CN113918445A - Laboratory test standard automatic identification method - Google Patents

Abstract

The invention discloses an automatic identification method for laboratory test standards, which comprises the following implementation process steps: according to the test standard text module 1, parameter setting and condition setting are carried out on the equipment parameter and control module 2, the sample parameter and control module 3, the ending condition setting module 4 and the judgment condition setting module 5; after the setting of the equipment parameter and control module 2 and the sample parameter and control module 3 is finished, protocol statements of equipment communication are generated through various equipment bus protocol conversion packet modules 6; the end condition setting module 4 and the judgment condition setting module 5 identify the collected data to be judged through the end condition judgment module 7 after the setting is finished; the preset timeline flow module 8 sequences the statements generated by the bus protocol conversion packet module 6 and the ending condition judgment module 7 of the various devices, and synthesizes a test language segment; the standard database module 9 stores the above test language segments.

Description

Laboratory test standard automatic identification method

Technical Field

The invention belongs to the field of automatic detection control, and particularly relates to a laboratory test standard automatic identification method.

Background

Laboratory operations are required to follow corresponding test operation standards and judgment criteria, and the test operation of the laboratory is performed manually according to the standards all the time. The method comprises the steps of installing a tested sample in a laboratory, initializing equipment after the tested sample is electrified and started, inputting test parameters manually according to a standard test flow, changing the parameters of the tested sample in the process, judging a test conclusion after the test is finished, disassembling the sample, and restoring the initialization of the laboratory. The laboratory procedures are still completed manually by operators, so that if a certain procedure is mistaken for a certain reason in the laboratory test operation process, the whole test is inevitably required to be restarted, very large energy waste can be caused, the overall test efficiency is low, the operation habits of the operators are different in the operation process, the conclusion of the test is influenced, and the consistency of the test data is greatly influenced. In order to solve various problems existing in the laboratory, the invention designs a method special for automatic identification of laboratory experiment standards.

Chinese patent application 201810416032.8 discloses an automatic data acquisition and intelligent management and control system for laboratory instruments, which comprises a storage module, a data transmission management module, and an instrument control and state monitoring module; the data transmission management module comprises a data acquisition mode setting unit, a data transmission mode setting unit, a data acquisition unit, a data verification unit, a data correction unit and a data validity early warning unit; the instrument control and state monitoring module comprises an instrument state monitoring unit, an instrument information acquisition unit and an instrument control unit; the storage module comprises a data storage unit, an instrument state information storage unit and a standard library storage unit. The invention can complete the automatic collection of the detection data of various chemical analysis instruments, complete the real-time monitoring of the data extraction process and the instrument state, and ensure the accuracy and the effectiveness of the collected data. However, the method is limited to analyzing and processing the data of the test results, and the artificial factors of the whole previous experimental operation flow are still not eliminated, so that the consistency of the experimental results is to be improved.

Chinese patent application 201911280736.8 discloses a method for automatically collecting data of a detection instrument, comprising the following steps: (1) the data acquisition module records the information stored in each group of detection instruments into a laboratory information management system and generates a unique standard data format; (2) selecting a detection instrument needing to be tested in a laboratory information management system, and sending a detection index instruction to the detection instrument; (3) and converting the new data detected by the detection instrument and the standard data into readable data through a data analysis module, independently comparing the readable data by using a data comparison module, and forming a final detection result report by using the compared result. The method reduces the traditional working mode of manually inputting the detection result and improves the working efficiency of detection. However, the same experimental operation process is still performed manually, and therefore, the consistency of the obtained detection results is still to be further discussed.

Disclosure of Invention

In order to solve various problems in the prior art, the invention provides an automatic identification method for laboratory test standards, which comprises the following steps:

(1) according to the test standard text module 1, parameter setting and condition setting are carried out on the equipment parameter and control module 2, the sample parameter and control module 3, the ending condition setting module 4 and the judgment condition setting module 5;

(2) after the setting of the equipment parameter and control module 2 and the sample parameter and control module 3 is finished, protocol statements of equipment communication are generated through various equipment bus protocol conversion packet modules 6;

(3) the end condition setting module 4 and the judgment condition setting module 5 identify the collected data to be judged through the end condition judgment module 7 after the setting is finished;

(4) the preset timeline flow module 8 sequences the statements generated by the bus protocol conversion packet module 6 and the ending condition judgment module 7 of the various devices, and synthesizes a test language segment;

(5) the standard database module 9 stores the above test language segments.

Further, the device parameters and the control module 2 function as: for controlling the addition, modification or deletion of the number of parameters, for defining the characteristics of the parameters, for logically defining the relationship between a plurality of parameters, for assigning values to the parameters.

Further, the sample parameters and the control module 3 function as: the device is used for adding, modifying or deleting the quantity of the control parameter of the tested sample, defining the characteristic of the parameter and assigning the value to the parameter.

Still further, the characteristics of the parameters include name, communication type, data type, timing.

Further, the ending condition setting module 4 is used for: different termination modes can be selected for specific test items, and the termination modes comprise termination of judgment conditions, termination of time, termination of steady state or termination of unsteady state.

Further, the determination condition setting module 5 functions to: the decision value for the criteria can be defined in a variable manner and the decision type and variable characteristics can be selected.

Further, the various device bus protocol conversion packet modules 6 function as: and integrating according to the communication types and protocols of the equipment and the model machine, and automatically forming specific protocol statements according to the communication types and parameters.

Further, the ending condition determining module 7 functions to: and generating a corresponding statement according to a set condition, wherein the statement can be bound and identified by the test software through channel data.

Further, the preset timeline flow module 8 functions as: the ordering of the protocol statements and conditional statements may be done according to a relative timeline.

Further, the standard database module 9 functions as: and storing the sentences generated by the time line by using a relational database and designing an incidence relation.

Compared with the prior art, the invention has the following beneficial effects:

the invention converts the text of the test standard into the language which can be identified by the test software through the test standard editor, and utilizes the test software to automatically execute the language to control various devices and tested samples in a laboratory to replace the operation of personnel so as to achieve the consistency of test operation.

Drawings

FIG. 1 is a schematic flow chart of a standard automated identification method for laboratory tests according to the present invention;

wherein the reference numerals are as follows:

1. testing a standard text module; 2. a device parameter and control module; 3. a sample parameter and control module; 4. an ending condition setting module; 5. a determination condition setting module; 6. various equipment bus protocol conversion packet modules; 7. an ending condition judgment module; 8. presetting a timeline flow module; 9. a standard database module; 10. a laboratory control module.

FIG. 2 is a schematic flow chart of a maximum operation refrigeration test standard automatic identification method according to the national standard GB/T7725-2004 air conditioner regulator.

Detailed Description

The present invention will be further explained with reference to specific examples in order to make the technical means, the technical features, the technical objectives and the effects of the present invention easier to understand, but the following examples are only preferred embodiments of the present invention, and not all embodiments of the present invention. Based on the embodiments in the implementation, other embodiments obtained by those skilled in the art without any creative efforts belong to the protection scope of the present invention. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

Example 1

An automated identification method of laboratory test standards, as shown in fig. 1, comprises the following steps:

(1) according to the test standard text module 1, parameter setting and condition setting are carried out on the equipment parameter and control module 2, the sample parameter and control module 3, the ending condition setting module 4 and the judgment condition setting module 5;

(2) after the setting of the equipment parameter and control module 2 and the sample parameter and control module 3 is finished, protocol statements of equipment communication are generated through various equipment bus protocol conversion packet modules 6;

(3) the end condition setting module 4 and the judgment condition setting module 5 identify the collected data to be judged through the end condition judgment module 7 after the setting is finished;

(4) the preset timeline flow module 8 sequences the statements generated by the bus protocol conversion packet module 6 and the ending condition judgment module 7 of the various devices, and synthesizes a test language segment;

(5) the standard database module 9 stores the above test language segments.

Further, the device parameters and the control module 2 function as: for controlling the addition, modification or deletion of the number of parameters, for defining the characteristics of the parameters, for logically defining the relationship between a plurality of parameters, for assigning values to the parameters.

Further, the sample parameters and the control module 3 function as: the device is used for adding, modifying or deleting the quantity of the control parameter of the tested sample, defining the characteristic of the parameter and assigning the value to the parameter.

Still further, the characteristics of the parameters include name, communication type, data type, timing.

Further, the ending condition setting module 4 is used for: different termination modes can be selected for specific test items, and the termination modes comprise termination of judgment conditions, termination of time, termination of steady state or termination of unsteady state.

Further, the determination condition setting module 5 functions to: the decision value for the criteria can be defined in a variable manner and the decision type and variable characteristics can be selected.

Further, the various device bus protocol conversion packet modules 6 function as: and integrating according to the communication types and protocols of the equipment and the model machine, and automatically forming specific protocol statements according to the communication types and parameters.

Further, the ending condition determining module 7 functions to: and generating a corresponding statement according to a set condition, wherein the statement can be bound and identified by the test software through channel data.

Further, the preset timeline flow module 8 functions as: the ordering of the protocol statements and conditional statements may be done according to a relative timeline.

Further, the standard database module 9 functions as: and storing the sentences generated by the time line by using a relational database and designing an incidence relation.

Example 2

The maximum operation refrigeration test of the standard of national standard GB/T7725-2004 air conditioner regulator.

The test method is to control the state of the air conditioner: damper, set temperature, wind speed, etc.; controlling a power supply source of the laboratory equipment; controlling the laboratory equipment to control the laboratory environment; and controlling the air conditioner according to the time line.

The judging method is that the air conditioner operates normally and the trip cannot occur; the air conditioner cannot trip due to current overload.

Standard identification framework and its working principle:

as shown in fig. 2, the air-conditioning state setting module: and integrating infrared and radio frequency control protocols. Laboratory control equipment design module: and integrating the equipment control protocol of the laboratory. The power supply design module: protocol integration for power supplies. A time sequence control module: ordering of protocol statements is performed according to a relative timeline. The laboratory collecting equipment judgment module: collecting data and presetting a judgment value. Standard test command set: the data judgment of the laboratory collection equipment is carried out by defining the collection equipment in the judgment parameters and the judgment types. Standard library: all the standard test command sets are stored in a cloud database in a tree management mode, and the standard test command sets are obtained through the database in a laboratory connected to the cloud. Intelligent laboratory test software: the method of identifying test criteria and decision criteria is performed by a time-sequenced command set.

Finally, it should be noted that the above-mentioned contents are only used for illustrating the technical solutions of the present invention, and not for limiting the protection scope of the present invention, and that the simple modifications or equivalent substitutions of the technical solutions of the present invention by those of ordinary skill in the art can be made without departing from the spirit and scope of the technical solutions of the present invention.

Claims (10)

1. An automatic identification method for laboratory test standards is characterized by comprising the following steps:

(1) setting parameters and conditions of the equipment parameter and control module, the sample parameter and control module, the ending condition setting module and the judgment condition setting module according to the test standard text module;

(2) after the equipment parameter and control module and the sample parameter and control module are set, protocol statements of equipment communication are generated through various equipment bus protocol conversion packet modules;

(3) the end condition setting module and the judgment condition setting module identify the acquired data to be judged through the end condition judgment module after setting is finished;

(4) the preset time line flow module sequences the sentences generated by the bus protocol conversion packet module and the ending condition judgment module of the various devices and synthesizes test language segments;

(5) and the standard database module stores the test language segments.

2. The automated laboratory test standard identification method according to claim 1, wherein the equipment parameter and control module is used for controlling the addition, modification or deletion of the number of parameters, defining the characteristics of the parameters, defining the logical relationship among a plurality of parameters, and assigning values to the parameters.

3. The method of claim 1, wherein the sample parameter and control module is configured to add, modify or delete a number of control parameters of the sample to be tested, to define characteristics of the parameters, and to assign values to the parameters.

4. The method of claim 2 or 3, wherein the characteristics of the parameters comprise name, communication type, data type, and timing.

5. The method of claim 1, wherein the ending condition setting module ends in a manner of determining ending condition, ending time, ending steady state or ending unsteady state.

6. The method as claimed in claim 1, wherein the criterion of the criterion setting module is variable.

7. The method of claim 1, wherein the device bus protocol conversion packet modules are used for integrating according to communication types and protocols of devices and prototypes, and automatically forming specific protocol statements according to the communication types and parameters.

8. The method of claim 1, wherein the end condition determining module is configured to generate a corresponding statement according to a set condition.

9. The method of claim 1, wherein the predetermined timeline flow module is configured to sort the protocol statements and the conditional statements according to a relative timeline.

10. The method as claimed in claim 1, wherein the standard database module is used for storing the sentences generated by the time line and designing the association relationship.

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