device based on the internet of things of claim 5, wherein the control module controls the data analysis module to determine the current humidity gradient evaluation index of the interior of the first storage cavity according to the humidity gradient vector by using the following algorithm:

，

in the method, in the process of the invention,a current humidity gradient evaluation index indicating the interior of said first storage chamber,/>A serial number, < > -representing the humidity gradient vector of the interior of the first storage chamber determined by the data analysis module>Representing the number of humidity gradient vectors, < > -of the interior of the first storage chamber determined by the data analysis module>Representing the first part of the interior of the first storage chamber determined by the data analysis module>Coordinate values of the end point of each humidity gradient vector in the X-axis direction of the second space rectangular coordinate system constructed in advance, +>Representing the first part of the interior of the first storage chamber determined by the data analysis module>Coordinate values of the end point of each humidity gradient vector in the Y-axis direction of the second space rectangular coordinate system constructed in advance, +>Representing the first part of the interior of the first storage chamber determined by the data analysis module>The coordinate values of the end points of the humidity gradient vectors in the Z-axis direction of a second pre-constructed space rectangular coordinate system, wherein the second pre-constructed space rectangular coordinate system comprises an X-axis representing the humidity variation in the horizontal direction, a Y-axis representing the humidity variation in the vertical direction and a Z-axis representing the humidity variation in the vertical direction, the X-axis, the Y-axis and the Z-axis are orthogonal to an O point in pairs, and the zero vector in the second space rectangular coordinate system corresponding to the O point is a humidity reference vector.