CN113049841A - Quality control product output setting method, quality control testing method and sample analysis system - Google Patents

Abstract

A setting method of quality control product output, a quality control testing method and a sample analysis system are used for obtaining the information of the quality control product; controlling the quality control test of the quality control product according to the information of the quality control product; acquiring an output mode corresponding to the quality control product according to the information of the quality control product; and controlling to output the quality control product after the quality control test according to the output mode corresponding to the quality control product. This application provides different and nimble output mode to the matter of controlling, labour saving and time saving, and is very convenient.

Description

Quality control product output setting method, quality control testing method and sample analysis system

Technical Field

The invention relates to a setting method of quality control product output, a quality control testing method and a sample analysis system.

Background

Before a patient sample is tested, quality control testing needs to be carried out on test items of a patient, so that the state of corresponding items of an instrument is checked, if the result of the quality control testing is abnormal, namely, is out of control, the current state of the instrument cannot guarantee the accuracy of the test result obtained after the out of control item is carried out on the patient sample, at this time, the out of control item of the instrument needs to be subjected to out of control processing, for example, the out of control item is tested again to confirm whether the out of control is carried out, for example, the quality control item is replaced, for example, the reagent is replaced, and the patient sample cannot be tested until the out of control item is controlled again, and the accuracy of the item test result of the patient sample cannot be guaranteed by the instrument.

Generally, a user puts a quality control product into a putting-in area of the sample analysis equipment every day, and after the quality control test is finished, the sample analysis equipment outputs the quality control product to a recovery area of the sample analysis equipment for the user to take out.

However, with the demand for a large number of samples to be measured, a sample analysis system in which a plurality of sample analysis devices are cascaded has been developed in order to meet the demand for high throughput and reduced time. For such a system including a plurality of analysis devices, generally, a sample to be tested is input at a front end of the system (e.g., an input module of the front end of the system) uniformly, and then the system distributes the sample to be tested to the corresponding one or more analysis devices in sequence for testing. In particular, the system typically incorporates a track by which the input module is connected to the various analytical devices so that a sample can pass from the input module to any one of the analytical devices for testing.

In such a sample analysis system in which a plurality of sample analysis devices are connected in cascade, it is understood that a quality control test needs to be performed for each sample analysis device. If the quality control product is put in the putting-in area of each sample analysis device like the previous single machine, time and labor are wasted, and more serious problems are that in many cases, the same quality control product needs to be subjected to quality control test in a plurality of sample analysis devices, after the quality control test of one sample analysis device is finished, a user needs to pick out the corresponding quality control product in the recycling area of the sample analysis device in time and put the corresponding quality control product in other sample analysis devices.

Disclosure of Invention

In order to solve the above problems, the present application provides a setting method of quality control product output, a quality control testing method, and a sample analysis system.

According to a first aspect, an embodiment provides a setting method of a quality control product output, including:

generating a quality control product output setting interface, wherein each quality control product scheduling setting interface comprises quality control product items and corresponding output mode items;

and responding to the operation of the quality control product output setting interface, and setting the quality control product in the quality control product item as the output mode in the corresponding output mode item.

In one embodiment, the setting the quality control item in the quality control item to the output mode in the corresponding output mode item in response to the operation on the quality control item output setting interface includes:

in response to the operation on the output mode entry, setting the quality control in the quality control entry as the output mode in the corresponding output mode entry; the output mode comprises a first mode of saving to the on-line refrigeration storage module and a second mode of outputting to the output module.

In one embodiment, in response to the operation on the quality control output setting interface, setting the quality control in the quality control entry to the output mode in the corresponding output mode entry, further includes:

the first mode of saving the data in the online refrigeration storage module also corresponds to a saving time item;

and responding to the operation of the preservation time item, and setting the preservation time of the corresponding quality control product to the on-line refrigeration storage module.

In one embodiment, in response to the operation on the quality control output setting interface, setting the quality control in the quality control entry to the output mode in the corresponding output mode entry, further includes:

the second mode of outputting to the output module is also corresponding to whether the item is added or not;

and responding to the operation of the item which is covered or not, and setting whether the corresponding quality control product is covered or not when being output to the output module.

In one embodiment, in response to the operation on the quality control output setting interface, setting the quality control in the quality control entry to the output mode in the corresponding output mode entry, further includes:

the quality control product output setting interface also comprises a capping area setting item;

setting a region where the capped quality control items output to the output module are output to the output module in response to an operation of setting an entry for the capped region;

and/or the presence of a gas in the gas,

the quality control product output setting interface also comprises uncovered area setting items;

in response to an operation of setting an entry for the capped area, setting an area where uncapped quality control items output to the output module are output to the output module.

According to a second aspect, an embodiment provides a method of quality control testing, comprising:

acquiring information of a quality control product;

controlling the quality control test of the quality control product according to the information of the quality control product;

acquiring an output mode corresponding to the quality control product according to the information of the quality control product;

and controlling to output the quality control product after the quality control test according to the output mode corresponding to the quality control product.

In an embodiment, the controlling the output of the quality control product completed by the quality control project according to the output mode corresponding to the quality control product includes:

and when the output mode corresponding to the quality control product is the first mode of storing the quality control product in the online refrigeration storage module, controlling the quality control product after the quality control test to be stored in the online refrigeration storage module.

In one embodiment, the first mode further comprises the number of days of storage of the online refrigeration storage module;

after the quality control product after the quality control test is stored in the online refrigeration storage module, scheduling the quality control product from the online refrigeration storage module for quality control test each day of the storage days;

if the current day is the last day of the storage days, the control product is output to the output module after the quality control test is finished, otherwise, the control product is still stored in the on-line refrigeration storage module.

In an embodiment, the controlling the output of the quality control product completed by the quality control project according to the output mode corresponding to the quality control product includes:

and when the output mode corresponding to the quality control product is the second mode of outputting to the output module, controlling to output the quality control product subjected to the quality control test to the output module.

In one embodiment, the second mode further comprises whether the cover is covered or not;

when the output mode corresponding to the quality control product is output to the output module and covered, the quality control product which is finished by the quality control test is controlled to be covered, and then the quality control product is output to the output module;

and when the output mode corresponding to the quality control product is output to the output module without covering, directly controlling to output the quality control product subjected to the quality control test to the output module.

In one embodiment, the output mode further comprises a covered area and an uncovered area, the covered area is used for limiting the area where the covered quality control products output to the output module are output to the output module, and the uncovered area is used for limiting the area where the uncovered quality control products output to the output module are output to the output module.

According to a third aspect, an embodiment provides a sample analysis system comprising:

the input module is used for receiving a sample put in by a user;

a plurality of analytical devices for testing the sample;

a post-processing module comprising one or more of a capping module, a refrigerated storage module, and a decapping module; the capping module is used for capping the sample; the refrigeration storage module is used for storing samples; the decapping module is used for decapping a sample;

the output module is used for receiving the tested sample;

a track connecting the input module, each analysis device, the post-processing module and the output module; and scheduling means for scheduling the samples by the track;

a processor for performing a method as in any embodiment herein.

According to a fourth aspect, an embodiment provides a computer readable storage medium comprising a program executable by a processor to implement a method as described in any of the embodiments herein

According to the setting method of the quality control product output, the quality control testing method, the sample analysis system and the computer readable storage medium of the embodiment, different and flexible output modes are provided for the quality control product, and the method is time-saving, labor-saving and very convenient.

Drawings

FIG. 1 is a schematic diagram of a sample analysis system according to an embodiment;

FIG. 2 is a schematic diagram of a sample analysis system according to another embodiment;

FIG. 3 is a schematic diagram of a preprocessing module according to an embodiment;

FIG. 4 is a schematic diagram of an exemplary aftertreatment module;

FIG. 5 is a schematic diagram of a sample analysis system according to yet another embodiment;

FIG. 6 is an example of a quality control output setting interface according to an embodiment;

FIG. 7 is an example of an output setting interface of a quality control product in another embodiment;

FIG. 8 is a view showing an example of an output setting interface of a quality control product in still another embodiment;

FIG. 9 is a flowchart of a method of quality control testing according to an embodiment;

FIG. 10 is a flowchart of a setting method of quality control product output according to an embodiment.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings. Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings).

As can be understood from the above background art, in a sample analysis system formed by cascading a plurality of sample analysis devices, if a user puts a quality control product in the putting area of each single machine to complete a quality control test on each sample analysis device in the sample analysis system, there are many inconveniences. In order to solve this problem, the applicant has proposed the present application; before describing the present application, a description of a sample analysis system will be provided.

Referring to fig. 1, the sample analysis system in some embodiments includes an input module 10, a plurality of analysis devices 30, a post-processing module 40, an output module 50, a track 60, a scheduling device 70, and a processor 80; referring to fig. 2, the sample analysis system in some embodiments may further include a preprocessing module 20, which is described in detail below.

The input module 10 is used for receiving samples put by users. The input module 10 is a place where a user uniformly puts a sample to be tested in the sample analysis system, when the sample analysis system works, the input component 10 can automatically scan the sample put in the sample to obtain identification information of the sample, and information such as a sample number and a project to be tested can be obtained through the identification information of the sample.

The preprocessing module 20 is configured to preprocess the sample to be tested received by the input module 10. Generally, after a user puts a sample into the input module 10, the input module 20 scans the sample, the scheduling device 60 then schedules the sample into the preprocessing module 20 for preprocessing, and the preprocessed sample is then scheduled from the preprocessing module 20 into the corresponding analysis device 30 for testing. In one embodiment, referring to fig. 3, the pre-processing module 20 may include one or more of a centrifuge module 21, a serum detection module 22, a decapping module 23, and a dispensing module 24. The centrifuge modules 21 are used for centrifuging the sample to be centrifuged, and the number of the centrifuge modules 21 may be one or more. The serum test module 22 is used to determine whether the serum amount of the sample is sufficient and/or whether the serum quality of the sample is acceptable, so as to determine whether the centrifuged sample can be used for subsequent determination. The decapping module 23 is used for decapping the centrifuged sample — as will be understood, the term decapping and decapping the sample herein refers to the process of capping and decapping a sample tube containing the sample; typically, the sample needs to be uncapped after centrifugation for subsequent dispensing or pipetting by the dispensing module 24 or the analytical device 30. The dispensing module 24 is used for dispensing a sample, for example, dividing a sample into a plurality of samples, to be sent to different analysis devices 30 for measurement. The preprocessing module 20 generally has a preprocessing flow: the centrifugal module 21 receives the sample scheduled by the input module 20 and centrifuges the sample; the serum detection module 22 detects serum of the centrifuged sample, and judges whether the serum can be used for subsequent measurement, and if the serum is insufficient in amount or unqualified in quality, the serum cannot be used for subsequent measurement; if the detection is passed, the sample is dispatched to the decapping module 23, the decapping module 23 removes the cap of the sample, if the dispensing module 24 exists, the dispensing module 24 sorts the sample with the cap removed, then the sorted sample is dispatched to the corresponding analysis equipment 30 for measurement, and if the dispensing module 24 does not exist, the sample is dispatched from the decapping module 23 to the corresponding analysis equipment 30 for measurement. It should be noted that the preprocessing module 20 is not required, and the sample analysis system of some embodiments may not include the preprocessing module 20, for example, fig. 1 is an example, and the sample analysis system of some embodiments may also include the preprocessing module 20, for example, fig. 2 is an example, and in the sample analysis system not including the preprocessing module 20, the sample coming out from the input module 10 is scheduled to be measured in the corresponding analysis device 30.

The analysis device 30 is used to perform a test on the sample. To improve efficiency and test throughput, typically, the sample analysis system has a plurality of analysis devices 30, and these analysis devices 30 may be the same type of analysis device or different types of analysis devices, which may be configured according to the needs of the user and the department. The analysis device 30 may be, for example, a biochemical analysis device, an immunoassay device, a coagulation analysis device, or the like.

The post-processing module 40 is used to complete post-processing of the sample. In one embodiment, referring to fig. 4, the post-processing module 40 includes one or more of a capping module 41, a refrigerated storage module 42, and a decapping module 43. A capping module 41 for capping the sample; the refrigerated storage module 42 is used for storing samples, and the refrigerated storage module 42 can be a refrigerator and the like; the decapping module 43 is used to decap the sample. One typical post-processing flow for the post-processing module 40 is: after all items needing to be measured of the sample are sucked in the corresponding analysis equipment 30, the sample is dispatched to a capping module 41, the capping module 41 caps the measured sample, and then the sample is dispatched to a refrigeration storage module 42 for storage; if the sample requires retesting, the sample is dispatched from the refrigerated storage module 42, uncapped in the decapping module 43, and then dispatched to the corresponding analytical device 30 for testing.

The output module 50 is used for receiving the tested sample. The output module 50 corresponds to the input module 10, the input module 10 is a place where the sample analysis system uniformly inputs the sample, the output module 50 is a place where the sample analysis system uniformly outputs the sample, and for the sample which does not need to be determined whether to be retested, the sample is dispatched to the output module 50 for the user to recover after being tested in each analysis device 30; for samples that need to be retested, the retesting is not needed when the samples are determined to be retested, or the samples are generally scheduled to the output module 50 for the user to retrieve after the samples are determined to be retested and retested.

The track 60 is used for connecting modules and components, such as the input module 10, the analysis device 30, the post-processing module 40, the output module 50, and the like, and the scheduling device 70 is used for scheduling samples through the track 60. Thus, the scheduling means 60 may schedule samples from the input module 10 to the analysis devices 30, between the analysis devices 30, from the analysis devices 30 to the post-processing module 40, and from the post-processing module 40 or the analysis devices 30 to the output module 50 by means of a track. In a sample analysis system comprising a pre-processing module 20, the track 60 also connects the pre-processing module 20, so that the scheduling means 70 may schedule samples from the input module 10 to the pre-processing module 20, from the pre-processing module 20 to the analysis devices 30, between the analysis devices 30, from the analysis devices 30 to the post-processing module 40, and from the post-processing module 40 or the analysis devices 30 to the output module 50 via the track.

Fig. 5 is an example of a sample analysis system of the present application. As shown in fig. 5, each device or module may also be provided with a module buffer, and the entire track may be a circular track. It should be noted that there are only one module or component shown in the drawings, but those skilled in the art will understand that the number is not limited herein, for example, there may be more centrifugal modules 21, more decapping modules 23, etc.

The above is an explanation of the sample analysis system in conjunction with the test flow of the sample.

Similarly, the user can put the quality control product into the input module 10, which is the place where the sample is uniformly input into the sample analysis system, so that the quality control product does not need to be pre-processed, and therefore the quality control product can be dispatched from the input module 10 to the corresponding analysis device 30 for quality control testing, and after the quality control testing is finished, the quality control product can be dispatched to the place where the sample is uniformly output from the sample analysis system, which is the output module 50. The quality control is output to the output module 50 and then processed by the user. The user either rejects the quality control, i.e., picks out the corresponding quality control from which it is no longer used, or picks out some quality controls that can be used next (e.g., the next day, etc.) and files them to the online storage module 42 or the offline storage module — in some cases, the offline storage module may have a much lower cooling temperature than the online storage module 42; after archiving the quality control, when the quality control needs to be reused, the user needs to manually take the quality control out of the off-line refrigerated storage module again and put the quality control into the sample analysis system, or to make the sample analysis system call out of the on-line refrigerated storage module 42 at regular time.

In other embodiments, the user may use a filing function, that is, the user puts the quality control product into the input module 10, which is the location where the sample is uniformly input by the sample analysis system, and then the quality control product is directly dispatched to the online refrigerated storage module 42 for filing, after filing, the sample analysis system will dispatch the quality control product from the online refrigerated storage module 42 at regular time (for example, 8 am next morning) and finally dispatch the quality control product to the corresponding analysis device 30 for quality control testing, after the quality control testing is completed, the quality control product will be dispatched to the output module 50, which is the location where the sample is uniformly output by the sample analysis system, and then wait for the user to process, for example, as described above, the quality control product is discarded or the online or offline filing is performed.

It can be seen that the quality control tests are dispatched to the output module 50 for the user to process after the current quality control test is completed, which is complicated and inconvenient. This application can control the output of matter of controlling. Specifically, in some embodiments, the processor 80 obtains information about the quality control item — for example, the processor 80 obtains information about the quality control item by scanning the quality control item through the input module 10; the processor 80 controls the quality control test of the quality control product according to the information of the quality control product, for example, the quality control product is dispatched to the corresponding analysis equipment 30 for quality control test; the processor 80 obtains the output mode corresponding to the quality control product, namely the output mode corresponding to each quality control product, according to the information of the quality control product, wherein the output modes can be preset when the system leaves a factory, and can also be set by a user through a human-computer interaction interface; the processor 80 controls the output of the quality control product after the quality control test according to the output mode corresponding to the quality control product — understandably, the quality control product after the quality control test refers to the quality control product which is subjected to the quality control test on the corresponding analyzing device 30 (which may be one or more) in the sample analyzing system at the present time, for example, 8 am of the sample analyzing system needs to perform one quality control test on each analyzing device, and the quality control product a needs to perform the quality control test on two analyzing devices, so that the quality control product a is output according to the corresponding output mode after the quality control product completes the quality control test on the two analyzing devices.

The quality control product can be dispatched to the online refrigeration storage module 42 or directly dispatched to the output module 50 according to the corresponding output mode, wherein it can be understood that the quality control product is in a decapped state at this time, which generally means that the quality control product is dispatched to the output module 50 and then discarded by a user, or is dispatched to the output module 50 after being capped, which generally means that the quality control product is dispatched to the output module 50 and then manually filed by the user and then put into the offline refrigeration storage module for storage. Thus, some embodiments of the present application provide a first way of saving to an online refrigerated storage module, and/or a second way of outputting to an output module. This will be explained in detail below.

In the first mode, the on-line refrigeration storage module stores the quality control product after the quality control test, as the name implies, in the on-line refrigeration storage module. Therefore, in some embodiments, when the output mode corresponding to the quality control product is the first mode of saving to the online refrigeration storage module, the processor 80 controls to save the quality control product after the quality control test to the online refrigeration storage module 42; in some embodiments, the first mode further includes the number of days of storage of the quality control test in the on-line refrigeration storage module, and then the processor 80 dispatches the quality control test from the on-line refrigeration storage module 42 for each of the following days of storage after controlling the quality control test to be completed in the on-line refrigeration storage module 42; if the current day is the last day of the storage days, the control product is output to the output module 50 after the quality control test is finished, otherwise, the control product is still stored in the on-line refrigeration storage module 42. For example, the output mode corresponding to the quality control product a is stored in the on-line refrigeration storage module for 3 days, so that the quality control product a is dispatched to the on-line refrigeration storage module 42 for storage after the quality control test is performed for the first time and is completed, the first day of the following, the test is scheduled for quality control testing, and after the quality control testing is finished, the test is scheduled to be stored by the on-line refrigeration storage module 42, and similarly, the next day, the test is dispatched to carry out the quality control test, and after the quality control test is finished, the test is dispatched to the on-line refrigeration storage module 42 to be stored, on the next third day, that is, the last day of storage, the quality control product a is dispatched to perform the quality control test, and after the quality control test is completed, the quality control product a is dispatched to the output module 50 to be output — understandably, the quality control product a is uncovered, and the output module 50 waits for the user to perform the discarding process.

In the second mode, the quality control product after the quality control test is output to the output module as the name suggests, and in some embodiments, the second mode further includes whether to cover the quality control product before the quality control product after the test is output to the output module. Therefore, in some embodiments, when the output mode corresponding to the quality control product is the second output mode to the output module, the processor 80 controls to output the quality control product after the quality control test to the output module 50; in some embodiments, the second method further comprises covering or not; therefore, when the output mode corresponding to the quality control product is output to the output module and the output module is capped, the processor 80 controls the capping of the quality control product after the quality control test is completed, and then the output module is output; when the output mode corresponding to the quality control product is to output the quality control product to the output module without covering the output module, the processor 80 directly controls to output the quality control product subjected to the quality control test to the output module.

In the first or second mode, the final quality control product is dispatched to the output module 50, and for the first mode, the final dispatch of the quality control product to the output module 50 is generally discarded by the user; in the second mode, the quality control items are dispatched to the output module 50 either for disposal by the user or for manual archiving by the user to an off-line refrigerated storage module, at which time the quality control items are typically capped in the post-processing module. In order to facilitate the user to quickly pick out which quality control articles are to be discarded and which quality control articles are to be filed to the offline refrigerated storage module, the output mode may further include a covered region and an uncovered region, the covered region is used for limiting the region where the covered quality control articles output to the output module are output to the output module, and the uncovered region is used for limiting the region where the uncovered quality control articles output to the output module are output to the output module. For example, the output module 50 has a total of 5 placement areas numbered 1 to 5, each placement area has a total of 30 sample rack areas numbered 1 to 30, and each sample rack area can be placed with one sample rack, so that each placement area can be placed with 30 sample racks. Sample rack areas of serial numbers 1 to 10 in the placement area of serial number 1 may be set as a capped area, and sample rack areas of serial numbers 1 to 30 in the placement area of serial number 5 may be set as an uncapped area; accordingly, the other regions may be regions where the sample is recovered and output after the test is completed. The covered area and the uncovered area can be preset or better when the system leaves a factory, and can also be set by a user through a related interactive interface.

The following describes how a user outputs a quality control product through an interactive interface.

In some embodiments, the processor 80 may generate a quality control output setting interface, where each quality control scheduling setting interface includes a quality control item and a corresponding output mode item; in response to the operation of the quality control output setting interface, the processor 80 sets the quality control in the quality control entry to the output mode in the corresponding output mode entry. Specifically, in some embodiments, in response to an operation on an output mode entry, the processor 80 sets a quality control in the quality control entry to the output mode in the corresponding output mode entry; the output mode comprises a first mode of saving to the on-line refrigeration storage module and a second mode of outputting to the output module. Fig. 6 is an example of a quality control output setting interface. The user can input the quality control product in the quality control product item through an input tool such as a keyboard, and select the corresponding output mode through a drop-down frame and the like in the output mode item, and what is shown in the figure is a mode I that the quality control products A, B and C select to be stored in the online refrigeration storage module, a mode II that the quality control products D and E select to be output to the output module, and a mode II that the quality control product F selects to be output to the output module.

For mode one, in some embodiments, mode one of saving to the online refrigerated storage module also corresponds to a save time entry. In response to the operation on the hold time entry, the processor 80 sets a hold time for the corresponding quality control to be saved to the online refrigerated storage module. For example, FIG. 7 illustrates an example where quality controls A, B and C have been selected to have a storage time of 2 days. The user may enter the number of days saved in the save time entry via an input tool such as a keyboard.

For mode two, in some embodiments, mode two output to the output module also corresponds to whether an entry is covered or not. In response to the operation of the capping or uncapping entry, the processor 80 sets capping or uncapping when the corresponding quality control is output to the output module. For example, referring to fig. 7, the quality control products D and E select the second mode of output to the output module without being covered; and the quality control product F selects a second mode of outputting to the output module and is covered. The user may select whether to cover or uncover by clicking a drop-down box that covers or uncovers an item with a mouse or the like.

In some embodiments, the quality control output setting interface may further include an add button and/or a delete button. In response to clicking the add button, processor 80 adds the quality control item and its corresponding output mode item. And responding to the click of the deletion key, and deleting the quality control item and the corresponding output mode item which are selected by the processor.

In the first or second embodiment, the region in which the quality control product is finally output to the output module may be set, and in the first embodiment, the quality control product which is finally output to the output module is in an uncapped state, and in the second embodiment, the quality control product which is most output to the output module may be in a capped state or uncapped state; in some embodiments, different areas are set in the output module for outputting the quality control product according to whether the quality control product is covered or not. In some embodiments, the quality control output setting interface further comprises a capped area setting entry; in response to the operation of setting the entry for the capped area, the processor 80 sets the area where the capped quality control items output to the output module are output to the output module. In some embodiments, the quality control output setting interface further comprises uncapped zone setting entries; in response to the operation of setting the entry for the capped area, the processor 80 sets the area where the uncapped quality control output to the output module is output to the output module. Fig. 8 is an example in which the sample rack areas of serial numbers 1 to 10 in the placement area of serial number 1 are set as the capping area, that is, the area where the capped quality control items output to the output module are output to the output module; the sample rack regions of serial numbers 1 to 30 in the placement region of serial number 5 are set as uncapped regions, i.e., regions where uncapped quality controls output to the output module are output to the output module.

The foregoing is a description of a sample analysis system in some embodiments of the present application. In some embodiments, a method of quality control testing is also disclosed, which is applied to a sample analysis system including a plurality of analysis devices, such as the sample analysis system disclosed herein.

Referring to fig. 9, the quality control testing method in some embodiments includes the following steps:

step 100: and acquiring the information of the quality control product. For example, step 100 scans the quality control item through the input module 10 to obtain information about the quality control item.

Step 110: and controlling the quality control test of the quality control product according to the information of the quality control product.

Step 120: and acquiring the output mode corresponding to the quality control product according to the information of the quality control product. The output mode corresponding to each quality control product can be preset when the system leaves a factory, or can be set by a user through a human-computer interaction interface.

Step 130: and controlling to output the quality control product after the quality control test according to the output mode corresponding to the quality control product. The quality control may be dispatched to the online storage module 42 or directly to the output module 50 based on its corresponding output, thus providing in some embodiments of the present application a first means of saving to the online storage module and/or a second means of outputting to the output module.

In the first mode, the on-line refrigeration storage module stores the quality control product after the quality control test, as the name implies, in the on-line refrigeration storage module. Therefore, in some embodiments, when the output mode corresponding to the quality control product is the first mode of saving to the online refrigeration storage module, step 130 controls to save the quality control product after the quality control test to the online refrigeration storage module 42; in some embodiments, the first mode further includes the number of days of storage of the quality control test in the online refrigeration storage module, then step 130 dispatches the quality control product from the online refrigeration storage module 42 for the quality control test each day of the number of days of storage after controlling the quality control product with the quality control test in the online refrigeration storage module 42; if the current day is the last day of the storage days, the control product is output to the output module 50 after the quality control test is finished, otherwise, the control product is still stored in the on-line refrigeration storage module 42. For example, the output mode corresponding to the quality control product a is stored in the on-line refrigeration storage module for 3 days, so that the quality control product a is dispatched to the on-line refrigeration storage module 42 for storage after the quality control test is performed for the first time and is completed, the first day of the following, the test is scheduled for quality control testing, and after the quality control testing is finished, the test is scheduled to be stored by the on-line refrigeration storage module 42, and similarly, the next day, the test is dispatched to carry out the quality control test, and after the quality control test is finished, the test is dispatched to the on-line refrigeration storage module 42 to be stored, on the next third day, that is, the last day of storage, the quality control product a is dispatched to perform the quality control test, and after the quality control test is completed, the quality control product a is dispatched to the output module 50 to be output — understandably, the quality control product a is uncovered, and the output module 50 waits for the user to perform the discarding process.

In the second mode, the quality control product after the quality control test is output to the output module as the name suggests, and in some embodiments, the second mode further includes whether to cover the quality control product before the quality control product after the test is output to the output module. Therefore, in some embodiments, when the output mode corresponding to the quality control product is the second output mode to the output module, step 130 controls to output the quality control product after the quality control test to the output module 50; in some embodiments, the second method further comprises covering or not; therefore, when the output mode corresponding to the quality control product is to output the quality control product to the output module and cover the output module, step 130 controls to cover the quality control product after the quality control test is completed, and then output the quality control product to the output module; when the output mode corresponding to the quality control product is to output the quality control product to the output module without covering, step 130 directly controls to output the quality control product after the quality control test to the output module.

In the first or second mode, the final quality control product is dispatched to the output module 50, and for the first mode, the final dispatch of the quality control product to the output module 50 is generally discarded by the user; in the second mode, the quality control items are dispatched to the output module 50 either for disposal by the user or for manual archiving by the user to an off-line refrigerated storage module, at which time the quality control items are typically capped in the post-processing module. In order to facilitate the user to quickly pick out which quality control articles are to be discarded and which quality control articles are to be filed to the offline refrigerated storage module, the output mode may further include a covered region and an uncovered region, the covered region is used for limiting the region where the covered quality control articles output to the output module are output to the output module, and the uncovered region is used for limiting the region where the uncovered quality control articles output to the output module are output to the output module. For example, the output module 50 has a total of 5 placement areas numbered 1 to 5, each placement area has a total of 30 sample rack areas numbered 1 to 30, and each sample rack area can be placed with one sample rack, so that each placement area can be placed with 30 sample racks. Sample rack areas of serial numbers 1 to 10 in the placement area of serial number 1 may be set as a capped area, and sample rack areas of serial numbers 1 to 30 in the placement area of serial number 5 may be set as an uncapped area; accordingly, the other regions may be regions where the sample is recovered and output after the test is completed. The covered area and the uncovered area can be preset or better when the system leaves a factory, and can also be set by a user through a related interactive interface.

As described above, the output mode corresponding to the quality control product obtained in step 120 may be preset when the system is shipped from the factory, or may be set by the user through the human-computer interface. The following describes how a user outputs a quality control product through an interactive interface.

Referring to fig. 10, in some embodiments of the present application, a method for setting an output of a quality control product is further disclosed, which includes the following steps:

step 200: and generating a quality control product output setting interface, wherein each quality control product scheduling setting interface comprises quality control product items and corresponding output mode items.

Step 210: and responding to the operation of the quality control product output setting interface, and setting the quality control product in the quality control product item as the output mode in the corresponding output mode item.

Specifically, in some embodiments, in response to an operation on an output mode entry, step 210 sets a quality control in the quality control entry to an output mode in the corresponding output mode entry; the output mode comprises a first mode of saving to the on-line refrigeration storage module and a second mode of outputting to the output module. Fig. 6 is an example of a quality control output setting interface. The user can input the quality control product in the quality control product item through an input tool such as a keyboard, and select the corresponding output mode through a drop-down frame and the like in the output mode item, and what is shown in the figure is a mode I that the quality control products A, B and C select to be stored in the online refrigeration storage module, a mode II that the quality control products D and E select to be output to the output module, and a mode II that the quality control product F selects to be output to the output module.

For mode one, in some embodiments, mode one of saving to the online refrigerated storage module also corresponds to a save time entry. In response to the operation on the hold time entry, step 210 sets a hold time for the corresponding quality control to be saved to the online refrigerated storage module. For example, FIG. 7 above is an example, where quality controls A, B and C are selected to have a shelf life of 2 days. The user may enter the number of days saved in the save time entry via an input tool such as a keyboard.

For mode two, in some embodiments, mode two output to the output module also corresponds to whether an entry is covered or not. In response to the operation of the capped or uncapped item, step 210 sets whether the corresponding quality control item is to be capped or uncapped when output to the output module. For example, referring to fig. 7, the quality control products D and E are selected to be outputted to the output module in the second mode without being covered; and the quality control product F selects a second mode of outputting to the output module and is covered. The user may select whether to cover or uncover by clicking a drop-down box that covers or uncovers an item with a mouse or the like.

In the first or second embodiment, the region in which the quality control product is finally output to the output module may be set, and in the first embodiment, the quality control product which is finally output to the output module is in an uncapped state, and in the second embodiment, the quality control product which is most output to the output module may be in a capped state or uncapped state; in some embodiments, different areas are set in the output module for outputting the quality control product according to whether the quality control product is covered or not. In some embodiments, the quality control output setting interface further comprises a capped area setting entry; in response to the operation of setting an entry for the capped area, step 210 sets the area where capped quality control items output to the output module are output to the output module. In some embodiments, the quality control output setting interface further comprises uncapped zone setting entries; in response to the operation of setting an entry for the capped area, step 210 sets an area where uncapped quality controls output to the output module are output to the output module. Fig. 8 is an example, in which the sample rack areas of serial numbers 1 to 10 in the placement area of serial number 1 are set as the capping area, that is, the capped quality control items output to the output module are output to the output module; the sample rack regions of serial numbers 1 to 30 in the placement region of serial number 5 are set as uncapped regions, i.e., regions where uncapped quality controls output to the output module are output to the output module.

To sum up, in the present application, after the quality control product is put into the input module 10 by the user, the quality control test can be performed, and then the corresponding output processing is performed according to the corresponding output mode, for example, the quality control product is stored in the on-line refrigeration storage module or directly output to the output module 50; of course, in some examples, after the quality control product is put into the input module 10 by the user, the quality control product may be filed into the on-line cold storage module through the sample analysis system, then the on-line cold storage module is called out at regular time (for example, 8 pm in the next day) to perform the quality control test, and after the quality control test is performed, the corresponding output processing is performed according to the corresponding output mode, for example, the quality control product is stored in the on-line cold storage module or directly output to the output module 50.

Reference is made herein to various exemplary embodiments. However, those skilled in the art will recognize that changes and modifications may be made to the exemplary embodiments without departing from the scope hereof. For example, the various operational steps, as well as the components used to perform the operational steps, may be implemented in differing ways depending upon the particular application or consideration of any number of cost functions associated with operation of the system (e.g., one or more steps may be deleted, modified or incorporated into other steps).

In the above embodiments, the implementation may be wholly or partially realized by software, hardware, firmware, or any combination thereof. Additionally, as will be appreciated by one skilled in the art, the principles herein may be reflected in a computer program product on a computer readable storage medium, which is pre-loaded with computer readable program code. Any tangible, non-transitory computer-readable storage medium may be used, including magnetic storage devices (hard disks, floppy disks, etc.), optical storage devices (CD-to-ROM, DVD, Blu-Ray discs, etc.), flash memory, and/or the like. These computer program instructions may be loaded onto a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions which execute on the computer or other programmable data processing apparatus create means for implementing the functions specified. These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including means for implementing the function specified. The computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified.

While the principles herein have been illustrated in various embodiments, many modifications of structure, arrangement, proportions, elements, materials, and components particularly adapted to specific environments and operative requirements may be employed without departing from the principles and scope of the present disclosure. The above modifications and other changes or modifications are intended to be included within the scope of this document.

The foregoing detailed description has been described with reference to various embodiments. However, one skilled in the art will recognize that various modifications and changes may be made without departing from the scope of the present disclosure. Accordingly, the disclosure is to be considered in an illustrative and not a restrictive sense, and all such modifications are intended to be included within the scope thereof. Also, advantages, other advantages, and solutions to problems have been described above with regard to various embodiments. However, the benefits, advantages, solutions to problems, and any element(s) that may cause any element(s) to occur or become more pronounced are not to be construed as a critical, required, or essential feature or element of any or all the claims. As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, system, article, or apparatus. Furthermore, the term "coupled," and any other variation thereof, as used herein, refers to a physical connection, an electrical connection, a magnetic connection, an optical connection, a communicative connection, a functional connection, and/or any other connection.

Those skilled in the art will recognize that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the invention. Accordingly, the scope of the invention should be determined only by the claims.

Claims (13)

1. A method for setting quality control product output is characterized by comprising the following steps:

generating a quality control product output setting interface, wherein each quality control product scheduling setting interface comprises quality control product items and corresponding output mode items;

and responding to the operation of the quality control product output setting interface, and setting the quality control product in the quality control product item as the output mode in the corresponding output mode item.

2. The setting method of claim 1, wherein setting the quality control in the quality control entry to the output mode in the corresponding output mode entry in response to the operation of the quality control output setting interface comprises:

in response to the operation on the output mode entry, setting the quality control in the quality control entry as the output mode in the corresponding output mode entry; the output mode comprises a first mode of saving to the on-line refrigeration storage module and a second mode of outputting to the output module.

3. The setting method of claim 2, setting a quality control in a quality control entry to an output mode in a corresponding output mode entry in response to an operation on the quality control output setting interface, further comprising:

the first mode of saving the data in the online refrigeration storage module also corresponds to a saving time item;

and responding to the operation of the preservation time item, and setting the preservation time of the corresponding quality control product to the on-line refrigeration storage module.

4. The setting method of claim 2, setting a quality control in a quality control entry to an output mode in a corresponding output mode entry in response to an operation on the quality control output setting interface, further comprising:

the second mode of outputting to the output module is also corresponding to whether the item is added or not;

and responding to the operation of the item which is covered or not, and setting whether the corresponding quality control product is covered or not when being output to the output module.

5. The setting method of claim 4, setting a quality control in a quality control entry to an output mode in a corresponding output mode entry in response to an operation on the quality control output setting interface, further comprising:

the quality control product output setting interface also comprises a capping area setting item;

setting a region where the capped quality control items output to the output module are output to the output module in response to an operation of setting an entry for the capped region;

and/or the presence of a gas in the gas,

the quality control product output setting interface also comprises uncovered area setting items;

in response to an operation of setting an entry for the capped area, setting an area where uncapped quality control items output to the output module are output to the output module.

6. A method of quality control testing, comprising:

acquiring information of a quality control product;

controlling the quality control test of the quality control product according to the information of the quality control product;

acquiring an output mode corresponding to the quality control product according to the information of the quality control product;

and controlling to output the quality control product after the quality control test according to the output mode corresponding to the quality control product.

7. The method according to claim 6, wherein the controlling of the output of the quality control item completed by the quality control item according to the output mode corresponding to the quality control item comprises:

and when the output mode corresponding to the quality control product is the first mode of storing the quality control product in the online refrigeration storage module, controlling the quality control product after the quality control test to be stored in the online refrigeration storage module.

8. The method of claim 7, wherein the first mode further comprises a number of days of storage to the on-line refrigerated storage module;

after the quality control product after the quality control test is stored in the online refrigeration storage module, scheduling the quality control product from the online refrigeration storage module for quality control test each day of the storage days;

if the current day is the last day of the storage days, the control product is output to the output module after the quality control test is finished, otherwise, the control product is still stored in the on-line refrigeration storage module.

9. The method according to claim 6, wherein the controlling of the output of the quality control item completed by the quality control item according to the output mode corresponding to the quality control item comprises:

and when the output mode corresponding to the quality control product is the second mode of outputting to the output module, controlling to output the quality control product subjected to the quality control test to the output module.

10. The method of claim 9, wherein the second mode further comprises capping or uncapping;

when the output mode corresponding to the quality control product is output to the output module and covered, the quality control product which is finished by the quality control test is controlled to be covered, and then the quality control product is output to the output module;

and when the output mode corresponding to the quality control product is output to the output module without covering, directly controlling to output the quality control product subjected to the quality control test to the output module.

11. The method of claim 10, wherein the output means further comprises a capped area for defining the area where capped quality control items output to the output module are output to the output module and an uncapped area for defining the area where uncapped quality control items output to the output module are output to the output module.

12. A sample analysis system, comprising:

the input module is used for receiving a sample put in by a user;

a plurality of analytical devices for testing the sample;

a post-processing module comprising one or more of a capping module, a refrigerated storage module, and a decapping module; the capping module is used for capping the sample; the refrigeration storage module is used for storing samples; the decapping module is used for decapping a sample;

the output module is used for receiving the tested sample;

a track connecting the input module, each analysis device, the post-processing module and the output module; and scheduling means for scheduling the samples by the track;

a processor for performing the method of any one of claims 1 to 11.

13. A computer-readable storage medium, characterized by comprising a program executable by a processor to implement the method of any one of claims 1 to 11.

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