CN210377463U - System data management system - Google Patents

Abstract

The utility model discloses a system data management system, which comprises a plurality of laser devices, a power supply device, a vacuum device and an optical cavity device, wherein the laser devices are connected with a laser device monitoring device through a serial bus I, and the power supply device, the vacuum device and the optical cavity device are respectively connected with the power supply device monitoring device, the vacuum device monitoring device and the optical cavity device monitoring device through a serial bus II; the laser equipment monitoring device, the vacuum equipment monitoring device and the optical cavity equipment monitoring device are respectively connected with a data centralized acquisition system through an Ethernet bus, and the data centralized acquisition machine realizes data transmission with a data management system through TCP/IP communication. The utility model discloses alleviate experimenter's work load, improve the work rate, provide detailed, accurate experimental data for the experimenter simultaneously, guarantee the historical authenticity of data.

Description

System data management system

Technical Field

The utility model belongs to the data and the information management field of system, concretely relates to system data management system.

Background

In the fields of scientific experiments, monitoring control, factories and production, a plurality of system performance parameters are related to acquisition and data online and offline management, the related parameters need to be acquired and displayed, acquisition of the related parameters under the reliable communication condition is realized, and effective management and statistical analysis are carried out on the data.

Generally, some systems do not have an automatic management system for historical query and analysis of data, automatic analysis report and report functions. Generally, experimental data of some systems are recorded at a manual average time interval by adopting a single experimental device, then data corresponding to a time point are fitted, and the change trend among a plurality of important relevant parameters and the influence change relation of key points are observed, so that the historical query of the data and the historical change relation among a plurality of influence parameters cannot be carried out. However, with the increase of the data volume of the special system and the occurrence of abnormality of the system, the analysis of the device parameters and the change relationship affecting the target parameters is realized, so that the automatic historical query, analysis and statistical summarization of the data have very important significance for some systems, and meanwhile, the functions of providing an automatic data analysis report for each experiment of some systems, automatically summarizing a report according to the abnormal conditions and the like are required, so that the data management and analysis capability of some systems can be improved, and a certain data support is provided for the experiment planning.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a put forward in order to overcome the shortcoming that exists among the prior art, its purpose provides a system data management system.

The utility model discloses a realize through following technical scheme:

a system data management system comprises a plurality of laser devices, power supply devices, vacuum devices and optical cavity devices, wherein the laser devices are connected with a laser device monitoring device through a serial bus I, and the power supply devices, the vacuum devices and the optical cavity devices are respectively connected with the power supply device monitoring device, the vacuum device monitoring device and the optical cavity device monitoring device through a serial bus II; the laser equipment monitoring device, the vacuum equipment monitoring device and the optical cavity equipment monitoring device are respectively connected with a data centralized acquisition system through an Ethernet bus, and the data centralized acquisition machine realizes data transmission with a data management system through TCP/IP communication.

The data management system comprises:

the data reading module is used for reading equipment monitoring data in real time;

the human-computer interaction display module is used for setting parameters and inputting experimental condition data;

the data storage module is used for storing the data read by the data reading module into equipment monitoring data, parameter setting data set by the man-machine interaction display module and condition change data in real time;

the data query analysis module is used for displaying and outputting the parameter graph after acquiring query analysis data from the data storage module;

the experimental process management module is used for displaying experimental setting data;

and the report counting module acquires the report data from the data storage module to generate a corresponding data analysis report and a corresponding statistical report.

The laser devices are arranged in parallel; a plurality of the power supply devices are arranged in parallel; a plurality of vacuum devices are arranged in parallel; and a plurality of optical cavity devices are arranged in parallel.

The data centralized acquisition system and the data management system are both PC machines.

The utility model has the advantages that:

the utility model provides a system data management system and method, adopt the database system, modular programming structure and TCP/IP real-time data acquisition technology realize the real-time demonstration to system key data, the historical inquiry of all relevant parameter data and information, the contrast, carry out automatic statement analysis and statistical analysis to experimental system information, can carry out demonstration and the statistical configuration to relevant information according to the experimental change simultaneously, help the experimenter to carry out the statistical analysis of data and the inquiry analysis of unusual problem, alleviate the work load of experimenter, improve the work rate, provide the detailing for the experimenter simultaneously, accurate experimental data, guarantee the historical authenticity of data.

Drawings

FIG. 1 is a schematic diagram of a system data management system according to the present invention;

FIG. 2 is an internal connection diagram of a data management PC in the system data management system of the present invention;

fig. 3 is a flowchart of a management method to which the system data management system of the present invention is applied.

Wherein:

1 laser device 2 Power supply device

3 vacuum equipment 4 optical cavity equipment

Serial bus No. 5I and serial bus No. 6 II

7 Ethernet bus 8 laser equipment monitoring device

9 power supply equipment monitoring device 10 vacuum equipment monitoring device

11 centralized data acquisition system of optical cavity equipment monitoring device 12

13 data management system 14 TCP/IP communication

15 data reading module 16 human-computer interaction display module

17 data storage module 18 data query analysis module

19 report statistical module of experimental process management module 20

21 device monitoring data 22 parameter setting data

Query analysis data 23 condition change data 24

Report data 26 experimental set data is reported 25.

For a person skilled in the art, other relevant figures can be obtained from the above figures without inventive effort.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the following description is provided with reference to the accompanying drawings and by way of specific embodiments to further explain the technical solution of the system data management system of the present invention.

As shown in fig. 1, a system data management system includes a plurality of laser devices 1, a power supply device 2, a vacuum device 3, and an optical cavity device 4, where the laser device 1 is connected to a laser device monitoring apparatus 8 through a serial bus i 5, and the power supply device 2, the vacuum device 3, and the optical cavity device 4 are respectively connected to a power supply device monitoring apparatus 9, a vacuum device monitoring apparatus 10, and an optical cavity device monitoring apparatus 11 through a serial bus ii 6; the laser equipment monitoring device 8, the equipment monitoring device 9, the vacuum equipment monitoring device 10 and the optical cavity equipment monitoring device 11 are respectively connected with a data centralized acquisition system 12 through an Ethernet bus 7, and the data centralized acquisition system 12 realizes data transmission with a data management system 13 through TCP/IP communication 14.

The laser equipment monitoring device 8 collects all monitoring data of the laser equipment 1 in real time through a serial bus I5, and the power supply equipment monitoring device 9, the vacuum equipment monitoring device 10 and the optical cavity equipment monitoring device 11 respectively collect monitoring data of the power supply equipment 2, the vacuum equipment 3 and the optical cavity equipment 4 in real time through a serial bus II 6; the data management system 13 (PC) acquires all the monitoring data of the centralized data acquisition system 12 (PC) through TCP/IP communication 14, that is, acquires all the monitoring data of the dedicated system in real time, and performs effective management.

The laser device monitoring apparatus is disclosed in my patent application nos. 201210485447.3, 201210485690.5.

The power supply equipment monitoring device is disclosed in my patent application nos. 200820139534.2, 201820963197.2.

The vacuum equipment monitoring device is disclosed in my patent application No. 201520730183.2.

The optical cavity equipment monitoring device is disclosed by the patent with the application number of 201720309640 in our hospital.

As shown in fig. 2, the data management system 13 includes:

the data reading module 15 reads the device monitoring data 21 in real time;

a human-computer interaction display module 16, which is used for setting parameters and inputting experimental condition data;

the data storage module 17 is used for storing the data read by the data reading module 15 into the equipment monitoring data 21, the parameter setting data 22 set by the human-computer interaction display module 16 and the condition change data 24 in real time;

a data query analysis module 18 for displaying and outputting the parameter graph after acquiring the query analysis data 23 from the data storage module 17;

an experiment process management module 19 that displays experiment setting data 26;

and the report statistics module 20 acquires the report data 25 from the data storage module 17 to generate a corresponding data analysis report and a corresponding statistical report.

The parameters managed by the data management system 13 include device monitoring data 21, parameter setting data 22, query analysis data 23, condition change data 24, report data 25, and experiment setting data 26. The device monitoring data 21 are all the device monitoring data collected by the laser device monitoring apparatus 8, the device monitoring apparatus 9, the vacuum device monitoring apparatus 10 and the optical cavity device monitoring apparatus 11.

The order of data management in the experiment was:

and after the data reading module 15 reads the device monitoring data 21 in real time, the device monitoring data 21 is stored in real time through the data storage module 17.

Before the experiment is started, parameter setting is carried out through the human-computer interaction display 16 module, and then parameter setting data 22 are stored in the data storage 17 module.

After the experiment is started, the experiment condition data is inputted through the man-machine interface 16, the experiment setting data 26 is displayed in the experiment process management 19, and the condition change data 24 is stored in the data storage 17.

After the experiment is finished, the data query analysis 18 acquires query analysis data 23 from the data storage 17 and then displays and outputs parameter graphs, and the report statistics 20 acquires report data 25 from the data storage 17 to generate corresponding data analysis reports and statistical reports.

The utility model discloses the theory of operation of device:

the laser equipment monitoring device 8, the equipment monitoring device 9, the vacuum equipment monitoring device 10 and the optical cavity equipment monitoring device 11 control and monitor a plurality of field equipment through a serial bus, wherein the field equipment comprises a laser device 1, a power supply device 2, a vacuum device 3 and an optical cavity equipment 4 monitoring point, the centralized data collector 12 collects all the device monitoring data 21 of all the device monitoring devices on site simultaneously through the Ethernet bus 7, the data management machine 13 reads all the device monitoring data 21 transmitted by the centralized data collector 12 through a TCP/IP interface protocol, displays key important information in real time, stores all the parameter data in real time, records experiment regulation change information generated in the experiment process, automatically compares and stores the key parameter data before and after the regulation information, automatically generates experiment summary reports and report information for each experiment, and provides historical query analysis of all the data.

As shown in fig. 3, the management method of the system data management system according to the present invention includes the following steps:

(I) establishment of System data management System

Establishing a system field device monitoring device;

(ii) establishing a system data centralized acquisition system;

(iii) establishing a data storage structure and creating a database;

(iv) analyzing the system data flow and establishing a data management model;

(v) designing a human-computer interface, and establishing a human-computer interaction picture;

(vi) analyzing the data relationship of the field devices of the system, and establishing a data query module;

(vii) the experimental results of the analysis system apply the data form and statistical information to establish reports, statements and statistical information modules.

(II) execution of System data management System

Starting (i)

(ii) parameter setting

Setting parameters of system experimental equipment and parameters of an acquisition system;

the system experimental equipment comprises laser equipment 1, power supply equipment 2, vacuum equipment 3 and optical cavity equipment 4;

(iii) data acquisition

Starting a data driving instruction, starting to read monitoring data of the laser equipment monitoring device 8, the equipment monitoring device 9, the vacuum equipment monitoring device 10 and the optical cavity equipment monitoring device 11, and storing corresponding data values when the data change;

(iv) storing

When the data is changed, storing the parameter setting data of the step (ii) and the corresponding data value of the monitoring data collected in the step (iii);

(v) Experimental State

Judging the current experiment state, and if the current experiment state is in the experiment, executing the step (vi); (xiii) if after the experiment, performing step (xiii) or step (xiii);

(vi) display of Key parameters

Displaying all key parameter data in real time;

(vii) real-time storage

Storing the optimal values of the key parameters in real time;

(viii) Condition Change

Monitoring whether the experimental conditions are changed in the experimental process in real time, and if the conditions are not changed, displaying and storing key parameters in real time all the time; if a condition change occurs, performing step (ix);

(ix) capturing data;

when the conditions are changed, capturing key parameters before and after the experiment conditions are changed;

(x) input variation conditions

Executing input change conditions and recording the change conditions;

(xi) Storing capture data

Storing the captured data of step (ix);

(xii) Data query

After the experiment is finished, inquiring historical parameter data;

the data query comprises multi-parameter query and experimental process query;

acquiring a change curve of any parameter in a certain period through multi-parameter query;

and inquiring and acquiring key parameters and change condition data in the experimental process through the experimental process.

(xiii) Data computation

Completing corresponding calculation parameters through data calculation;

the data calculation comprises report generation and data statistics;

generating and selecting a certain experiment number through a report, generating an experiment report of the time, and selecting configuration conditions to generate a report;

and selecting a plurality of experiment numbers through data statistics, comparing main parameters of the plurality of experiments, and generating a comparison report.

(xiv) Data export

Exporting the data acquired in the step (xii) or the step (xiii), wherein the exported report or statistical report can be exported in an EXCEL table form;

(xv) End up

When the experiment is over and there are no query or computation tasks, execution is over and the process is over.

The utility model discloses a working process does:

after a management system runs and monitoring devices of all field devices are started, a data centralized acquisition system and a data management system are started firstly, a program is executed, relevant parameters such as acquisition and the like are set through parameters, data acquisition is started, data storage is carried out, after an experiment is started, all key parameter data are displayed in real time through key parameter display during the experiment, the key parameters are stored in real time, if the condition changes, the key parameters before and after the condition changes are grabbed through grabbing data, then the input of the changed condition is executed, the changed condition is recorded, the grabbing data are stored at the same time, and if the condition does not change, the key parameters are displayed and stored all the time; after the experiment is finished, after the experiment, multi-parameter query can be carried out through data query to display a change curve of any parameter in a certain time period, key parameter and change condition data in the experiment process can also be queried and analyzed through the experiment process query, corresponding calculation parameters are completed through data calculation, then an experiment report is generated through a report form to generate experiment report data of a certain time, or multiple times of experiment key data are selected through data statistics to carry out comprehensive comparison, finally the generated report or the generated statistical report can be exported through an EXCEL table form through data export, and when the experiment is finished and a query task does not exist, the program can be executed to be finished.

The utility model provides a pair of system data management system and method, adopt the database technology, the modularization programming technique, the real-time communication technique, real-time multitask technique and data statistics computing technology, the management and the analysis to special system device data and information data have been realized, the data management and the analytic method of managing special system are provided for the experiment person in charge, can provide a data support for special system's steady operation, the person in charge provides a historical data trend of change for equipment development, true data support is provided for the analytical equipment stability, reliability design for supervisory equipment provides data support and improvement method. The utility model discloses have characteristics such as stability is strong, strong adaptability and expansibility are strong, satisfy the application in many fields.

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

The applicant states that the above description is only a specific embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and those skilled in the art should understand that any changes or substitutions easily conceivable by those skilled in the art within the technical scope of the present invention are within the protection scope and the disclosure scope of the present invention.

Claims (4)

1. The system data management system comprises a plurality of laser devices (1), a power supply device (2), a vacuum device (3) and an optical cavity device (4), and is characterized in that: the laser equipment (1) is connected with a laser equipment monitoring device (8) through a serial bus I (5), and the power supply equipment (2), the vacuum equipment (3) and the optical cavity equipment (4) are respectively connected with a power supply equipment monitoring device (9), a vacuum equipment monitoring device (10) and an optical cavity equipment monitoring device (11) through a serial bus II (6); the laser equipment monitoring device (8), the equipment monitoring device (9), the vacuum equipment monitoring device (10) and the optical cavity equipment monitoring device (11) are respectively connected with a data centralized acquisition system (12) through an Ethernet bus (7), and the data centralized acquisition system (12) is in data transmission with a data management system (13) through TCP/IP communication (14).

2. The system data management system according to claim 1, characterized in that: the data management system (13) comprises:

the data reading module (15) reads equipment monitoring data (21) in real time;

the human-computer interaction display module (16) is used for setting parameters and inputting experimental condition data;

the data storage module (17) is used for reading the data reading module (15) into equipment monitoring data (21), parameter setting data (22) set by the man-machine interaction display module (16) and condition change data (24) and storing the data in real time;

a data query analysis module (18) which displays and outputs the parameter graph after acquiring query analysis data (23) from the data storage module (17);

an experiment process management module (19) for displaying experiment setting data (26);

and the report counting module (20) acquires report data (25) from the data storage module (17) to generate a corresponding data analysis report and a corresponding statistical report.

3. The system data management system according to claim 1, characterized in that: a plurality of laser devices (1) are arranged in parallel; a plurality of power supply devices (2) are arranged in parallel; a plurality of vacuum devices (3) are arranged in parallel; the plurality of optical cavity devices (4) are arranged in parallel.

4. The system data management system according to claim 1, characterized in that: the data centralized acquisition system (12) and the data management system (13) are both PC machines.

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