CN113947377A - Laboratory management system - Google Patents
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Abstract
The invention discloses a laboratory management system, comprising: the basic information configuration module is used for editing a parameter library of the experimental product and configuring experimental standard information which accords with an experimental product standard file based on the parameter library, the parameter library comprises a basic parameter library and a project parameter library, and the experimental standard information is used for standardizing project contents of the experimental product; the experimental scheme configuration module is used for selectively calling basic information configuration module data aiming at experimental products and configuring and generating a specific experimental scheme so as to respond to specific experimental items in item contents; and the experiment control center is used for establishing communication connection with the experiment product through the product communication command and carrying out specific experiments on the target object according to the specific experiment scheme. The technical scheme provided by the invention solves the problem of low experimental efficiency of a laboratory, and facilitates overall experimental management.
Description
Technical Field
The invention relates to the field of computer software design, in particular to a laboratory management system.
Background
With the development of scientific technology, the requirements of enterprise scientific research units on informatization, intellectualization and safety are higher and higher. How to improve the management capability and the management efficiency of scientific research information and enhance the safety and the high efficiency of experiments is an important subject to be solved by many enterprises at present. The efficient management of the laboratory by the enterprise directly affects the product quality and the increase of the profit of the enterprise, and is a high-level embodiment of the enterprise. Management informatization of enterprise scientific research departments is an important guarantee for ensuring that the enterprise scientific research level is continuously improved. The enterprise laboratory is an important part for promoting the development of the scientific and technological level of the enterprise. Through research on the development conditions of the laboratory management systems of enterprises at home and abroad, the requirements of the enterprises on the information management system are more and more urgent, and the requirement on the information degree is higher and higher. At present, many enterprises are in an information-based starting stage, and scientific research departments of some enterprises still adopt traditional manual data input to control experimental equipment, so that data results are manually analyzed after data acquisition, and then data reports are manually edited, and the efficiency is low.
Disclosure of Invention
In view of this, the embodiment of the present invention provides a laboratory management system, so as to improve the experimental efficiency.
According to a first aspect, a laboratory management system, the system comprising:
the system comprises a basic information configuration module, a parameter database and a project parameter database, wherein the basic information configuration module is used for editing a parameter database of an experimental product and configuring experimental standard information which accords with an experimental product standard file based on the parameter database, the parameter database comprises a basic parameter database and a project parameter database, and the experimental standard information is used for standardizing project contents of the experimental product; the experiment scheme configuration module is used for selectively calling basic information configuration module data aiming at the experiment product and configuring and generating a specific experiment scheme so as to respond to a specific experiment project in the project content; and the experiment control center is used for establishing communication connection with the experiment product through a product communication command and carrying out specific experiments on the experiment product according to the specific experiment scheme.
Optionally, the basic information configuring module includes: the data dictionary module is used for receiving an external response for editing the description information of the experimental product and editing the description information of the experimental product by the external response; the project parameter module is used for receiving an external response of the editing parameter library and editing the parameter library according to the description information in the data dictionary by using the external response; the experimental project module is used for receiving an external response for editing the project content description information, editing the project content description information by the external response, and matching the parameter information in the parameter library with the project content to obtain the parameter information of the project content; the standard file module is used for receiving an external response for editing the standard file of the experimental product and editing the standard file of the experimental product according to the external response; the standard information module is used for configuring the experimental standard information of the project content by taking the experimental product standard file as a reference; and the communication command module is used for receiving an external response for maintaining the communication information and maintaining the communication information for establishing communication connection with the experimental product according to the external response.
Optionally, the standard information module includes an experiment description column, and the experiment description column is automatically loaded and generated by the system according to the project content.
Optionally, the protocol configuration module comprises: the setting and reading scheme configuration module is used for generating a reading strategy for reading the product information of the experimental product according to the standard defined by the experimental standard information through the received external response for configuring the setting and reading scheme; and the scheme configuration module is used for selecting specific experimental items in the item content and specific item parameters related to the specific experimental items aiming at the experimental products through the received external response for configuring the specific experimental schemes so as to generate the specific experimental schemes.
Optionally, the experiment control center module includes: the experiment loading module is used for loading the specific experiment scheme, carrying out experiment integrity check and then establishing communication connection with the experiment product through the product communication command; and the experiment operation module is used for reading the preset experiment flow of the specific experiment scheme after establishing communication connection with the experiment product, and developing an experiment according to the preset experiment flow.
Optionally, the experiment operation module displays and stores experiment data, experiment process information and abnormal log information in real time.
Optionally, after the experiment operation is completed, the experiment operation module uploads the data to the server by receiving an external response of the storage operation and updates the current experiment commission progress.
Optionally, the experiment running module stores data in the experiment process at preset time intervals, and is used for performing data recovery operation when the experiment process is abnormal.
Optionally, the system further comprises at least one of the following modules: the authority management module is used for performing informatization management and control on the authority of the experiment related personnel; the experiment entrustment management module is used for consulting the accepted entrustment experiment list information; the experimental equipment management module is used for establishing and managing a laboratory equipment ledger; the experimental environment monitoring module is used for carrying out related setting on the monitoring equipment according to the external response of the monitoring equipment, acquiring environmental data in real time, and carrying out environmental monitoring and environmental abnormity early warning in real time; the experiment data center is used for receiving equipment operation records and experiment historical data output by the experiment control center so as to carry out data lookup, data analysis, experiment report derivation and inspection data operation processing; and the document management center is used for editing or exporting the document related to the experiment.
Optionally, the bottom layer of the system adopts a multi-thread design, and supports simultaneous operation of multiple experiments; the system also comprises a bottom layer interface which is used for carrying out butt joint of the bottom layer interface and the new experimental equipment by utilizing a communication protocol.
The technical scheme of the invention has the following advantages:
the embodiment of the invention provides a laboratory management system. The system specifically comprises: the system comprises a basic information configuration module, an experiment scheme configuration module and an experiment control center. The project, the inspection standard and the basic description configuration of the test of the entrusted experiment to be carried out are configured in the basic information configuration module, then the specific project to be tested is determined from all the projects to be carried out of the test according to the basic information of the test in the experiment scheme configuration module, the project to be tested is automatically completed in the experiment control center according to the preset experiment process, the whole experiment process is informationized, and the experiment efficiency is greatly improved. The additional authority management module, the experiment entrustment management module, the experiment equipment management module, the experiment environment monitoring module, the experiment data center and the document management center respectively expand the authority management function, the entrustment experiment checking function, the equipment standing book recording function, the experiment environment monitoring function, the experiment data analyzing and counting function and the relevant document editing and exporting function of the system, so that the experiment operation can be conveniently, simply and safely carried out. The system provided by the invention has the advantages that the multithreading and the communication interface expansion are carried out on the bottom layer, so that the experimental efficiency of the system is higher, the application range is wider, the experimental process is well subjected to informatization management, the enterprise management efficiency is improved, and the enterprise management cost is reduced.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art 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 can be obtained by those skilled in the art without creative efforts.
FIG. 1 is a schematic diagram of a laboratory management system according to an embodiment of the present invention;
fig. 2 is a schematic structural diagram of a basic information configuration module of a laboratory management system according to an embodiment of the present invention;
FIG. 3 is a schematic diagram of a configuration module of a laboratory protocol of a laboratory management system according to an embodiment of the present invention;
FIG. 4 is an optimized structural diagram of a laboratory management system according to an embodiment of the present invention;
FIG. 5 is a schematic diagram of a parallel implementation of multiple experiments according to an embodiment of the present invention;
fig. 6 is a schematic structural diagram of an electronic device according to an embodiment of the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. 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 invention.
The technical features mentioned in the different embodiments of the invention described below can be combined with each other as long as they do not conflict with each other.
Referring to fig. 1, a laboratory management system according to an embodiment of the present invention includes:
the basic information configuration module 101 is configured to edit a parameter library of the experimental product, and configure experimental standard information conforming to the standard file of the experimental product based on the parameter library, where the parameter library includes a basic parameter library and a project parameter library, and the experimental standard information is used to standardize the project content of the experimental product. Specifically, the module mainly comprises a data dictionary, project parameters, experimental projects, standard files, standard information, communication commands and other modules, wherein a user edits a parameter library into two parts, one part is a basic parameter library containing basic standard parameters of experimental product basic information such as size, model, power, voltage and the like, and the other part is a project parameter library of project parameters such as voltage, current, product quantity, serial-parallel connection and the like required by a certain experimental project. The system provides the user with the corresponding experimental project content and standard information according to different experimental standard files through the parameters in the parameter library, and the standard information is the standard which the experiment needs to abide by or reach. The system supports error type experiments, latent and starting type experiments, temperature change experiments, electromagnetic compatibility type experiments, daily timing type experiments, constant type experiments, power consumption type experiments and the like. The project content is all relevant experiment projects included in each of the above-mentioned large-scale experiments, and after determining all project contents and experiment standards included in the entrusted experiment, the specific experiment scheme configuration is performed. The information-based unified management is carried out on the relevant information of the experiment, the experiment speed is accelerated, the error is avoided, and the experiment efficiency is improved.
The experiment scheme configuring module 102 is configured to selectively invoke basic information configuring module data for an experiment product, and configure and generate a specific experiment scheme in response to a specific experiment item in the item content. Specifically, the experiment scheme configuration module 102 mainly includes a configuration of a design copy scheme and a scheme configuration module. The configuration module of the copy scheme (which is a scheme for configuring copy product information) provides a function of configuring a communication command of a product to be tested by a user. And determining a scheme for reading the product information of the experimental product according to the relevant basic information configured by the experimental basic information module so as to configure relevant parameters for establishing communication connection with the product. The scheme configuration module (which is used for configuring the whole experiment process of a product) supports a user to establish a scheme according to different products and select configured experiment items, the system automatically generates configuration columns of the items according to information such as configuration parameters, parameter corresponding editing types, data ranges and data dictionaries of the experiment items of the user, and provides different editing modes of each column according to parameter setting, such as a pull-down box, a text box, a check box and a time control to help the user to realize the flexibility and the expansibility of scheme configuration. For example, in the temperature change experiment, to perform an experiment of the influence of temperature on the resistance change, a user finds out a specific experiment item only related to the influence of temperature on the resistance change from all related item contents, and then determines all parameters related to the specific experiment item to obtain a specific experiment scheme, and performs the next experiment.
And the experiment control center 103 is used for establishing communication connection with the experiment product through the product communication command and carrying out specific experiments on the target object according to the specific experiment scheme. Specifically, a user selects an experiment task, establishes communication connection with a product, automatically runs the experiment process after selecting the experiment process corresponding to the product under the experiment task, executes the experiment steps, sends instructions and related operations in the process, and performs operations such as communication interaction with the product and equipment, data acquisition and operation processing, and control over the experiment process. And (5) finishing each experiment by taking the detection basis in the standard information as an experiment standard. After the experiment is completed, the system automatically saves the experimental process data and updates the experimental progress.
Specifically, in an embodiment, as shown in fig. 2, the basic information configuration module 101 further includes:
and the data dictionary module 201 is used for receiving an external response for editing the description information of the experimental product and editing the description information of the experimental product by using the external response. Specifically, the user edits the related data dictionary through the interactive interface, and the content comprises names, applicable product models, descriptions, parameter information and the like.
And the project parameter module 202 is used for receiving an external response for editing the parameter library and editing the parameter library according to the description information in the data dictionary by using the external response. Specifically, a user edits a project parameter library through an interactive interface by referring to the data dictionary, and the content comprises information such as a project parameter code number, a parameter name, a parameter type, a control type, a data range, a parameter description and the like, and is used for configuring an experiment project and an experiment scheme.
The experimental project module 203 is configured to receive an external response for editing the description information of the project content, edit the description information of the project content with the external response, and match the parameter information in the parameter library with the project content to obtain the parameter information of the project content. Specifically, the user edits the experimental project of the product through the interactive interface, and the content includes information such as a project name, a project code, a project automation type, a project description, a project export data template, a selected project parameter, and a sub-project parameter, where the selected project parameter and the sub-project parameter are configured through the project parameter obtained by the module 202.
The standard file module 204 is configured to receive an external response for editing the standard file of the experimental product, and edit the standard file of the experimental product according to the external response. Specifically, the user performs operations such as adding, modifying, deleting, downloading and viewing on the product experiment standard file through the interactive interface.
And the standard information module 205 is used for configuring the experimental standard information of the project content based on the experimental product standard file. Specifically, the user configures corresponding experimental standard information for the entered experimental project. And selecting configured items by a user, and then adding standard file names, corresponding technical conditions and experimental methods. Specifically, in one embodiment, the standard information module includes an experiment description column, and the experiment description column is automatically loaded and generated by the system according to the project content. For example: in an initial inherent error experiment of the electric energy meter, an experiment standard file is JJF1245.1-2019, conditions are item 6.2.3, a method is item 9.2.1, a project type is an initial inherent error class, and a project mark is BsaicError. The project experiment description loaded by the system according to the project type and the identification comprises: access mode, balanced load, current (start), current (stop), power factor, active A, B, C, D, E class, reactive 0.5, 1.0, 2.0, 3.0 class. The user enters error limits for different levels of IR46 power meters under various conditions according to experimental criteria, for example as described in the project: under the conditions of no access mode, balanced load, current (starting) Itr, current (stopping) Imax and power factor of 0.5L, the active class A limit value is 2.0, the active class B limit value is 1.0, the active class C limit value is 0.5, the active class D limit value is 0.2 and the active class E limit value is 0.1.
And the communication command module 206 is used for receiving an external response for maintaining the communication information and maintaining the communication information for establishing communication connection with the experimental product by using the external response. Specifically, a user clicks the communication command management module through an interactive interface to maintain and manage communication protocol information supported by a product, wherein the communication protocol information includes information such as a communication command name, a communication identifier, an attribute/method, an operation type, a function code, an analysis name, an analysis format, an analysis unit, a conversion unit, a fixed type, a data identifier, a display mode and the like. The module facilitates establishing a connection with the product.
Specifically, in an embodiment, as shown in fig. 3, the experimental scheme configuration module 102 specifically includes:
and a reading scheme configuration module 207, configured to generate a reading strategy for reading the product information of the experimental product according to the standard defined by the experimental standard information through the received external response of the configuration reading scheme. Specifically, a user adds a setting and copying scheme classification according to a standard defined by experimental standard information through an interactive interface, establishes a scheme node, edits a scheme name, a communication password and an encryption mode, selects a command in a communication command library to form a setting and copying scheme detail, and sets related information of the command in the detail to include information such as a default value, comparison, a comparison range, formula comparison, a setting and copying remark.
And the scheme configuration module 208 is configured to select specific experimental items in the item content and specific item parameters related to the specific experimental items for the experimental product through the received external response for configuring the specific experimental scheme, so as to generate the specific experimental scheme. Specifically, the user first adds a scheme category and a specific scheme, and selects an item to which the scheme relates. The system automatically loads a scheme detail column for a user to edit according to parameters set by a project, if a scheme single-phase table is added, an initial inherent error project is selected, the system sets a corresponding project parameter module as a pull-down box control according to project parameters configured by the initial inherent error project, such as a load mode, the selection values of the load mode in a data dictionary are forward active, reverse active, forward reactive and reverse reactive, and the pull-down box of the scheme detail column load mode selects the contents of the forward active, reverse active, forward reactive and reverse reactive. The remaining scheme details are "phase type", "power factor", "voltage percentage", "current percentage", "number of errors", "number of turns", etc., and so on. For example, the user edits the load mode to be positive active, the phase type is a main loop, the power factor is 0.5L, the voltage percentage is 100%, the current percentage is Imin, the error times are 1, the number of turns is 1, and the rest configurations are similar according to the project requirements. The user can set the step sequence, the system provides a quick configuration interface for the user to select the experimental environment and automatically add the experimental steps in a checking mode, and a specific experimental scheme is automatically generated according to the configuration result.
Specifically, in an embodiment, the experiment control center 103 specifically includes:
and the experiment loading module 209 is used for loading the commission experiment after the scheme configuration is completed, carrying out experiment integrity check, and then establishing communication connection with the target object through a product communication command.
The experiment operation module 210 is configured to read a preset experiment process of a specific experiment scheme after establishing a communication connection with an experiment product, and develop an experiment according to the preset experiment process.
Specifically, the user selects the consignment test order, checks the experimental samples, the experimental equipment, the historical documents of the experimental environment conditions and the experimental items to carry out integrity check on the experiment, and the system loads the consignment order sample information selected by the user. And selecting an experiment scheme by a user according to the sample information, checking the experiment item to be developed, and adding the inspection basis of each item. And the system combines the inspection basis and the inspection scheme, and after the standard information of the project is matched, the user clicks to determine to enter an experiment operation interface.
The system loads the experiment items to be developed currently by the product, and automatically loads the detailed information corresponding to the flow lines and the flow lines of the project experiment by combining the project parameters and the project experiment scheme. The user can select operations such as continuous start, single-item start and single-point start on an experiment operation interface, when the user clicks and starts, the system performs communication interaction with products and equipment according to the content of a check flow line, displays and stores experiment data, process information, abnormal logs and the like in real time, and after the operation is finished, the user clicks and stores the data to upload the data to the server and updates the current experiment entrustment progress. The system supports the data recovery function after the experiment process is abnormal.
For example: a user selects a certain active A-level single-phase table entrusting order, an experimental scheme is selected to be a single-phase table scheme, an initial inherent error item configured under the system loading scheme is added to the item, the user adds JJF1245.1-2019 experimental basis to the item, the system is matched with standard information of the initial inherent error by adopting JJF1245.1-2019 experimental standard according to the fact that the content of a certain detailed line in the single-phase table scheme is a load mode which is positive active, the phase type is a main loop, the power factor is 0.5L, the voltage percentage is 100%, the current percentage is Imin, the error times are 1, and the number of turns is 1, the active A-level table is matched under the conditions that an access mode is free, the load is balanced, the Imin current is Itr-current (starting) Imax, and the power factor is 0.5L, and the limit value is 2.0. The rest of the detailed description is repeated in the same way.
The user enters an experiment operation interface after clicking and determining, a system loading project is 'initial inherent error', a project flow line is loaded into a project information column and a selection epitope column, and if the project information column is positive active; a main loop; 0.5L; 100 percent; imin, and the selected epitope is epitope 1. After clicking starts, the system sends a source raising control 1 to the stage body equipment according to the process content; 0.5L; imin; and (3) commanding by 100%, after the source is successfully raised, reading the error of the electric meter once by the system after the electric meter reads for one circle as error data, and comparing whether the error is within the range of +/-2.0, if the error is met, displaying that the content in the epitope 1 column is qualified, and if the error is not qualified, displaying that the content is not qualified.
If the item configuring the copying scheme is selected, such as 'alternating current sampling', the item flow line is loaded into an item information column, a selection table column and a copying parameter column, and if the item information column is positive active; a main loop; 0.5L; 100 percent; imin, and the selected epitope is epitope 1. After clicking starts, the system sends a source raising control 1 to the stage body equipment according to the process content; 0.5L; imin; and (3) commanding by 100%, and after the source is successfully raised, configuring the detail by the system according to a setting and reading scheme: the contents of A phase voltage, reading, default value 000.0, no comparison, identification 02010100 and the like send an A phase voltage reading instruction to a product, and the system displays the numerical value of the read A phase voltage and sets a reading column. If the scheme configuration copy result needs to be compared, comparing the content of the 'copy value' column with the content of the 'default value' column according to a specified rule, and finally giving a comparison result, otherwise, defaulting to be qualified. The rest of the detailed description is repeated in the same way. In the process, the process information of system interaction, the information of the detected product, the abnormal information and the like can be displayed in real time through the display. After the experiment is finished, the user clicks and saves the data, and then the system uploads the data to the server and updates the experiment entrusting progress of the initial inherent error project in the experiment entrusting.
Specifically, in an embodiment, the experiment operation module further has a function of displaying and storing experiment data, experiment process information, and abnormal log information in real time.
Specifically, in an embodiment, as shown in fig. 4, a laboratory management system provided in an embodiment of the present invention further includes at least one of the following modules:
and the authority management module 104 is used for performing informatization management and control on the authority of the experiment related personnel. Specifically, the user can edit information such as operation authority and login password of experiment related personnel through the module, and authority informatization management and control is achieved. The safety and reliability of the system are improved.
And an experiment request management module 105 for referring to the received request experiment. Specifically, the function that the user checks the relevant commission information of the accepted experiment commission is mainly provided, the function is convenient for looking up, and the user can inquire and enter the experiment commission bill information of the system, including commission book number, submission unit, product name, product model, accessory downloading and the like. And supporting the user to set the consignment priority and print the consignment worksheet and the sample identification strip.
The laboratory equipment management module 106 is used for establishing a laboratory equipment ledger, so that the laboratory equipment management is unified, clear and not easy to lose. Specifically, the method mainly provides information such as configuration laboratory equipment archives and support projects for users, and helps the users to establish laboratory equipment ledgers. The module provides manual test for a user on supporting equipment, and the supporting equipment comprises an electrostatic discharge generator, a three-phase cycle falling generator, an impulse current experimental device, a three-phase electric energy meter inspection device, a single-phase electric energy meter inspection device, a multi-path temperature tester, a high-low temperature alternating humidity and heat incubator and the like. The user inputs the related information of the laboratory related equipment, such as equipment number, equipment name, model, manufacturer, delivery date, equipment type, maintenance responsible person, equipment state, asset number, equipment support project, equipment extension attribute, equipment related file and the like. And manual testing of the supporting equipment by a user is provided, such as voltage rising, pulse reading, source descending, latent starting and the like, and real-time communication information and abnormal information are printed. The system saves the running record in the experimental process of the equipment, and can be inquired and analyzed by the user.
And the experimental environment monitoring module 107 is used for performing relevant setting on the monitoring equipment and acquiring environmental data in real time to perform environmental monitoring and abnormal early warning. Specifically, the system mainly provides relevant configuration for configuring environmental temperature and humidity monitoring equipment of each area of a laboratory by a user, and the user sets information such as the area where the temperature and humidity acquisition equipment is located, a communication mode, a communication address, an equipment address, an upper temperature limit, a lower temperature limit, an upper humidity limit, a lower humidity limit, sampling intervals and the like. The system is communicated with corresponding equipment according to the setting to acquire environment temperature and humidity data and monitor the environment temperature and humidity data in real time, and when the environment temperature and humidity exceed the limit, an abnormal early warning prompt is immediately sent out, so that the safety of the experimental process is improved.
And the experiment data center 108 is used for receiving the equipment operation records and experiment historical data output by the experiment control center so as to perform data consultation and data analysis. Specifically, the system provides a user to inquire data such as historical experimental data, abnormal logs, user operation records and information modification records. And supporting a project corresponding template configured by a user, and providing a function of exporting an experiment report from the experiment entrusted batch by the user by the system. And the system automatically performs operation processing on the inspection data according to the export template selected by the project and exports the experimental report of the word version or the excel version. Provides convenience for analysis after experiments.
And the document management center 109 is used for editing or exporting the document related to the experiment. Specifically, the functions of uploading, auditing and downloading equipment files, entrusted documents and experiment report templates and the like by a user are supported, the information management and control and sharing support of the documents are realized, and the use of workers is facilitated.
Specifically, in an embodiment, as shown in fig. 5, the bottom layer of the laboratory management system provided in the embodiment of the present invention employs a multi-thread design, which supports multiple experiments to run simultaneously. The system adopts a layered architecture and a multithreading technology to realize simultaneous data monitoring and data display on a plurality of products, and realizes that automatic experiments and manual experiments of the products can be controlled by the system. The laboratory management system provided by the invention is provided with a bottom layer interface, and the bottom layer interface is in butt joint with new experimental equipment by utilizing a communication protocol. The system supports the rapid expansion of different types and different protocol devices, and newly added devices can realize control only by developing a device control bottom layer without modifying a service logic layer and a presentation layer.
The functions between the above system modules are illustrated as follows by a specific embodiment:
the user selects an experiment entrusting order with a certain product model of the intelligent electric energy meter, product information is model 0001, reference voltage is 220V, current specification is 0.2-0.5(60) A, frequency is 50Hz, active constant is 2000, reactive constant/, active grade B, product name intelligent electric energy meter, experiment entrusting order number is 0000001, entrusted experiment items comprise experiments such as visual inspection, initial inherent error, starting, shunt running, electric energy meter constant, voltage change and high temperature, and the number of samples is 6.
After the user confirms that the entrusting list is selected and clicks to confirm, the system displays the information of the product in the entrusting list in the information column of the selection list interface table, the entrusting item combines with the item configured by the current computer and the experimental item progress, and the item state are displayed in the experimental item column, if the item name is an initial inherent error, the item state is not completed; the project name is alternating damp-heat experiment, and the project state is that the equipment does not support; the rest items are analogized in turn.
The user also needs to configure specific experimental parameters, such as the table type is static, the phase line is single phase, the access mode is direct access, the tide direction is single phase/active, the insulation protection type is type II and the like, the use environment is outdoor/type II and the like, and the parameters and the parameter selection content can be expanded according to the product type. The parameters of the functional configuration can further meet the standard information matching of the product under other special conditions.
And after the user completes the supplement of the specific experiment parameters, selecting the experiment scheme and clicking a selection button of the experiment scheme column. The system automatically displays the experimental scheme configured by the user, and the user selects the scheme which is edited in advance, such as the scheme name which is a single-phase table. And double-clicking the selected scheme node to complete scheme selection. The system makes the following judgments according to the scheme selected by the user: and according to the items under the scheme selected by the user, rejecting the contents which are not contained in the scheme items in the experimental item list. After the screening, the user then checks the experimental items to be developed, such as visual check, voltage change experiment, etc.
After the user selects the experiment scheme, a check basis is added to each experiment item, the user clicks the item line of the experiment item column, the additional button of the check basis column is clicked, and the system automatically displays the standard file added by the user. After the user clicks and determines the standard click to be added, the system stores the standard information of the file corresponding to the item into a cache; the proof bases of the other items also operate in sequence.
After the configuration is finished, the user checks the sample to be tested currently, clicks to determine, and the system compares whether the standard information can be found in the added inspection basis according to the scheme configured corresponding to the test item to be developed this time.
The protocol configuration step rows are shown in table 1, as selected visual inspection items. (visual inspection experiment of intelligent electric energy meter can judge whether the appearance of the product meets the standard requirements, and the product mainly introduces how the system supports the flow of manual experiment.)
TABLE 1 visual inspection item execution procedure
Serial number | Experimental site |
1 | Unit of measurement |
2 | Rated working condition |
3 | Watch case and window |
4 | Display device |
5 | Test output |
6 | Key test |
The added inspection basis is JJF1245.1-2019, the technical standard of the system matching visual inspection project is JJF1245.1-2019, and the standard information under the standard file is shown in Table 2. The experimental points of the scheme configuration can be matched with the corresponding experimental requirements under the basis. The system stores the matched standard information into a cache.
TABLE 2 Standard information of Standard document JJF1245.1-2019
The scheme rows are shown in table 3 as the selected voltage change item. (voltage change experiment of intelligent electric energy meter, namely under the condition of voltage condition change, whether the change amount of product inspection error meets the standard requirement or not, and how the system supports the flow of automatic experiment is mainly introduced.)
TABLE 3 arrangement of Voltage Change terms
The added verification basis is JJF1245.1-2019, and the technical standard of the system matching voltage change project is standard information configured under JJF1245.1-2019, and is shown in Table 4. The system stores the matched corresponding standard information value 0.7 which is within the current range Itr-Imax, the power factor of the intelligent electric energy meter is 1.0, and the active level is B level in a cache.
Table 4 standard information of voltage change items under standard file JJF1245.1-2019
Access mode | Current (play) | Current (stop) | Power factor | A | B | C | D | E |
Is free of | Itr | Imax | 1.0 | 1.0 | 0.7 | 0.2 | 0.1 | 0.05 |
Is free of | Itr | Imax | 0.5L | 1.5 | 1.0 | 0.4 | 0.2 | 0.1 |
And repeating the rest items, finding the matched standard information value and storing the value in a cache, and if the system cannot find the corresponding standard information, prompting which items do not match the standard information. And after the items to be selected and developed are successfully matched, the system can enter a checking interface.
After the system enters a checking interface, judging whether equipment corresponding to the currently developed project carries out daily check, if not, prompting to carry out the daily check; if so, the normal loading item checks the relevant content, including the standard information of the item, the item step line and the like.
The user clicks the continuous button, and the system starts to check in sequence according to the project sequence:
1. visual inspection: the automation type of the project is manual, the project type is appearance inspection type, a user interface is provided, the interface displays the experimental points and the experimental requirements corresponding to the experimental points, and the interface provides the manual inspection results which can be manually input into the experimental points by a user. And if the input result of the user is in accordance, the system displays the content of the epitope 1 column in a qualified mode √ or x mode if the input result is not in accordance. After the project is finished, the system updates the qualified display V of the project according to the results of all the experimental points, and if the results are not qualified, the display X is displayed.
2. Voltage change experiment: the automation type of the project is automatic, and the project type is an error experiment. The steps of the system according to the scheme of table 3 in the first row are as follows:
firstly, under the condition that the voltage is 100% of reference voltage, the phase type is a main loop, the load mode is positive active, the power factor is 1.0, and the current is Imax, reading the average value of two errors as an error value 1 under the 100% of reference voltage; reading the error value 1 under the reference voltage of 90% as the average value of the errors of two times under the condition that other conditions are unchanged and the voltage is 90%; calculating the change quantity of the error value 1 under the reference voltage of 90 percent and the error value 1 under the reference voltage of 100 percent; reading the error value 1 under the reference voltage of 110% as the average value of the errors of two times under the condition that other conditions are unchanged and the voltage is 110%; calculating the change quantity of the error value 1 under the 110% reference voltage and the error value 1 under the 100% reference voltage; the verification step lines generated according to this scheme line are as follows. The contents of the other scheme rows corresponding to the inspection step rows are analogized in sequence. (Note that the experimental steps are generated by the system according to the experimental standard and the experimental flow of the product, and the step mode of the experiment can be determined by configuring the type information and the project parameters of the project by the user.)
The system performs project information according to the steps: a main loop; positive active power; 1.0; 100 percent; imax, controlling the equipment bound by the project to be a single-phase electric energy meter inspection device, and forming an equipment control command 1 according to the project information; 1.0; imax; 100%, after receiving a command successfully returned by the equipment source rising, the system automatically reads an error result output by the electric energy meter inspection device under the voltage condition, and according to the error times 2, after the system reads errors twice, the average value is taken as an error value 1 under the reference voltage condition, and the error value is filled in the first line of the table 5 as a result value. (Note: in the present example, three product experiments were conducted simultaneously for the development of 3 epitopes.)
The system performs project information according to the steps: a main loop; positive active power; 1.0; 90 percent; imax, controlling the equipment bound by the project to be a single-phase electric energy meter inspection device, and forming an equipment control command 1 according to the project information; 1.0; imax; and 90%, after receiving a command successfully returned by the equipment source rising, automatically reading an error result output by the electric energy meter inspection device under the voltage condition by the system, reading the error twice by the system according to the error times 2, taking the average value as an error value 1 under the 90% reference voltage condition, and filling the error value in the second row of the table 5 as a result value.
The system calculates the difference value between the error value 1 under the condition of 90% reference voltage and the error value 1 under the condition of reference voltage as the error change quantity, and judges whether the result value is in the range of +/-0.7, if so: then the result value is displayed in the third line of table 5 for red font; otherwise: the result value is displayed in the third line of table 5 for black font.
The system performs project information according to the steps: a main loop; positive active power; 1.0; 110 percent; imax, controlling the equipment bound by the project to be a single-phase electric energy meter inspection device, and forming an equipment control command 1 according to the project information; 1.0; imax; 110%, after receiving a command returned successfully by the equipment source raising, the system automatically reads the error result output by the electric energy meter inspection device under the voltage condition, and according to the error numerical value 2, the system reads the error twice again, takes the average value as the error value 1 under the 110% reference voltage condition, and fills the error value in the fourth line of the table 5 as the result value.
The system calculates the difference value between the error value 1 under the 110% reference voltage condition and the error value 1 under the reference voltage condition as the error change amount, judges whether the result value is in the range of +/-0.7, and if not: the result value in the fifth line is displayed for the red font; the method comprises the following steps: the resulting values in the fifth line of table 5 are displayed for black fonts.
TABLE 5 table of voltage change experiment results
Project information | Epitope 1 | Epitope 2 | Epitope 3 |
A main loop; positive active power; 1.0; 100 percent; imax | |||
A main loop; positive active power; 1.0; 90 percent; imax | |||
Amount of change | |||
A main loop; positive active power; 1.0; 110 percent; imax | |||
Amount of change |
And (5) repeating the operation of the other steps until each project is finished, automatically stopping the system, and sending a device source descending control command. The system stores experimental process data, environmental temperature and humidity data and the like. The user clicks to save, the system provides the items selected to be saved by the user, and the results can be uploaded to the server database after clicking to save; and for unqualified items, the mail notification function provided by the system can support the user to quickly generate unqualified mail contents and send the unqualified mail contents to the client. The user can inquire the process data of the inspection according to the conditions of the order number, the operator, the inspection time and the like in the inspection data inquiry interface. Meanwhile, the system supports users to inquire data such as abnormal logs, user operation records, information modification records and the like. And a report export module of the system provides a function of exporting the experiment report from the experiment entrusted batch by the user. The system automatically performs operation processing on the inspection data according to the export template selected by the project, and automatically exports the experimental report of the word version or the excel version.
Through the cooperative cooperation of the above components, the laboratory management system provided by the embodiment of the invention. The system specifically comprises: the system comprises a basic information configuration module, an experiment scheme configuration module and an experiment control center. The project, the inspection standard and the basic description configuration of the test of the entrusted experiment to be carried out are configured in the basic information configuration module, then the specific project to be tested is determined from all the projects to be carried out of the test according to the basic information of the test in the experiment scheme configuration module, the project to be tested is automatically completed in the experiment control center according to the preset experiment process, the whole experiment process is informationized, and the experiment efficiency is greatly improved. The additional authority management module, the experiment entrustment management module, the experiment equipment management module, the experiment environment monitoring module, the experiment data center and the document management center respectively expand the authority management function, the entrustment experiment checking function, the equipment standing book recording function, the experiment environment monitoring function, the experiment data analyzing and counting function and the relevant document editing and exporting function of the system, so that the experiment operation can be conveniently, simply and safely carried out. The system provided by the invention has the advantages that the multithreading and the communication interface expansion are carried out on the bottom layer, so that the experimental efficiency of the system is higher, the application range is wider, the experimental process is well subjected to informatization management, the enterprise management efficiency is improved, and the enterprise management cost is reduced.
Fig. 6 shows an electronic device of an embodiment of the present invention, the device including: the processor 901 and the memory 902 may be connected by a bus or other means, and fig. 6 illustrates an example of a connection by a bus.
The memory 902, which is a non-transitory computer-readable storage medium, may be used to store non-transitory software programs, non-transitory computer-executable programs, and modules, such as program instructions/modules corresponding to the methods in the above-described method embodiments. The processor 901 executes various functional applications and data processing of the processor by executing non-transitory software programs, instructions and modules stored in the memory 902, that is, implements the methods in the above-described method embodiments.
The memory 902 may include a program storage area and a data storage area, wherein the program storage area may store an operating system, an application program required for at least one function; the storage data area may store data created by the processor 901, and the like. Further, the memory 902 may include high speed random access memory, and may also include non-transitory memory, such as at least one magnetic disk storage device, flash memory device, or other non-transitory solid state storage device. In some embodiments, the memory 902 may optionally include memory located remotely from the processor 901, which may be connected to the processor 901 via a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.
One or more modules are stored in the memory 902, which when executed by the processor 901 performs the methods in the above-described method embodiments.
Specifically, in an embodiment, the electronic device further includes:
the display is connected with the processor and used for displaying the experimental data and/or the environmental data;
and the monitoring equipment is connected with the processor and is used for acquiring the environmental data to monitor the environment. Specifically, in the embodiment of the present invention, the monitoring device includes but is not limited to: camera, temperature sensor, humidity transducer, gas concentration sensor.
The specific details of the electronic device may be understood by referring to the corresponding related descriptions and effects in the above method embodiments, and are not described herein again.
It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, and the implemented program can be stored in a computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. The storage medium may be a magnetic Disk, an optical Disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a Flash Memory (Flash Memory), a Hard Disk (Hard Disk Drive, abbreviated as HDD) or a Solid State Drive (SSD), etc.; the storage medium may also comprise a combination of memories of the kind described above.
Although the embodiments of the present invention have been described in conjunction with the accompanying drawings, those skilled in the art may make various modifications and variations without departing from the spirit and scope of the invention, and such modifications and variations fall within the scope defined by the appended claims.
Claims (10)
1. A laboratory management system, characterized in that the system comprises:
the system comprises a basic information configuration module, a parameter database and a project parameter database, wherein the basic information configuration module is used for editing a parameter database of an experimental product and configuring experimental standard information which accords with an experimental product standard file based on the parameter database, the parameter database comprises a basic parameter database and a project parameter database, and the experimental standard information is used for standardizing project contents of the experimental product;
the experiment scheme configuration module is used for selectively calling basic information configuration module data aiming at the experiment product and configuring and generating a specific experiment scheme so as to respond to a specific experiment project in the project content;
and the experiment control center is used for establishing communication connection with the experiment product through a product communication command and carrying out specific experiments on the experiment product according to the specific experiment scheme.
2. The system of claim 1, wherein the basic information configuration module comprises:
the data dictionary module is used for receiving an external response for editing the description information of the experimental product and editing the description information of the experimental product by the external response;
the project parameter module is used for receiving an external response of the editing parameter library and editing the parameter library according to the description information in the data dictionary by using the external response;
the experimental project module is used for receiving an external response for editing the project content description information, editing the project content description information by the external response, and matching the parameter information in the parameter library with the project content to obtain the parameter information of the project content;
the standard file module is used for receiving an external response for editing the standard file of the experimental product and editing the standard file of the experimental product according to the external response;
the standard information module is used for configuring the experimental standard information of the project content by taking the experimental product standard file as a reference;
and the communication command module is used for receiving an external response for maintaining the communication information and maintaining the communication information for establishing communication connection with the experimental product according to the external response.
3. The system of claim 2, wherein the criteria information module comprises an experiment description column, and the experiment description column is generated by automatic loading of the system according to the project content.
4. The system of claim 1, wherein the protocol configuration module comprises:
the setting and reading scheme configuration module is used for generating a reading strategy for reading the product information of the experimental product according to the standard defined by the experimental standard information through the received external response for configuring the setting and reading scheme;
and the scheme configuration module is used for selecting specific experimental items in the item content and specific item parameters related to the specific experimental items aiming at the experimental products through the received external response for configuring the specific experimental schemes so as to generate the specific experimental schemes.
5. The system of claim 4, wherein the experiment control center module comprises:
the experiment loading module is used for loading the specific experiment scheme, carrying out experiment integrity check and then establishing communication connection with the experiment product through the product communication command;
and the experiment operation module is used for reading the preset experiment flow of the specific experiment scheme after establishing communication connection with the experiment product, and developing an experiment according to the preset experiment flow.
6. The system of claim 5, wherein the experiment running module displays and saves experiment data, experiment process information and abnormal log information in real time.
7. The system of claim 5, wherein the experiment running module uploads the data to the server and updates the current experiment commission schedule by receiving an external response to the save operation after the experiment running is completed.
8. The system of claim 5, wherein the experiment running module saves data in the experiment process at preset time intervals for performing a data recovery operation when an abnormality occurs in the experiment process.
9. The system of claim 1, further comprising at least one of the following modules:
the authority management module is used for performing informatization management and control on the authority of the experiment related personnel;
the experiment entrustment management module is used for consulting the accepted entrustment experiment list information;
the experimental equipment management module is used for establishing and managing a laboratory equipment ledger;
the experimental environment monitoring module is used for carrying out related setting on the monitoring equipment according to the external response of the monitoring equipment, acquiring environmental data in real time, and carrying out environmental monitoring and environmental abnormity early warning in real time;
the experiment data center is used for receiving equipment operation records and experiment historical data output by the experiment control center so as to carry out data lookup, data analysis, experiment report derivation and inspection data operation processing;
and the document management center is used for editing or exporting the document related to the experiment.
10. The system of claim 1, wherein the system bottom layer adopts a multi-thread design, and supports simultaneous operation of multiple experiments; the system also comprises a bottom layer interface which is used for carrying out butt joint of the bottom layer interface and the new experimental equipment by utilizing a communication protocol.
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