CN114578072A - Control method of sample analysis apparatus - Google Patents

Abstract

The present application provides a method of controlling a sample analyzing apparatus. The sample analysis apparatus includes a plurality of independent analysis modules, and the control method includes: setting the working mode of the analysis module in response to a setting instruction of a user, wherein the working mode comprises a single machine mode and a pipeline mode; and carrying out differentiation control on each analysis module based on the working mode set by each analysis module. The control method of the sample analysis equipment enables a user not to start each analysis module one by one, improves the working efficiency of the user, and can meet the requirement of multi-scene user groups.

Description

Control method of sample analysis apparatus

Technical Field

The invention relates to the technical field of medical analysis equipment, in particular to a control method of sample analysis equipment.

Background

In the field of medical analysis and diagnosis, sample analysis equipment is used for detecting samples, and the samples are generally loaded on sample racks and transported through a production line so as to realize streamlined detection operation.

At present, a plurality of customized product modules or cascade products are generally purchased by a user in a pipeline operation mode and spliced according to needs, and each product module is an independent module and can be independently controlled.

However, when the production line is started, workers often need to start products of each independent module one by one, which results in low working efficiency of users; in some special scenes, when a certain instrument or module needs to be distinguished from other pipeline instruments, the system cannot distinguish the special instrument or module, and manual special treatment needs to be carried out on the special instrument or module, so that the system cannot meet the requirement of a multi-scene user group.

Disclosure of Invention

The application provides a control method of sample analysis equipment, and aims to solve the problems that when a production line is started, each independent module needs to be started, so that the working efficiency of a user is low, and a system cannot distinguish special instruments or modules, so that the system cannot meet the requirements of multi-scenario user groups.

In order to solve the technical problem, the application adopts a technical scheme that: there is provided a control method of a sample analysis apparatus including a plurality of independent analysis modules, the control method including:

and setting the working mode of the analysis module in response to a setting instruction of a user, wherein the working mode comprises a stand-alone mode and a pipeline mode.

And carrying out differentiation control on each analysis module based on the working mode set by each analysis module.

Wherein the step of setting the operation mode of the analysis module in response to a setting instruction of a user includes:

displaying a list of the analysis modules capable of performing working mode setting in the sample analysis equipment and working mode options corresponding to the analysis modules on a display interface.

And responding to the operation of the user on the working mode option, and marking the working mode of the analysis module as the stand-alone mode or the pipeline mode.

Wherein the step of setting the operation mode of the analysis module in response to a setting instruction of a user includes:

enabling the on/off reservation option of the analysis module with the working mode being the pipeline mode on a display interface, and disabling the on/off reservation option of the analysis module with the working mode being the single machine mode.

Responding to the operation of the user on the power-on/off reservation option, and associating the power-on/off reservation time for the analysis module with the working mode being the pipeline mode.

The step of performing differential control on each analysis module based on the working mode set by each analysis module comprises:

responding to a one-key starting/closing instruction or starting/closing reserved time, starting or closing the analysis module with the working mode being the pipeline mode, and keeping the analysis module with the working mode being the single machine mode in an original state.

Wherein the step of starting or stopping the analysis module of which the working mode is the pipeline mode in response to a one-key start/stop instruction or a power-on/off reservation time, and maintaining the analysis module of which the working mode is the stand-alone mode in an original state includes:

starting or closing all the analysis modules of the sample analysis device, of which the working mode is the pipeline mode, in response to a one-key starting/closing instruction, and/or starting or closing the analysis modules of which the working mode is the pipeline mode and which are associated with the starting/closing reservation time, in response to the starting/closing reservation time.

Wherein the step of starting or stopping the analysis module of which the working mode is the pipeline mode in response to a one-key start/stop instruction or a power-on/off reservation time, and maintaining the analysis module of which the working mode is the stand-alone mode in an original state includes:

during the starting process, further starting an auxiliary module related to the analysis module of which the working mode is the pipeline mode; and/or during a shutdown procedure, the auxiliary modules which are not associated with the remaining analysis modules which remain switched on.

The sample analysis equipment comprises a sample conveying module, and the step of performing differential control on each analysis module based on the working mode set by each analysis module comprises the following steps of:

controlling the sample transport module to distribute and recover samples to the analysis modules of the pipeline mode for the working mode based on a load balancing manner.

Wherein the sample analysis device comprises a sample conveying module, and the step of performing differential control on each analysis module based on the working mode set by each analysis module further comprises:

and responding to a working mode switching instruction of the analysis module in a starting state, and judging whether the current working mode of the analysis module is the pipeline mode or the single machine mode.

And if the current working mode is the production line mode, changing the working mode of the analysis module into the single machine mode, and stopping the sample conveying module from distributing and recovering the samples of the analysis module.

Wherein the sample analysis device comprises a sample conveying module, and the step of performing differential control on each analysis module based on the working mode set by each analysis module further comprises:

and if the current working mode is the single machine mode, generating an alarm.

According to the control method of the sample analysis equipment, the sample analysis equipment comprises a plurality of independent analysis modules, the working modes of the analysis modules are set by responding to the setting instructions of a user, the analysis modules are set to be in a single machine mode or a production line mode, and the analysis modules are subjected to differential control according to the working modes set by the analysis modules; the control method only needs a user to input a setting instruction corresponding to the working mode of the analysis module, and does not need to start each analysis module one by one, so that the working efficiency of the user is improved; meanwhile, the control method sets the working mode of the corresponding analysis module according to the setting instruction of the user and performs differentiation control on each analysis module, so that each analysis module can work in a single machine mode or a production line mode respectively, and the analysis modules can be controlled independently and can enter the single machine working mode in the production line in a way of being distinguished from other analysis modules, and a multi-scene user group is met.

Drawings

FIG. 1 is a schematic block diagram of one embodiment of a sample analysis device provided herein;

fig. 2 is a schematic flow chart illustrating an embodiment of a method for controlling a sample analyzer according to the present disclosure;

fig. 3 is a schematic structural diagram of an embodiment of a display interface in the control method provided in the present application;

FIG. 4 is a flowchart illustrating an embodiment of step S10 in FIG. 2;

FIG. 5 is a flowchart illustrating an embodiment of step S12 in FIG. 4;

FIG. 6 is a flowchart illustrating an embodiment of step S20 in FIG. 2;

FIG. 7 is a flowchart illustrating an embodiment of step S21 in FIG. 6;

FIG. 8 is a schematic flow chart diagram illustrating one embodiment of a pipeline mode analysis module provided herein;

FIG. 9 is a schematic flow chart diagram illustrating an embodiment of a stand-alone analysis module according to the present disclosure;

fig. 10 is a flowchart illustrating a sample detection result transmission according to an embodiment of the present disclosure.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms "first", "second" and "third" in this application are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any indication of the number of technical features indicated. Thus, a feature defined as "first," "second," or "third" may explicitly or implicitly include at least one of the feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless explicitly specifically limited otherwise. All directional indications (such as up, down, left, right, front, and rear … …) in the embodiments of the present application are only used to explain the relative positional relationship between the components, the movement, and the like in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indication is changed accordingly. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase 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. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

As described above, the sample analysis device is located in the production line, and when the production line is started, the user needs to start each independent analysis module one by one, so that the operation steps of the user are increased, the operation convenience of the sample analysis device is low, and the work efficiency of the user is reduced. Moreover, in some special scenes, for example, in the scenes of emergency treatment, the number of started instruments is less than the number of pipeline accesses, peak season management instruments for samples, instrument performance treatment, instrument out-of-control treatment and the like, when a certain analysis module in the pipeline needs to be distinguished from other analysis modules, the control system cannot identify the analysis module, and often needs a user to perform manual special treatment on the analysis module, so that the use of sample analysis equipment in multiple scenes is greatly limited, and the requirement of a multi-scene user group cannot be met.

The application provides a control method of sample analysis equipment aiming at the existing problems, wherein the sample analysis equipment comprises a plurality of independent analysis modules, a user only needs to input a setting instruction of a working mode of the corresponding analysis module, and each analysis module is not required to be started one by one, so that the user operation is reduced, the user operation convenience is improved, and the user working efficiency is improved; meanwhile, the control method can perform differentiation control on each analysis module according to a setting instruction of a user, so that the analysis modules in the assembly line can be distinguished from other analysis modules and work in a corresponding working mode without manual special processing by the user, the sample analysis equipment can be used in multiple scenes, and the user group in multiple scenes can be met.

The present application will be described in detail with reference to the accompanying drawings and examples.

Referring to fig. 1, fig. 1 is a schematic structural diagram of an embodiment of a sample analysis apparatus provided in the present application; the present embodiment provides a sample analysis apparatus, which includes a plurality of independent analysis modules 10 and sample transport modules 40, wherein the plurality of analysis modules 10 are sequentially connected by corresponding sample transport modules 40, and the sample transport modules 40 may be specifically a transport track. Each analysis module 10 comprises a corresponding unloading unit 11, a code scanning unit 12, a loading unit 13 and a sampling area 14. The sample analysis apparatus further comprises a loading channel 30 and a sample recovery section 50 connected to the transport track of the sample transport module 40 for loading a sample rack containing sample containers and recovering the tested samples, respectively. When a sample is detected, the transport track conveys a sample rack with a sample container to a corresponding analysis module 10, the unloading unit 11 unloads the sample container from the sample rack and conveys the sample container to the code scanning unit 12, the code scanning unit 12 performs code scanning operation on the sample to confirm the ID of the sample, the code scanning unit 12 conveys the sample to a sampling area 14 of the analysis module 10, the sampling analysis unit of the analysis module 10 performs sampling analysis on the sample in the sample container in the sampling area, the sample container is conveyed to the loading unit 13 after sampling is completed, and the loading unit 13 reloads the sample container to the sample rack. The sample rack is a test tube rack capable of loading a plurality of test tubes (sample containers), and the samples contained in the test tubes can be blood routine samples, CRP (C-reactive protein) samples, push-sheet samples, saccharification samples, blood coagulation samples, blood type samples, blood sedimentation samples, flow type project samples and the like. The analysis module 10 may be a blood cell analyzer, a saccharification analyzer, a blood sedimentation analyzer, a flow analyzer, a slide pusher, or the like. In this embodiment, at least one analysis module 10 of the plurality of analysis modules 10 can perform at least two items of blood routine detection, CRP detection, saccharification, push sheet detection, blood coagulation, blood type detection, blood sedimentation and flow type detection, so that a plurality of service parameters can be measured by sampling one tube of sample at a time, thereby greatly shortening the detection time and improving the detection efficiency.

Specifically, the sample analysis device further comprises a control platform 20, and the plurality of analysis modules 10, the sample conveying module 40, the unloading unit 11, the code scanning unit 12 and the loading unit 13 are all electrically connected with the control platform 20, so that pipeline mode management of the plurality of analysis modules 10 is realized.

Referring to fig. 2, fig. 2 is a schematic flow chart illustrating an embodiment of a method for controlling a sample analyzer according to the present disclosure; there is provided a control method of a sample analysis apparatus, the control method including:

s10: the operation mode of the analysis module 10 is set in response to a setting instruction of a user, wherein the operation mode includes a stand-alone mode and a pipeline mode.

In this embodiment, a user may set an operation mode of the analysis module 10 entering the pipeline through the control system, so that the analysis module 10 enters a corresponding operation mode. The working modes comprise a single machine mode and a pipeline mode. Specifically, in the analysis module 10 in the pipeline mode, a Central Transport System (CTS) performs balanced load distribution and sample rack recovery on the CTS through a transport track; the analysis module 10 in stand-alone mode, which can be used independently by the user, is no longer assigned and retrieved by the Central Transport System (CTS) to the analysis module 10.

Referring to fig. 3-4, fig. 3 is a schematic structural diagram of an embodiment of a display interface in the control method provided by the present application, and fig. 4 is a schematic flow diagram of an embodiment of step S10 in fig. 2; in the present embodiment, step S10 specifically includes the following steps:

s11: a list of analysis modules 10 capable of performing operation mode setting in the sample analysis apparatus and operation mode options corresponding to the analysis modules 10 are displayed on the display interface.

S12: the operational mode of the analysis module 10 is marked as either a stand-alone mode or a pipeline mode in response to user manipulation of the operational mode option.

Referring to fig. 3, fig. 3 is a schematic structural diagram of a working mode setting interface according to an embodiment of the present application; in the present embodiment, a list of the analysis modules 10 capable of performing the operation mode setting in the sample analysis apparatus and the operation mode options corresponding to the analysis modules 10 are displayed on the display interface of the control system. Specifically, in the display list, the user may click the corresponding operating mode option button corresponding to the analysis module 10 by using a mouse to input a corresponding setting instruction; specifically, the pipeline working mode can be set when the working mode option button is lightened, and the single machine mode can be set when the working mode option button is not lightened. In another embodiment, the working mode option corresponding to the analysis module 10 may also be in a rule selection list mode, the option is set as a list for checking, the selection list includes a single machine mode and a pipeline mode, and a user can check according to requirements; it will be readily appreciated that the selection list can only be a single selection, i.e. each analysis module 10 can only check one mode of operation. Of course, in other embodiments, the operation mode option may be implemented in other manners as long as the operation mode of the corresponding analysis module 10 can be selected. In this embodiment, a user may set one or more of the analysis modules 10 to be in a pipeline mode or a stand-alone mode, or all of the analysis modules may be in the pipeline mode, or all of the analysis modules may be in the stand-alone mode, that is, the number of the analysis modules 10 in each operation mode is not limited, so as to facilitate the user.

The control system responds to the operation of the user on the working mode options, and marks the working mode of the analysis module 10 as a single machine mode or a pipeline mode; that is, according to the operation of the user on the above operation mode options, the corresponding analysis module 10 is set to be in the single machine mode or the pipeline mode, and is marked as the single machine mode or the pipeline mode on the display interface, so as to facilitate the user identification.

The working mode of the analysis module 10 is marked as the working mode corresponding to the operation, in the specific embodiment, the initial state of the option button of the working mode corresponding to the plurality of analysis modules 10 in the display list is located in the pipeline mode option, and the control system marks the plurality of analysis modules 10 as the pipeline mode by default; after a user clicks a working mode option button corresponding to the analysis module 10 which needs to be set to be in the stand-alone mode, the control system responds to the operation to enable the change state of the corresponding working mode option button to be located in the stand-alone mode option; it will be readily appreciated that each time the user clicks on the button, the control system will change the operating mode option for that button and mark the operating mode for the corresponding analysis module 10.

Referring to fig. 3 and 5, fig. 5 is a schematic flowchart illustrating an embodiment of step S12 in fig. 4; in the present embodiment, step S12 specifically includes the following steps:

s121: the on/off reservation option of the analysis module 10 whose operation mode is the pipeline mode is enabled on the display interface, and the on/off reservation option of the analysis module 10 whose operation mode is the stand-alone mode is disabled.

S122: in response to the user's operation of the on/off reservation option, the analysis module 10, whose operating mode is the pipeline mode, associates the on/off reservation time.

With reference to fig. 3, the on/off reservation option of the analysis module 10 with the pipeline mode as the working mode is enabled on the display interface, that is, the on/off reservation option of the analysis module 10 with the pipeline mode as the working mode is enabled on the display interface to be in a usable state, that is, the on/off reservation option end of the analysis module 10 is controlled to be in a state capable of inputting instructions, and the user can reserve the on/off time of the analysis module 10; specifically, on the display interface, the checkup button or the toggle button of the on/off reservation option of the analysis module 10 is displayed in a usable state, for example, visually displayed in an illuminated state, and the user can set the toggle button of the on/off reservation option of the analysis module 10 on the display interface to reserve the on time and/or the off time of the corresponding analysis module 10. In this embodiment, a reserved startup option and a reserved shutdown option are correspondingly set beside a working mode option corresponding to each analysis module 10 in the display list, when a user sets the working mode of the analysis module 10 to a pipeline working mode, the reserved startup option and the reserved shutdown option corresponding to the analysis module 10 can be checked, for example, after the reserved startup option is checked, the control system responds to the operation, the user sets startup time in a startup time option bar, and the control system associates the startup time with the corresponding analysis module 10, so that the analysis module 10 can be started according to the startup time set by the user; similarly, after the reserved shutdown option is checked, the control system responds to the operation, the user sets the shutdown time in the shutdown time option bar, and the control system associates the shutdown time with the corresponding analysis module 10, so that the analysis module 10 can be shut down according to the shutdown time set by the user.

It should be noted that when the power-on time and the power-off time are set, the power-off time is after the power-on time, and if the user sets the power-off time before the power-on time, the display interface will prompt the user of an operation error. Certainly, the user may also not set the reserved on/off time for the analysis module 10 whose operating mode is the pipeline mode, that is, the reserved on option or the reserved off option is not checked, and the reserved on option is not checked, then the control system defaults the on time of the analysis module 10 to be the current time. In this embodiment, the on/off reservation time of the analysis module 10 of which a part of the operating modes are the pipeline mode may be set, and the on/off reservation time of the analysis module 10 of which another part of the operating modes are the pipeline mode is not set; or the analysis modules 10 with all the operating modes being the pipeline mode are set with the on/off appointment time, or the setting of the on/off appointment time is not performed at all, so that the use modes of the analysis modules 10 of the sample analysis device are more flexible and convenient.

According to the embodiment, the analysis module 10 with the operating mode being the pipeline mode can be started and shut down according to the time reserved by the user, so that when the user starts the pipeline mode every day, the analysis module 10 in the pipeline mode can be started and enter the pipeline mode at the specified time without performing instant operation on site, samples are detected and analyzed, or the analysis module is shut down at the specified time, the user does not need to wait, and the sample detection efficiency is improved.

Disabling the on/off reservation option of the analysis module 10 with the stand-alone mode on the display interface, that is, enabling the on/off reservation option of the analysis module 10 with the stand-alone mode to be in a disabled state on the display interface, that is, controlling the on/off time reservation option end of the analysis module 10 to be in an instruction non-input state, so that a user cannot reserve the on/off time of the analysis module 10; specifically, on the display interface, the checkup button or the toggle button of the on/off reservation option corresponding to the analysis module 10 is displayed in a disabled state, for example, visually displayed in gray, and the user cannot reserve the on/off time of the analysis module 10. Specifically, for the analysis module 10 with the single machine mode as the working mode, the analysis module 10 is used by the user alone, the control system disables the on/off reservation option of the analysis module 10 in the working mode, even if the on/off reservation option of the analysis module 10 is in a disabled state, the user cannot perform the on-time reservation and the off-time reservation for the analysis module 10 in the single machine mode, in the display interface, the reservation option and the reserved off option corresponding to the analysis module 10 in the working mode are in an off state, and the user cannot perform the on-time reservation and the off-time reservation for the analysis module 10 in the working mode. Thereby preventing the user from performing an invalid operation or a wrong operation with respect to the analysis module 10 whose operation mode is the stand-alone mode.

In this embodiment, the method of controlling a sample analysis apparatus further includes:

s20: based on the working mode set by each analysis module 10, each analysis module 10 is differentially controlled.

Referring to fig. 6-8, fig. 6 is a schematic flowchart illustrating an embodiment of step S20 in fig. 2, fig. 7 is a schematic flowchart illustrating an embodiment of step S21 in fig. 6, and fig. 8 is a schematic flowchart illustrating an embodiment of a pipeline mode of an analysis module provided in the present application; in this embodiment, the control system performs differential control on each analysis module 10 according to the working mode set by each analysis module 10, so that the analysis module 10 enters the corresponding working mode to make corresponding preparation for subsequent sample detection and analysis. Specifically, the step S20 includes the following steps:

s21: in response to a one-key start/stop instruction or a reserved time for power on/off, the analysis module 10 having the pipeline mode as its operating mode is started or stopped, and the analysis module 10 having the stand-alone mode as its operating mode is maintained in an original state.

In this embodiment, the analysis module 10 whose operating mode is the pipeline mode may be turned on or off by a one-key on/off instruction, and if a reserved time for turning on/off the analysis module 10 in the pipeline mode is set, the corresponding analysis module 10 is turned on or off according to the reserved time.

The analysis module 10 with the single machine mode is kept in the original state, so that the analysis module 10 is different from the analysis module 10 with the pipeline mode, and a user can operate the analysis module independently, thereby avoiding errors caused by interference on the operation of the analysis module 10 with the single machine mode.

Specifically, step S21 includes the following steps:

s211: responding to a one-key starting/closing instruction, starting or closing all the analysis modules 10 of which the working modes are pipeline modes in the sample analysis equipment; and/or in response to the power on/off schedule, the analysis module 10, whose operating mode is the pipeline mode and associated with the power on/off schedule, is turned on or off.

Based on the setting instruction for the operation mode of the analysis module 10 in the above embodiment, if the operation mode of the analysis module 10 is set to the pipeline mode and the user does not set the reserved time for power on/off of the analysis module 10, the one-key-on operation instruction may be completed by clicking a one-key-on button or starting a one-key-on switch, and the like, and the control system responds to the operation instruction to start all the analysis modules 10 in the sample analysis device, the operation modes of which are the pipeline mode; each analysis module 10 enters the pipeline mode to work, the working contents comprise the contents of sample detection and analysis work, instrument cleaning work and the like, after the work is stopped, a user can also complete the operation instruction of one-key closing by clicking a one-key closing button or disconnecting a one-key closing switch and the like, and the control system responds to the operation instruction and closes all the analysis modules 10 of which the working modes are the pipeline mode in the sample analysis equipment; the user operation steps are effectively simplified, and the user does not need to perform manual intervention on the analysis module 10 for starting all pipeline modes.

If the working mode of the analysis module 10 is set to the pipeline mode and the corresponding startup reservation time/shutdown reservation time is set, the analysis module 10 associates the startup/shutdown reservation time, the control system responds to the instruction of the startup/shutdown reservation time, and the analysis module 10 whose working mode is the pipeline mode and is associated with the startup/shutdown reservation time is turned on/off at the corresponding time; by the embodiment, the analysis module 10 in the sample analysis equipment can be turned on or turned off in preset time, a user sets a relevant instruction in advance, and the turning-on or turning-off of the relevant analysis module 10 can be completed without entering a site to perform relevant operations, so that the working efficiency of the user and the sample detection efficiency are improved.

Of course, if the user sets the analysis module 10 with the power-on reservation time/the power-off reservation time yet does not reach the power-on reservation time/the power-off reservation time, but the user needs to power on the analysis module 10 to use, the analysis module 10 may also be turned on/off by using a one-key start/stop method, where the one-key start/stop control method is similar to or the same as the control method related in the above embodiment, which may be referred to above specifically, and is not described here again.

Further, for step S21, the method further includes the following steps:

s212, in the starting process, further starting an auxiliary module related to the analysis module 10 with the pipeline mode as the working mode; and/or to shut down the auxiliary modules independently of the remaining analysis modules 10 which remain switched on during the shut down procedure.

In this embodiment, based on the operation of the analysis module 10 in which the start operation mode is the pipeline mode, in the starting process, the auxiliary module related to the analysis module 10 is further started, so that the subsequent preparation for detecting and analyzing the sample by the sample analysis device is more sufficient, the time consumed for starting the sample analysis device is shortened, and the sample detection efficiency is improved. Specifically, the related auxiliary modules include a central control platform, a Central Transmission System (CTS), a pipeline base unit (a sample loading unit and a sample unloading unit), a code scanning buffer unit, a rotation unit, a single sample injection unit, a double-click sample injection unit, an air source used by the analysis module 10 or the related units, a computer power switch, and the like.

In the shutdown process, except for the analysis module 10 whose operating state is the pipeline mode, the auxiliary modules unrelated to the remaining analysis modules 10 that are kept in the power-on state are also shut down, that is, all the auxiliary modules that cannot be used by the analysis module 10 that is kept in the power-on state are shut down, only the auxiliary modules needed by the remaining analysis modules 10 that are kept in the power-on state are turned on, for example, the auxiliary units that are needed to be used, such as the loading unit, the unloading unit, the code scanning buffer unit, the power switch of the related instrument, and the like, which are related to the analysis module 10 in the power-on state are kept in the power-on state, and all the remaining auxiliary modules are shut down, thereby avoiding resource waste.

Based on the above embodiment, after the start-up operation of the analysis module 10 with the pipeline mode is completed, step S20 further includes the following steps:

s22: the sample transport module is controlled to distribute and recover samples to the analysis module 10 in the pipeline mode based on the load balancing mode.

In this embodiment, all of the analysis modules 10 in the sample analysis device, which are set in pipeline mode, will be dispensed and samples recovered by the sample transport module. In a specific embodiment, the sample to be tested is usually contained in a sample container, the sample container is loaded on a sample rack, the sample transport module is configured to distribute the sample rack loaded with the sample container to a plurality of analysis modules 10 having a pipeline mode based on a load balancing manner, after the analysis modules 10 complete the detection and analysis of the sample to be tested, the sample rack loaded with the sample to be tested is recovered by the sample transport module, and then the sample to be tested is processed uniformly. This embodiment is through making sample transport module with load balancing mode for corresponding analysis module 10 distribution and recovery treat the sample for the work load of each analysis module 10 is comparatively balanced, avoids that certain analysis module 10 is idle or the work load is piled up too much, thereby shortens whole check-out time, improves work efficiency.

In a specific embodiment, the analysis module 10 further has a mode switching status indicator light, in a normal case, when the analysis module 10 is in the pipeline mode, the mode switching status indicator light is green, and when the analysis module 10 operates in the working mode, the mode switching status indicator light is green flashing, that is, a green flashing status; when the analysis module 10 is in the stand-alone mode, the mode switching status indicator light is orange, and when the analysis module 10 operates in the working mode, the mode switching status indicator light is orange flashing, that is, orange flashing. Of course, in other embodiments, the color of the mode switching status indicator light may be set to other colors as long as it can distinguish whether the corresponding analysis module 10 is in the pipeline mode or the stand-alone mode, and the application is not particularly limited thereto.

Based on the above embodiment, step S20 further includes:

s23: in response to a working mode switching instruction for the analysis module 10 in the power-on state, judging whether the current working mode of the analysis module 10 is the pipeline mode or the single machine mode;

s24: if the current operation mode is the pipeline mode, the operation mode of the analysis module 10 is changed to the single machine mode, and the sample delivery module is stopped from performing sample distribution and recovery on the analysis module 10.

In some special situations, such as emergency treatment, performance treatment of the analysis module 10, and runaway treatment of the analysis module 10, a user needs to switch the operation mode of the analysis module 10 to cope with the special situations. When the user switches the working mode of the analysis module 10 in the power-on state, the control system responds to the working mode switching instruction of the user to determine whether the current working mode of the analysis module 10 is the pipeline mode or the single machine mode.

If the current operation mode of the analysis module 10 is the pipeline mode, the operation mode of the analysis module 10 is changed to the single machine mode, and the sample transportation module is stopped to distribute and recover the samples to the analysis module 10. That is, the analysis module 10 is changed from the line mode to the single machine mode, and at this time, the sample transport module does not distribute and collect the sample rack loaded with the sample container to the analysis module 10 any more, and after the analysis module 10 completes the detection and analysis work currently performed, the user can use the analysis module 10 alone. Accordingly, the color of the mode switching status indicator lamp of the analysis module 10 is changed to orange. According to the embodiment, the analysis module 10 in the pipeline mode can be switched to the single machine mode during operation so as to deal with other operations of a user, so that the use flexibility of the analysis module 10 is improved, and the use of multiple scenes can be met.

Further, based on the step S23, the step S20 further includes:

s25: and if the current working mode is the single machine mode, generating an alarm.

Specifically, if the current working mode of the analysis module 10 is the single machine mode, the user is not allowed to switch the working mode of the analysis module 10, and if the user still performs the switching operation of the working mode on the analysis module 10, the control system will generate an alarm to prompt the user to perform an illegal operation. Specifically, in an embodiment, the control system generates an alarm, which may specifically be an alarm sound, an alarm prompt lamp, an alarm prompt window, or other alarm modes, as long as it can prompt the user to perform an illegal operation and it is obvious enough for the user to receive the alarm information, and this application is not limited specifically. In this embodiment, since the analysis module 10 cannot be switched to the pipeline mode, the mode-switching status indicator lamp of the analysis module 10 is still orange.

After the analysis module 10 in the pipeline mode is completely worked, when entering the next detection and analysis work, the user can reset the analysis module 10 which was in the single machine mode last time, so that the analysis module is changed into the pipeline mode, and the detection and analysis are performed on the sample to be detected.

Referring to fig. 9, fig. 9 is a schematic flow chart illustrating an embodiment of a stand-alone mode analysis module provided in the present application; in this embodiment, when the operation mode of the analysis module 10 is the stand-alone mode, the user uses the analysis module 10 alone; specifically, the method comprises the following steps:

in response to a start instruction of the analysis module 10 with the operation mode being the stand-alone mode, for example, the start instruction may be triggered by a start key to start the stand-alone sample injection unit. To prepare the user for using the analysis module 10 alone in the stand-alone mode.

The general power of the analysis module 10 is turned on. The main power supply specifically comprises an analysis module 10 host, an air source and a computer power supply. So that the analysis module 10 and the related auxiliary modules are both in an open state, thereby completing the sample detection and analysis work specified by the user.

In response to a switching instruction of the analysis module 10 in the on state, an alarm is generated. The step is similar to the step S25, and the realized functions and effects are similar or identical, which are specifically referred to above and are not described herein again.

Referring to fig. 10, fig. 10 is a schematic flow chart illustrating an embodiment of sample detection result transmission provided in the present application; for the control method of the sample analysis device provided in the foregoing embodiment, after the sample analysis device completes the corresponding sample detection and analysis work, it is further required to transmit sample detection data to a related system, and the method specifically includes the following steps:

s31: the analysis module 10 counts and forms the detection result.

S32: and responding to a setting instruction of a user, and judging whether to send a sample detection result to a Laboratory Information System (LIS).

S33: if the instruction is yes, the sample detection result is sent to the LIS.

S34: if the instruction is no, the sample detection result is sent to a Central Transmission System (CTS).

S35: in response to the CTS command, it is determined whether to send the sample detection result to the LIS.

S33: if the instruction is yes, the sample detection result is sent to the LIS.

S36: if the instruction is no, the sample detection result is sent to a specialist management system (PMS), and the sample detection result is sent to the LIS.

In this embodiment, generally, if the analysis module 10 is in the pipeline mode, the sample detection result is directly sent to the LIS. If the analysis module 10 is in a stand-alone mode, the user can self-define the sample detection result to be sent to the LIS system or the CTS system, and if the sample detection result is sent to the CTS system, the CTS system sends the sample detection result to the LIS system or the PMS system according to the user self-definition; if the information is sent to the PMS system, the information is sent to the LIS system by the PMS system; according to the embodiment, the user can directly send the sample detection result to the LIS system, or send the sample detection result to the PMS system and the LIS system through the CTS system, the sample detection result can be transmitted according to user definition, and the use convenience of the user is improved.

The above description is only for the purpose of illustrating embodiments of the present application and is not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application or are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims (9)

1. A control method of a sample analysis apparatus, the sample analysis apparatus including a plurality of independent analysis modules, the control method comprising:

setting the working mode of the analysis module in response to a setting instruction of a user, wherein the working mode comprises a single machine mode and a pipeline mode;

and carrying out differentiation control on each analysis module based on the working mode set by each analysis module.

2. The control method according to claim 1, wherein the step of setting the operation mode of the analysis module in response to a setting instruction of a user comprises:

displaying a list of the analysis modules capable of performing working mode setting in the sample analysis equipment and working mode options corresponding to the analysis modules on a display interface;

and responding to the operation of the user on the working mode option, and marking the working mode of the analysis module as the stand-alone mode or the pipeline mode.

3. The control method according to claim 2, wherein the step of setting the operation mode of the analysis module in response to a setting instruction of a user comprises:

enabling the on/off reservation option of the analysis module with the working mode being the pipeline mode on a display interface, and disabling the on/off reservation option of the analysis module with the working mode being the stand-alone mode;

responding to the operation of the user on the power-on/off reservation option, and associating the power-on/off reservation time for the analysis module with the working mode being the pipeline mode.

4. The control method according to claim 1, wherein the step of differentially controlling each of the analysis modules based on the operation mode set by each of the analysis modules comprises:

responding to a one-key starting/closing instruction or starting/closing reserved time, starting or closing the analysis module with the working mode being the pipeline mode, and keeping the analysis module with the working mode being the single machine mode in an original state.

5. The control method according to claim 4, wherein the step of turning on or off the analysis module with the operation mode being the pipeline mode in response to a one-touch power-on/off command or a power-on/off reservation time, and maintaining the analysis module with the operation mode being the stand-alone mode in an original state comprises:

starting or closing all the analysis modules of the sample analysis device, the working modes of which are the pipeline modes, in response to a one-key starting/closing instruction, and/or starting or closing the analysis modules of which the working modes are the pipeline modes and are associated with the starting/closing scheduled time, in response to the starting/closing scheduled time.

6. The control method according to claim 5, wherein the step of starting or shutting down the analysis module of which the operation mode is the pipeline mode in response to a one-touch start/shut-down command or a power-on/shut-down reservation time, and maintaining the analysis module of which the operation mode is the stand-alone mode in an original state comprises:

during the starting process, further starting an auxiliary module related to the analysis module of which the working mode is the pipeline mode; and/or during a shutdown procedure, shutting down auxiliary modules that are not associated with the remaining analysis modules that remain in the power-on state.

7. The control method according to claim 1, wherein the sample analysis apparatus includes a sample transport module, and the step of differentially controlling the analysis modules based on the operation mode set by each of the analysis modules includes:

controlling the sample transport module to distribute and recover samples to the analysis modules of the pipeline mode for the working mode based on a load balancing manner.

8. The control method according to claim 7, wherein the sample analysis apparatus includes a sample transport module, and the step of differentially controlling the analysis modules based on the operation mode set by each of the analysis modules further includes:

responding to a working mode switching instruction of the analysis module in a starting state, and judging whether the current working mode of the analysis module is the pipeline mode or the single machine mode;

and if the current working mode is the assembly line mode, changing the working mode of the analysis module into the single machine mode, and stopping the sample conveying module from distributing and recovering the samples of the analysis module.

9. The control method according to claim 8, wherein the sample analysis apparatus includes a sample transport module, and the step of differentially controlling the analysis modules based on the operation mode set by each of the analysis modules further includes:

and if the current working mode is the single machine mode, generating an alarm.

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