CN114661207B - Interface module control method and device, computer equipment and storage medium - Google Patents

Abstract

The invention discloses an interface module control method, a device, computer equipment and a storage medium, wherein the method comprises the following steps: acquiring the running states of all the functional modules, displaying the running states on a module control interface by corresponding identifiers, setting control buttons for switching the running states for all the functional modules, and displaying the control buttons in association with all the functional modules; and responding to the operation of a control button on the module control interface by a user, and controlling the corresponding functional module to be switched from the current running state to the other running state. According to the embodiment of the invention, the corresponding control buttons are arranged for the functional modules, and a user can achieve the effect of controlling the running process of the functional modules by operating the control buttons, so that the use efficiency of the module control interface is improved. Meanwhile, the invention also displays the running state of each functional module so as to remind a user to take corresponding treatment according to the running state of each functional module in time.

Description

Interface module control method and device, computer equipment and storage medium

Technical Field

The present invention relates to the field of computer software technologies, and in particular, to an interface module control method, an interface module control device, a computer device, and a storage medium.

Background

The management efficiency of each functional module is generally low, and the user is often limited by reasons that the functional modules lack enough connection and the states of the functional modules cannot be displayed in the process of performing man-machine interaction on the module control interface, so that the user lacks enough use experience, and the user needs to consume larger time cost in the process of performing interaction.

Disclosure of Invention

The embodiment of the invention provides an interface module control method, an interface module control device, computer equipment and a storage medium, aiming at improving the use efficiency of a module control interface.

In a first aspect, an embodiment of the present invention provides an interface module control method, including:

acquiring the running states of all the functional modules, displaying the running states on a module control interface by corresponding identifiers, setting control buttons for switching the running states for all the functional modules, and displaying the control buttons in association with all the functional modules;

and responding to the operation of a control button on the module control interface by a user, and controlling the corresponding functional module to be switched from the current running state to the other running state.

In a second aspect, an embodiment of the present invention provides an interface module control device, including:

the acquisition unit is used for acquiring the running state of each functional module;

the display unit is used for receiving the running states of the functional modules, displaying the running states on a module control interface according to the corresponding identifiers, setting control buttons for switching the running states for the functional modules and displaying the control buttons in a correlated mode with the functional modules;

and the first switching unit is used for responding to the operation of a control button on the module control interface by a user and controlling the corresponding functional module to switch from the current running state to another running state.

In a third aspect, embodiments of the present invention provide a biochemical immune cascade system comprising: function module, interface module controlling means, input device and output device, wherein:

the functional module includes:

the sample scheduling module is used for transmitting the samples to the sample analysis module;

a sample immunoassay module for reacting a sample with a reagent, a dispensing mechanism for dispensing the sample or the reagent to the reaction unit, a detection unit for detecting a mixture of the sample and the reagent, and an analysis immunoassay item;

A sample biochemical analysis module, a reaction unit for reacting the sample and the reagent, a dispensing mechanism for dispensing the sample or the reagent to the reaction unit, a detection unit for detecting a mixture of the sample and the reagent, and an analysis biochemical item;

the interface module control device is the interface module control device;

the input device is used for receiving input information directly input by a user on the man-machine interaction interface;

and the output device is used for outputting and displaying the limit range prompt and the failure prompt information.

In a fourth aspect, an embodiment of the present invention provides a computer device, including a memory, a processor, and a computer program stored in the memory and capable of running on the processor, where the processor implements the interface module control method according to the first aspect when executing the computer program.

In a fifth aspect, an embodiment of the present invention provides a computer readable storage medium, where a computer program is stored, where the computer program is executed by a processor to implement the interface module control method according to the first aspect.

The embodiment of the invention provides an interface module control method, an interface module control device, computer equipment and a storage medium, wherein the method comprises the following steps: acquiring the running states of all the functional modules, displaying the running states on a module control interface by corresponding identifiers, setting control buttons for switching the running states for all the functional modules, and displaying the control buttons in association with all the functional modules; and responding to the operation of a control button on the module control interface by a user, and controlling the corresponding functional module to be switched from the current running state to the other running state. According to the embodiment of the invention, the corresponding control buttons are arranged for the functional modules, and a user can achieve the effect of controlling the running process of the functional modules by operating the control buttons, so that the use efficiency of the module control interface is improved. Meanwhile, the embodiment of the invention also displays the running state of each functional module so as to remind a user to take corresponding treatment according to the running state of each functional module in time.

Drawings

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

FIG. 1 is a flow chart of an interface module control method according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a sub-flow in an interface module control method according to an embodiment of the present invention;

FIG. 3 is a schematic block diagram of an interface module control device according to an embodiment of the present invention;

FIG. 4 is a schematic block diagram of a control device of an interface module according to an embodiment of the present invention;

fig. 5 is an exemplary diagram of a functional module in an interface module control method according to an embodiment of the present invention;

FIG. 6 is an exemplary diagram of a control button in an interface module control method according to an embodiment of the present invention;

fig. 7 is an exemplary diagram of a prompt popup window in an interface module control method according to an embodiment of the present invention;

fig. 8 is an exemplary diagram of a shielding state in an interface module control method according to an embodiment of the present invention;

Fig. 9 is an exemplary diagram of a prompt popup window for canceling a shielding state in an interface module control method according to an embodiment of the present invention;

fig. 10 is an exemplary diagram of a method for controlling an interface module according to an embodiment of the present invention;

FIG. 11 is an exemplary diagram of reset initialization in an interface module control method according to an embodiment of the present invention;

FIG. 12 is a diagram illustrating another example of reset initialization in an interface module control method according to an embodiment of the present invention;

fig. 13 is a schematic diagram of a prompt popup window in a stopped state in an interface module control method according to an embodiment of the present invention;

fig. 14 is an exemplary diagram of a stop state in an interface module control method according to an embodiment of the present invention;

FIG. 15 is an exemplary diagram of a prompt pop-up window for a shutdown state in an interface module control method according to an embodiment of the present invention;

fig. 16 is an exemplary diagram of a shutdown state in an interface module control method according to an embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It will be understood that the terms "comprises" and "comprising," when used throughout this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

It is also to be understood that the terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used throughout this disclosure, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be further understood that the term "and/or" as used throughout this disclosure refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.

Referring to fig. 1, fig. 1 is a flow chart of an interface module control method according to an embodiment of the present invention, which specifically includes: steps S101 to S102.

S101, acquiring the running states of all the functional modules, displaying the running states on a module control interface according to corresponding identifiers, setting control buttons for switching the running states for all the functional modules, and displaying the control buttons in an associated mode with all the functional modules;

S102, responding to the operation of a control button on the module control interface by a user, and controlling the corresponding functional module to be switched from the current running state to another running state.

In this embodiment, the alarm states of the functional modules on the module control interface are displayed on the module control interface in a manner of identification display. And a control button is arranged for each functional module, the operation state of the corresponding functional module can be switched and controlled through the control button, and corresponding display is also carried out on a module control interface in the switching process. When the user operates each control button on the module control interface, the function module corresponding to the control button is controlled to switch from the current running state to another running state according to the control button selected by the user, and the other running state is determined by the state corresponding to the control button. Of course, each function module control program in the module control interface is independently executed and is not interfered with each other.

According to the embodiment, the corresponding control buttons are arranged for the functional modules, and a user can achieve the effect of controlling the running process of the functional modules by operating the control buttons, so that the use efficiency of the module control interface is improved. Meanwhile, the embodiment also displays the running states of the functional modules so as to remind a user to take corresponding treatment according to the running states of the functional modules in time.

For example, as shown in fig. 5, the state and execution modules of the sample biochemical analysis module M2, the sample immune analysis module M1, the sample scheduling module STU, etc. may be displayed on the module control interface, where control buttons set by the sample biochemical analysis module M2 and the sample immune analysis module M1 may include a mask button, a cancel mask button, a reset button, a stop button, a shutdown button, etc. The states of the sample immunoassay module M1, the sample biochemical analysis module M2, the sample scheduling module STU, and the operation states of the execution module may be initialization, standby, in-test, stop, offline, reset, maintenance, shutdown, and the like. The specific method is as follows:

initializing: the functional module controls the stable time of the light source temperature from entering the software interface to finishing the mechanical action.

Standby: the functional module is idle and no test operation is performed.

In the test: the functional module is being tested, scheduled or loaded with reagents on-line.

Stopping: the functional module enters a stopped state due to a failure or clicking a stop button.

Off-line: the functional module is connected with the host computer to be interrupted.

Resetting: the functional module executes a reset program.

Maintenance: the functional module performs maintenance mechanical operations such as dirty cup detection, reaction cup intensive cleaning, and the like.

And (5) shutting down: the function module executes the state of the function module after being shut down.

When the current running state is in the process of initialization and test, the remaining time needs to be displayed: time minutes seconds ", the remaining time is updated in real time.

For control buttons, fig. 6 may be combined, wherein:

the masking button may separate a functional module that cannot participate in testing, to which the sample rack is not scheduled by the sample scheduling module, but which may still perform other non-testing operations normally.

The cancel mask button may cancel the mask state of a functional module that may continue to perform the test to which the sample rack may be dispatched by the sample dispatcher module.

The reset button can initialize a certain functional module, so that the functional module can recover from faults, each component is recovered to an initial position, and the state of the functional module is recovered to be standby.

The stop button may stop all tests and other actions currently on a functional module that is stationary at this point.

The shutdown button may shut down a functional module that is not operational, and the operating software and other functional modules continue to operate.

In one embodiment, the step S102 includes:

Responding to the operation of a control button on the module control interface by a user, and generating and displaying a prompt popup for function confirmation;

responding to the confirmation operation of the user in the prompt popup window, and controlling the corresponding functional module to switch from the current running state to another running state; or, in response to the cancel operation of the user in the prompt popup, maintaining the current running state of the corresponding functional module.

In this embodiment, a corresponding prompt popup window is generated for each control button, when a user operates a control button on a module control interface, the prompt popup window corresponding to the control button can be popped up, after the user further confirms the prompt popup window, the function module corresponding to the control button is controlled to switch the running state, and after the user cancels the prompt popup window, the function module corresponding to the control button is not required to switch the running state. Therefore, the situation that a user mispoints the control button can be prevented, the use precision of the module control interface is guaranteed, and the user experience is improved.

For example, as shown in fig. 7, in response to a user operation of a mask button on the module control interface, a prompt pop-up window for mask confirmation is generated and displayed; when the user carries out shielding confirmation on the prompt popup window, the current running state of the functional module corresponding to the shielding button is switched to a shielding state; when the user cancels the prompt popup window, the current running state of the functional module corresponding to the shielding button is not required to be switched into the shielding state, namely, the current running state of the functional module corresponding to the shielding button is maintained.

For another example, as shown in fig. 9, in response to a user operation of a cancel shading button on the module control interface, a prompt pop-up window for canceling shading confirmation is generated and displayed; when the user carries out shielding canceling confirmation on the prompt popup window, the current running state of the function module corresponding to the shielding canceling button is switched to a shielding canceling state; when the user carries out the cancel operation on the prompt popup window, the current running state of the functional module corresponding to the cancel shielding button is not required to be switched to the cancel shielding state, namely the current running state of the functional module corresponding to the cancel shielding button is maintained.

In one embodiment, the control button includes: a mask button and a cancel mask button;

the control corresponding to the function module switching from the current operating state to another operating state includes:

the corresponding functional module is controlled to be switched from a shielding state to a shielding canceling state, the shielding canceling button is subjected to ash setting, and the shielding canceling button is subjected to ash setting canceling; or, controlling the corresponding functional module to switch from a shielding canceling state to a shielding state, performing dust setting treatment on the shielding button, and performing dust setting canceling treatment on the shielding canceling button.

In this embodiment, in conjunction with fig. 8, when a user operates a mask button on the module control interface, a corresponding prompt pop-up window may be displayed (for example, determining to mask a functional module. Further, a mask logo may be displayed on the functional module, such as in the lower right corner of the functional moduleThe mark, the mask, is displayed as "yes".

In one embodiment, the sample analysis module comprises a sample biochemical analysis module and a sample immunoassay module.

Further, in an embodiment, the controlling, corresponding to the function module switching from the current operation state to another operation state, includes:

controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding state to a shielding-canceling state, performing ash setting treatment on the shielding-canceling button, and performing ash setting canceling treatment on the shielding button; or controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding-canceling state to a shielding state, performing ash setting treatment on the shielding button, and performing ash setting canceling treatment on the shielding-canceling button.

In another embodiment, the controlling the sample biochemical analysis module and/or the sample immune analysis module to switch from a shielding state to a shielding-canceling state, and performing the ash setting process on the shielding-canceling button, and the performing the ash setting canceling process on the shielding button includes:

judging whether the current running state of the sample biochemical analysis module and/or the sample immunity analysis module is a test state or not;

and if the current running state of the sample biochemical analysis module and/or the sample immune analysis module is judged to be the test state, controlling the sample scheduling module to reschedule a sample frame to the sample biochemical analysis module and/or the sample immune analysis module, enabling the sample biochemical analysis module and/or the sample immune analysis module to continuously execute the test, and enabling a sample tray or a sample injection mechanism of the sample scheduling module to start the test.

For example, the sample immunoassay module M1 and/or the sample biochemical analysis module M2 may be masked when an analysis section in the module control interface fails, which requires handling of sample racks that are not intended for it.

Specifically, the controlling the sample biochemical analysis module and/or the sample immune analysis module to switch from a shielding canceling state to a shielding state, performing the ash setting process on the shielding button, and performing the ash setting canceling process on the shielding canceling button includes:

Responding to the application operation of a user on the sample biochemical analysis module and/or the sample immune analysis module, performing failure treatment on an entity operation button, and performing ash setting treatment on a starting popup window choosing frame corresponding to the sample biochemical analysis module and/or the sample immune analysis module.

After the sample immune analysis module M1 and the sample biochemical analysis module M2 are shielded, the test can be applied for but can not be started, and the frame ash can not be selected by the corresponding module of starting the popup window. In addition, after the sample immune analysis module M1 and the sample biochemical analysis module M2 are shielded, the sample dispatching module STU will not dispatch the sample rack to the sample dispatching module STU, and the sample tray or the sample feeding mechanism of the sample dispatching module STU will stop testing, but other non-testing operations can still be normally executed. The masking and its meaning are specifically shown in table 1:

TABLE 1

It should be noted that the functional modules on the module control interface can be switched to the shielding state in any state. And after the functional module is shielded, the corresponding shielding button is gray.

In connection with fig. 10, in response to a user operating a mask button on the module control interface, a corresponding prompt pop-up window may be displayed (e.g., determining to cancel the masking function module. Further, the obscured indication on the functional module may be removed, e.g. displayed in the lower right corner of the functional module The flag, mask display is "no".

After the functional module cancels the shielding, the test can be started normally, and the corresponding module hook frame of the starting popup window is optional. Meanwhile, after the functional module removes the shielding, when the system is in test, the test can be continuously executed, the STU dispatches the sample rack to the STU again, and the test can be started by the sample tray or the sample feeding mechanism. When the module is not shielded, the shielding button is canceled to put ash.

In one embodiment, the control button includes: a reset button;

the control corresponding to the function module switching from the current operating state to another operating state includes:

resetting and initializing the corresponding functional module, and detecting whether a stopping operation is received or not in the resetting and initializing process; if yes, stopping resetting initialization; if not, continuing to execute the reset program until the reset program is completed, and switching the corresponding functional module to a standby state.

In this embodiment, in response to the user operating the reset button corresponding to the functional module, the functional module is reset and initialized, so that the functional module can be recovered from the fault, and other components are reset at the same time. After the reset initialization is completed, the functional module will be in standby state.

Further, in an embodiment, the resetting initialization of the corresponding functional module includes:

and responding to the operation of a user on a control button on the module control interface, and generating and displaying a prompt popup for prompting that the user cannot leave the current interface.

Further, in an embodiment, before the resetting initialization of the corresponding functional module, the method includes:

judging the running state of the functional module;

and if the running state of the functional module is any one of an initialization state, a test state or an offline state, controlling the functional module to be incapable of resetting and initializing from the current running state, and carrying out ash setting on the reset button.

Specifically, the control corresponds to the function module being switched from the current running state to another running state, and includes:

resetting and initializing the sample biochemical analysis module and/or the sample immunity analysis module, and detecting whether a stopping operation is received or not in the resetting and initializing process; if yes, stopping resetting initialization, resetting the state and stopping the state; if not, continuing to execute the reset program until the completion, and switching the sample biochemical analysis module and/or the sample immunity analysis module to a standby state.

In connection with fig. 11 and 12, in the reset initialization process, the reset initialization may be selected to be stopped, that is, the reset initialization of the functional module may be stopped, so that the functional module is in a stopped state. Further, in the reset initialization process, the user cannot leave the current interface, and click on the button related to other pages, a prompt popup window can be popped up, for example, "the system is resetting the module and cannot leave the current interface-! ". In addition, when the functional module is in the initialized, tested, offline and other states, the functional module cannot be reset, and accordingly, the reset button is subjected to ash setting.

In one embodiment, the control button includes: a stop button and a shutdown button;

the control corresponding to the function module switching from the current operating state to another operating state includes:

and controlling the corresponding functional module to switch from the current running state to the stopping state or the shutdown state, and carrying out ash setting treatment on the rest control buttons except the reset button.

In this embodiment, when responding to the stop button in the module control interface, the current running state of the corresponding function module is switched to the stop state. Likewise, in response to a user's power-off button in the module control interface, the current operating state of the corresponding functional module is switched to a power-off state. Further, as shown in fig. 13 and 15, in conjunction with the prompt pop-up window, that is, in response to a user's confirmation operation on a stop button or a shutdown button in the module control interface, a prompt pop-up window corresponding to the stop button (for example, a result of all incomplete tests of the functional module will be invalidated, a stop test is determined) or a prompt pop-up window corresponding to the shutdown button (a shutdown of the functional module is determined).

Further, in an embodiment, before the control corresponding to the function module is switched from the current running state to the stop state or the shutdown state, the control includes:

judging the current running state of the functional module;

if the current running state of the functional module is judged to be in test and reset, controlling the functional module to be unable to switch from the current running state to a shutdown state, and carrying out ash setting treatment on the shutdown button;

if the current running state of the functional module is judged to be a fault state, controlling the functional module to reset and initialize from the current running state, and controlling the functional module to switch from the current running state to a shutdown state after the reset and initialize are completed;

and when the fault state of the functional module is not recovered or cannot be recovered, carrying out ash setting treatment on the shutdown button.

Specifically, the control corresponds to the function module being switched from the current running state to another running state, and includes:

and controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from the current running state to the stop state or the shutdown state, and carrying out ash setting treatment on the rest control buttons except the reset button.

Referring to fig. 14, when a function module is switched to a stopped state, the function module cannot perform a corresponding function operation.

Specifically, the controlling the sample biochemical analysis module and/or the sample immune analysis module to switch from the current running state to the stop state or the shutdown state, and performing ash setting treatment on the rest control buttons except the reset button comprises:

and stopping biochemical immunity test movement of the sample biochemical analysis module and/or the sample immunity analysis module when the sample biochemical analysis module and/or the sample immunity analysis module is in a stop state, performing failure treatment on an entity operation button, and performing ash setting treatment on a starting popup hook frame corresponding to the sample biochemical analysis module and/or the sample immunity analysis module.

For example, when the sample immune analysis module M1 and/or the sample biochemical analysis module M2 are in a stop state, the functional module may apply for but may not start the test, and correspondingly, the module corresponding to the start popup window may hook the frame ash, so that the frame ash cannot be selected. When the sample immunoassay module M1 and/or the sample biochemical analysis module M2 are stopped, the sample dispatching module STU will not dispatch the sample rack thereto, and the sample tray or the sample feeding mechanism thereof will stop all the testing and other movements. The stopping situation and the meaning thereof are specifically shown in table 2:

TABLE 2

If the function module in the stopped state is to be restored to the state of testability, movement and the like, the function module can be selected again, then the function module is clicked for reset, the stopped state of the function module is switched to the standby state, the corresponding entity operation button is revalidated, and the start button popup frame is selected for restoration.

Meanwhile, the control corresponding to the function module is switched from the current running state to another running state, and the control comprises the following steps:

resetting and initializing the sample scheduling module, and detecting whether a stopping operation is received or not in the resetting and initializing process; if yes, stopping resetting initialization; if not, continuing to execute the reset program until the completion, and switching the sample scheduling module to a standby state;

or controlling the sample scheduling module to switch from the current running state to the stop state, and carrying out ash setting treatment on the rest control buttons except the reset button.

When the analysis part (such as a sample analysis module) has no testable sample, the functional module can be shut down to save energy consumption; when the analysis part fails and needs shutdown processing, the module can be shut down.

Further, the controlling the sample scheduling module to switch from the current running state to the stop state or the shutdown state includes:

And controlling the sample dispatching module to be incapable of dispatching the sample rack, stopping the movement of a sample tray or a sample feeding mechanism of the sample dispatching module, keeping the current running state of the sample biochemical analysis module and/or the sample immune analysis module, and feeding samples through a track in the sample biochemical analysis module or a sample tray in the sample immune analysis module.

After the sample immunity analysis module M1 and the sample biochemical analysis module M2 are shut down, the test and the mechanical movement cannot be carried out, the physical operation button fails, the start button popup window corresponding module hooks the frame to put the ash, and the sample dispatching module STU can not dispatch a sample frame to the sample dispatching module STU. The shutdown condition and the meaning thereof are specifically shown in table 3:

TABLE 3 Table 3

Referring to fig. 16, the module in the test and reset state cannot be turned off, and the off button is turned on; when the built-in circulating water tank of the M2 module is empty, shutdown cannot be performed, and at the moment, the shutdown button of the M2 module is placed with ash; when the module has a fault, the module must be reset before the module can be shut down, and when the fault is not recovered or cannot be recovered, the module shutdown button is used for setting ash.

After the functional module is shut down, if the functional module needs to be restarted, the functional module can be reset by clicking the reset module, the state of the functional module is switched to a standby state, the corresponding entity operation button is restarted, and the start button popup frame is selected for restoration. Meanwhile, after the functional module is shut down, other buttons are all gray except for the reset button.

In one embodiment, as shown in fig. 2, the step S101 includes: steps S201 to S203.

S201, detecting alarm states of all functional modules, and acquiring corresponding alarm grades according to the alarm states;

s202, acquiring an alarm identifier associated with the alarm level;

s203, displaying the alarm identification on the module control interface.

In this embodiment, different alarm states correspond to different alarm levels, and different alarm levels may be associated with different alarm identifiers. Therefore, after the alarm state of the functional module is acquired, the alarm identifier associated with the alarm level corresponding to the alarm state is displayed on the module control interface.

For example, the alarm states may be red alarm, yellow alarm, and normal states, the corresponding alarm levels are red alarm > yellow alarm > normal states, and the alarm identifications associated with the alarm levels may be red identifications, yellow identifications, and normal identifications. Further, the red alarm indicates that the functional module has serious alarm, and the information list in the module control interface can be clicked to enter the fault information interface, and then the alarm information is checked and processed. The yellow alarm indicates that the function module generates alarm, and can click on the information list to enter the fault information interface, and then the alarm information is checked and processed. The normal state indicates that the functional module is in a normal state.

In an embodiment, the functional modules include at least one sample scheduling module and a plurality of sample analysis modules.

In this embodiment, the functional module may include the sample scheduling module and a plurality of sample analysis modules (such as a sample biochemical analysis module and a sample immune analysis module), where the sample scheduling module is configured to transmit samples to the sample analysis modules, and may specifically include: the placing area is used for bearing the area of the sample rack to be tested; the recovery unit is used for bearing the area of the sample rack to be recovered; a dispatching unit for dispatching the sample rack to be tested from the placement area and the buffer area to the analysis part, and dispatching the sample rack to be tested, automatically retested and recovered from the analysis part to the buffer area and the recovery area; the buffer area is used for bearing and buffering the area of the sample rack to be tested, automatically retested and recovered.

Sample analysis module one-M1 (e.g., sample immunoassay module) for analyzing an immune-type item, comprising a first reaction unit for reacting a sample and a reagent, a first dispensing mechanism for dispensing the sample or reagent to the reaction unit, and a first detection unit for detecting a mixture of the sample and the reagent; sample analysis module two-M2 (e.g., sample biochemical analysis module) for analyzing biochemical items, including a second reaction unit for reacting a sample and a reagent, a second dispensing mechanism for dispensing the sample or the reagent into the reaction unit, and a second detection unit for detecting a mixture of the sample and the reagent.

Of course, in other embodiments, the functional module may further include a control module, an output module, an input module, and the like, where, for example, the control module is configured to control the setting module according to a set control requirement; the output module is used for outputting a module control interface, and the module control interface comprises a module state presentation control and a module control selection control; the input module is used for receiving the set control module and control requirements.

Fig. 3 is a schematic block diagram of an interface module control apparatus 300 according to an embodiment of the present invention, where the apparatus 300 includes:

an acquiring unit 301, configured to acquire an operation state of each functional module;

the display unit 302 is configured to receive alarm states of each functional module, display the alarm states on a module control interface according to corresponding identifiers, set control buttons for switching operation states for each functional module, and perform associated display with each functional module;

and the first switching unit 303 is configured to control switching of the corresponding functional module from the current operating state to another operating state in response to a user operation of a control button on the module control interface.

In an embodiment, the first switching unit 303 includes:

The popup window corresponding unit is used for responding to the operation of a user on a control button on the module control interface, and generating and displaying a prompt popup window for function confirmation;

the second switching unit is used for responding to the confirmation operation of the user on the prompt popup window and controlling the corresponding functional module to switch from the current running state to another running state; or, in response to the cancel operation of the user in the prompt popup, maintaining the current running state of the corresponding functional module.

In one embodiment, the control button includes: a mask button and a cancel mask button;

the second switching unit includes:

the shielding and ash setting unit is used for controlling the corresponding functional module to switch from a shielding state to a shielding canceling state, carrying out ash setting treatment on the shielding button and carrying out ash setting canceling treatment on the shielding canceling button; or, controlling the corresponding functional module to switch from a shielding canceling state to a shielding state, performing dust setting treatment on the shielding canceling button, and performing dust setting canceling treatment on the shielding canceling button.

In one embodiment, the control button includes: a reset button;

the second switching unit includes:

And the initialization unit is used for responding to the operation of the reset button by a user, resetting the corresponding functional module and initializing the functional module.

In an embodiment, the initialization unit includes:

and the second popup generating unit is used for responding to the operation of the user on other control buttons except the reset button on the module control interface and generating and displaying a prompt popup for prompting that the user cannot leave the current interface.

In an embodiment, further comprising:

the first state judging unit is used for judging the running state of the functional module;

and the resetting and ash setting unit is used for prohibiting the functional module from resetting and carrying out ash setting on the reset button if the running state of the functional module is judged to be any one of an initialization state, a test state or an offline state.

In one embodiment, the control button includes: a stop button and a shutdown button;

the second switching unit includes:

and the stopping or shutdown unit is used for responding to the operation of a user on the stopping button or shutdown button, controlling the corresponding functional module to be switched from the current running state to the stopping state or shutdown state, and carrying out ash setting treatment on the rest control buttons except the reset button.

In an embodiment, further comprising:

and the third popup window generating unit is used for responding to the application operation of a user on a control button on the module control interface when the functional module is in a shutdown state, and generating and displaying a prompt popup window for prompting that the module control interface cannot be separated.

In an embodiment, further comprising:

the second state judging unit is used for judging the current state of the functional module;

the first shutdown ash setting unit is used for carrying out ash setting treatment on the shutdown button if the current state of the functional module is judged to be an initialization state;

the shutdown switching unit is used for controlling the functional module to initialize from the current state if the current state of the functional module is judged to be a fault state, and controlling the functional module to switch from the current state to the shutdown state after the initialization is completed;

and the second shutdown ash setting unit is used for carrying out ash setting treatment on the shutdown button when the fault state of the functional module is not recovered or cannot be recovered.

In one embodiment, as shown in fig. 4, the display unit 302 includes:

an alarm detection unit 401, configured to detect an alarm state of each functional module, and obtain a corresponding alarm level according to the alarm state;

An alarm identifier obtaining unit 402, configured to obtain an alarm identifier associated with the alarm level;

and the alarm identifier display unit 403 is configured to display the alarm identifier on the module control interface.

In an embodiment, the functional modules include at least one sample scheduling module and a plurality of sample analysis modules.

In one embodiment, the plurality of sample analysis modules includes a sample biochemical analysis module and a sample immunoassay module;

the first switching unit includes:

the biochemical and immune analysis unit is used for controlling the sample biochemical analysis module and/or the sample immune analysis module to switch from a shielding state to a shielding-canceling state, carrying out ash setting treatment on the shielding button, and carrying out ash setting canceling treatment on the shielding-canceling button; or controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding-canceling state to a shielding state, performing ash setting treatment on the shielding-canceling button, and performing ash setting canceling treatment on the shielding button.

In one embodiment, the biochemical and immunological analysis unit comprises:

the disabling ash placing unit is used for responding to the application operation of a user to the sample biochemical analysis module and/or the sample immunity analysis module, performing failure treatment on the control button and generating a corresponding control button disabling prompt; and carrying out ash setting treatment on the popup window choosing frame generated after the start button corresponding to the sample biochemical analysis module and/or the sample immunity analysis module is started.

In one embodiment, the biochemical and immunological analysis unit comprises:

the test state judging unit is used for judging whether the current running state of the sample biochemical analysis module and/or the sample immunity analysis module is a test state or not;

and the sample frame scheduling unit is used for judging that the current running state of the sample biochemical analysis module and/or the sample immune analysis module is a test state, if yes, controlling the sample scheduling module to reschedule the sample frame to the sample biochemical analysis module and/or the sample immune analysis module, enabling the sample biochemical analysis module and/or the sample immune analysis module to continuously execute the test, and enabling a sample tray or a sample injection mechanism of the sample scheduling module to start the test.

In one embodiment, the biochemical and immunological analysis unit comprises:

and the test stopping unit is used for stopping the biochemical immunity test action of the sample biochemical analysis module and/or the sample immunity analysis module when the sample biochemical analysis module and/or the sample immunity analysis module are switched to a stopping state, performing failure treatment on the entity operation button, and performing ash setting treatment on a popup window choosing frame generated after the start button corresponding to the sample biochemical analysis module and/or the sample immunity analysis module is started.

In an embodiment, the stopping or shutting down unit comprises:

the sample frame dispatching stopping unit is used for controlling the sample dispatching module to stop dispatching the sample frame to the sample biochemical analysis module and injecting sample through a track in the sample biochemical analysis module;

and the sample dispatching module is used for controlling the sample dispatching module to stop dispatching the sample rack to the sample immunoassay module and injecting samples through a sample tray in the sample immunoassay module.

Since the embodiments of the apparatus portion and the embodiments of the method portion correspond to each other, the embodiments of the apparatus portion are referred to the description of the embodiments of the method portion, and are not repeated herein.

The embodiment of the invention also provides a biochemical immune cascade system, which comprises: function module, interface module controlling means, input device and output device, wherein:

the functional module includes:

the sample scheduling module is used for transmitting the samples to the sample analysis module;

a sample immunoassay module for reacting a sample with a reagent, a dispensing mechanism for dispensing the sample or the reagent to the reaction unit, a detection unit for detecting a mixture of the sample and the reagent, and an analysis immunoassay item;

A sample biochemical analysis module, a reaction unit for reacting the sample and the reagent, a dispensing mechanism for dispensing the sample or the reagent to the reaction unit, a detection unit for detecting a mixture of the sample and the reagent, and an analysis biochemical item;

the interface module control device is the interface module control device;

the input device is used for receiving input information directly input by a user on the man-machine interaction interface;

and the output device is used for outputting and displaying the limit range prompt and the failure prompt information.

The embodiment of the present invention also provides a computer readable storage medium having a computer program stored thereon, which when executed can implement the steps provided in the above embodiment. The storage medium may include: a U-disk, a removable hard disk, a Read-only memory (ROM), a random access memory (RandomAccess Memory, RAM), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The embodiment of the invention also provides a biochemical immune cascade system, which comprises: a sample scheduling module-STU for transmitting samples to a sample analysis module; a sample analysis module I-M1 (immune module) for analyzing immune type items, comprising a first reaction unit for reacting a sample and a reagent, a first dispensing mechanism for dispensing the sample or the reagent to the reaction unit, and a first detection unit for detecting a mixture of the sample and the reagent; a second sample analysis module (a biochemical module) 2 for analyzing biochemical items, including a second reaction unit for reacting the sample with the reagent, a second dispensing mechanism for dispensing the sample or the reagent into the reaction unit, and a second detection unit for detecting a mixture of the sample and the reagent; the output device is used for outputting a module control interface, and the module control interface comprises a module state presentation control and a module control selection control; the input device is used for receiving the set control module and control requirements; and the control device is used for controlling the setting module according to the set control requirement.

Wherein, the sample scheduling module includes: the placing area is used for bearing the area of the sample rack to be tested; the recovery unit is used for bearing the area of the sample rack to be recovered; the dispatching unit is used for dispatching the sample rack to be tested from the placement area and the buffer area to the analysis part, and dispatching the sample rack to be tested, automatically retested and recovered from the analysis part to the buffer area and the recovery area; the buffer area is used for bearing and buffering the area of the sample rack to be tested, automatically retested and recovered.

The embodiment of the application also provides a computer device, which can comprise a memory and a processor, wherein the memory stores a computer program, and the processor can realize the steps provided by the embodiment when calling the computer program in the memory. Of course, the computer device may also include various network interfaces, power supplies, and the like.

In the description, each embodiment is described in a progressive manner, and each embodiment is mainly described by the differences from other embodiments, so that the same similar parts among the embodiments are mutually referred. For the system disclosed in the embodiment, since it corresponds to the method disclosed in the embodiment, the description is relatively simple, and the relevant points refer to the description of the method section. It should be noted that it will be apparent to those skilled in the art that the present application may be modified and practiced without departing from the spirit of the present application.

It should also be noted that in this specification, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, 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, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Claims (26)

1. An interface module control method, comprising:

acquiring the running states of all the functional modules, displaying the running states on a module control interface by corresponding identifiers, setting control buttons for switching the running states for all the functional modules, and displaying the control buttons in association with all the functional modules; the control button includes: a mask button and a cancel mask button;

Responding to the operation of a control button on the module control interface by a user, and controlling the corresponding functional module to be switched from the current running state to another running state;

the functional module comprises at least one sample scheduling module and a plurality of sample analysis modules;

the plurality of sample analysis modules comprise a sample biochemical analysis module and a sample immunity analysis module;

and responding to the operation of a control button on the module control interface by a user, controlling the corresponding functional module to be switched from the current running state to another running state, and comprising the following steps:

controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding state to a shielding-canceling state, performing ash setting treatment on the shielding-canceling button, and performing ash setting canceling treatment on the shielding button; or, controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding-canceling state to a shielding state, performing ash setting treatment on the shielding button, and performing ash setting canceling treatment on the shielding-canceling button;

the control module is used for controlling the sample biochemical analysis module and/or the sample immune analysis module to switch from a shielding state to a shielding-canceling state, carrying out ash setting treatment on the shielding-canceling button, and carrying out ash setting canceling treatment on the shielding button; or, controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding-canceling state to a shielding state, performing dust setting treatment on the shielding button, and performing dust setting canceling treatment on the shielding-canceling button, including:

Judging whether the current running state of the sample biochemical analysis module and/or the sample immunity analysis module is a test state or not;

and judging the current running state of the sample biochemical analysis module and/or the sample immune analysis module as a test state, if yes, controlling the sample scheduling module to reschedule a sample frame to the sample biochemical analysis module and/or the sample immune analysis module, enabling the sample biochemical analysis module and/or the sample immune analysis module to continuously execute the test, and enabling a sample tray or a sample injection mechanism of the sample scheduling module to start the test.

2. The interface module control method according to claim 1, wherein the controlling the corresponding function module to switch from the current operation state to another operation state in response to the operation of the control button on the module control interface by the user includes:

responding to the operation of a control button on the module control interface by a user, and generating and displaying a prompt popup for function confirmation;

responding to the confirmation operation of the user in the prompt popup window, and controlling the corresponding functional module to switch from the current running state to another running state; or, in response to the cancel operation of the user in the prompt popup, maintaining the current running state of the corresponding functional module.

3. The interface module control method according to claim 1 or 2, characterized in that the control corresponding to the function module switching from a current operation state to another operation state includes:

the corresponding functional module is controlled to be switched from a shielding state to a shielding canceling state, the shielding canceling button is subjected to ash setting, and the shielding canceling button is subjected to ash setting canceling; or, controlling the corresponding functional module to switch from a shielding canceling state to a shielding state, performing dust setting treatment on the shielding button, and performing dust setting canceling treatment on the shielding canceling button.

4. The interface module control method according to claim 1 or 2, wherein the control button includes: a reset button;

and responding to the operation of a control button on the module control interface by a user, controlling the corresponding functional module to be switched from the current running state to another running state, and comprising the following steps:

and responding to the operation of the reset button by a user, and carrying out reset operation on the corresponding functional module so as to initialize the functional module.

5. The interface module control method according to claim 4, wherein the resetting operation of the corresponding function module in response to the operation of the reset button by the user, initializing the function module, comprises:

And responding to the operation of the user on other control buttons except the reset button on the module control interface, and generating and displaying a prompt popup for prompting that the user cannot leave the current interface.

6. The interface module control method according to claim 4, wherein before the reset operation is performed on the corresponding function module, comprising:

judging the running state of the functional module;

and if the running state of the functional module is any one of an initialization state, a test state or an offline state, prohibiting the functional module from resetting and carrying out ash setting on the reset button.

7. The interface module control method of claim 4, wherein the control button comprises: a stop button and a shutdown button;

and responding to the operation of a control button on the module control interface by a user, controlling the corresponding functional module to be switched from the current running state to another running state, and comprising the following steps:

and responding to the operation of the user on the stop button or the shutdown, controlling the corresponding functional module to be switched from the current running state to the stop state or the shutdown state, and carrying out ash setting treatment on the rest control buttons except the reset button.

8. The interface module control method according to claim 7, wherein the control corresponding to the function module after switching from a current operation state to a stop state or a shutdown state, comprises:

when the functional module is in a shutdown state, responding to the application operation of a user on a control button on the module control interface, and generating and displaying a prompt popup for prompting that the module control interface cannot be separated.

9. The interface module control method according to claim 7, wherein the controlling before the function module is switched from the current operation state to the stop state or the shutdown state, comprises:

judging the current state of the functional module;

if the current state of the functional module is judged to be in test and reset, carrying out ash setting treatment on the shutdown button;

if the current state of the functional module is judged to be a fault state, the functional module is controlled to carry out reset operation through a reset button, and after the reset is finished, the functional module is controlled to be switched from the current state to a shutdown state through a shutdown button;

and when the fault state of the functional module is not recovered or cannot be recovered, carrying out ash setting treatment on the shutdown button.

10. The interface module control method according to claim 1, wherein the obtaining the operation state of each functional module and displaying the operation state on the module control interface with the corresponding identifier includes:

detecting the alarm state of each functional module, and acquiring a corresponding alarm grade according to the alarm state;

acquiring an alarm identifier associated with the alarm level;

and displaying the alarm identifier on the module control interface.

11. An interface module control device, comprising:

the acquisition unit is used for acquiring the running state of each functional module;

the display unit is used for receiving the running states of the functional modules, displaying the running states on a module control interface according to the corresponding identifiers, setting control buttons for switching the running states for the functional modules and displaying the control buttons in a correlated mode with the functional modules; the control button includes: a mask button and a cancel mask button;

the first switching unit is used for responding to the operation of a control button on the module control interface by a user and controlling the corresponding functional module to switch from the current running state to another running state;

the functional module comprises at least one sample scheduling module and a plurality of sample analysis modules;

The plurality of sample analysis modules comprise a sample biochemical analysis module and a sample immunity analysis module;

the first switching unit includes:

the biochemical and immune analysis unit is used for controlling the sample biochemical analysis module and/or the sample immune analysis module to switch from a shielding state to a shielding-canceling state, carrying out ash setting treatment on the shielding-canceling button, and carrying out ash setting canceling treatment on the shielding button; or, controlling the sample biochemical analysis module and/or the sample immunity analysis module to switch from a shielding-canceling state to a shielding state, performing ash setting treatment on the shielding button, and performing ash setting canceling treatment on the shielding-canceling button;

the biochemical and immunological analysis unit comprises:

the test state judging unit is used for judging whether the current running state of the sample biochemical analysis module and/or the sample immunity analysis module is a test state or not;

and the sample frame scheduling unit is used for judging that the current running state of the sample biochemical analysis module and/or the sample immune analysis module is a test state, if yes, controlling the sample scheduling module to reschedule the sample frame to the sample biochemical analysis module and/or the sample immune analysis module, enabling the sample biochemical analysis module and/or the sample immune analysis module to continuously execute the test, and enabling a sample tray or a sample injection mechanism of the sample scheduling module to start the test.

12. The interface module control apparatus according to claim 11, wherein the first switching unit includes:

the first popup generating unit is used for responding to the operation of a control button on the module control interface by a user and generating and displaying a prompt popup for function confirmation;

the second switching unit is used for responding to the confirmation operation of the user on the prompt popup window and controlling the corresponding functional module to switch from the current running state to another running state; or, in response to the cancel operation of the user in the prompt popup, maintaining the current running state of the corresponding functional module.

13. The interface module control apparatus according to claim 12, wherein the second switching unit includes:

the shielding and ash setting unit is used for controlling the corresponding functional module to switch from a shielding state to a shielding canceling state, carrying out ash setting treatment on the shielding canceling button and carrying out ash setting canceling treatment on the shielding button; or, controlling the corresponding functional module to switch from a shielding canceling state to a shielding state, performing dust setting treatment on the shielding button, and performing dust setting canceling treatment on the shielding canceling button.

14. The interface module control of claim 12, wherein the control button comprises: a reset button;

the second switching unit includes:

and the initialization unit is used for responding to the operation of the reset button by a user, resetting the corresponding functional module and initializing the functional module.

15. The interface module control apparatus according to claim 14, wherein the initialization unit includes:

and the second popup generating unit is used for responding to the operation of the user on other control buttons except the reset button on the module control interface and generating and displaying a prompt popup for prompting that the user cannot leave the current interface.

16. The interface module control device of claim 14, further comprising:

the first state judging unit is used for judging the running state of the functional module;

and the resetting and ash setting unit is used for prohibiting the functional module from resetting and carrying out ash setting on the reset button if the running state of the functional module is judged to be any one of an initialization state, a test state or an offline state.

17. The interface module control of claim 12, wherein the control button comprises: a stop button and a shutdown button;

the second switching unit includes:

and the stopping or shutdown unit is used for responding to the operation of a user on the stopping button or shutdown button, controlling the corresponding functional module to be switched from the current running state to the stopping state or shutdown state, and carrying out ash setting treatment on the rest control buttons except the reset button.

18. The interface module control device of claim 17, further comprising:

and the third popup window generating unit is used for responding to the application operation of a user on a control button on the module control interface when the functional module is in a shutdown state, and generating and displaying a prompt popup window for prompting that the module control interface cannot be separated.

19. The interface module control device of claim 17, further comprising:

the second state judging unit is used for judging the current state of the functional module;

the first shutdown ash setting unit is used for carrying out ash setting treatment on the shutdown button if the current state of the functional module is judged to be a test-in-process and reset state;

The shutdown switching unit is used for controlling the functional module to carry out reset operation through a reset button if the current state of the functional module is judged to be a fault state, and controlling the functional module to be switched from the current state to a shutdown state through the shutdown button after the reset is completed;

and the second shutdown ash setting unit is used for carrying out ash setting treatment on the shutdown button when the fault state of the functional module is not recovered or cannot be recovered.

20. The interface module control device of claim 11, wherein the display unit comprises:

the alarm detection unit is used for detecting the alarm state of each functional module and acquiring a corresponding alarm grade according to the alarm state;

the alarm identification acquisition unit is used for acquiring an alarm identification associated with the alarm level;

and the alarm display unit is used for displaying the alarm identifier on the module control interface.

21. The interface module control device of claim 11, wherein the biochemical and immunological analysis unit comprises:

the disabling ash placing unit is used for responding to the application operation of a user to the sample biochemical analysis module and/or the sample immunity analysis module, performing failure treatment on the control button and generating a corresponding control button disabling prompt; and carrying out ash setting treatment on the popup window choosing frame generated after the start button corresponding to the sample biochemical analysis module and/or the sample immunity analysis module is started.

22. The interface module control device of claim 11, wherein the biochemical and immunological analysis unit comprises:

and the test stopping unit is used for stopping the biochemical immunity test action of the sample biochemical analysis module and/or the sample immunity analysis module when the sample biochemical analysis module and/or the sample immunity analysis module are switched to a stopping state, performing failure treatment on the entity operation button, and performing ash setting treatment on a popup window choosing frame generated after the start button corresponding to the sample biochemical analysis module and/or the sample immunity analysis module is started.

23. The interface module control device of claim 17, wherein the stop or shut down unit comprises:

the sample frame dispatching stopping unit is used for controlling the sample dispatching module to stop dispatching the sample frame to the sample biochemical analysis module and injecting sample through a track in the sample biochemical analysis module;

and the sample dispatching module is used for controlling the sample dispatching module to stop dispatching the sample rack to the sample immunoassay module and injecting samples through a sample tray in the sample immunoassay module.

24. A biochemical immune cascade system, comprising: function module, interface module controlling means, input device and output device, wherein:

The functional module includes:

the sample scheduling module is used for transmitting the samples to the sample analysis module;

a sample immunoassay module for reacting a sample with a reagent, a dispensing mechanism for dispensing the sample or the reagent to the reaction unit, a detection unit for detecting a mixture of the sample and the reagent, and an analysis immunoassay item;

a sample biochemical analysis module, a reaction unit for reacting the sample and the reagent, a dispensing mechanism for dispensing the sample or the reagent to the reaction unit, a detection unit for detecting a mixture of the sample and the reagent, and an analysis biochemical item;

the interface module control device is the interface module control device according to claim 12;

the input device is used for receiving input information directly input by a user on the man-machine interaction interface;

and the output device is used for outputting and displaying the limit range prompt and the failure prompt information.

25. A computer device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the interface module control method according to any one of claims 1 to 10 when executing the computer program.

26. A computer-readable storage medium, wherein a computer program is stored on the computer-readable storage medium, which when executed by a processor implements the interface module control method according to any one of claims 1 to 10.