CN116233097A - Industrial configuration station building method based on WEB and industrial configuration system thereof - Google Patents

Abstract

The invention discloses a WEB-based industrial configuration station building method, which comprises the following steps of S1, confirming functional requirements, analyzing the functional requirements and obtaining engineering related data; s2, engineering page design; s3, simplifying the design, and enabling the system to customize a plurality of grammar sugars in order to reduce the difficulty of script writing of users and simplify the script quantity required to be written; s4, engineering configuration; s5, compiling and publishing engineering; s6, real-time data communication, compared with the prior art, the method and the device for establishing the secure communication connection by using the Websocket communication protocol, and ensure the real-time performance and the reliability of data; by adopting grammar sugar, the compiling process is simplified; the data acquisition center is used for actively acquiring and actively reporting the equipment layer, and the user side is not required to send a data refreshing instruction to the server at regular time.

Description

Industrial configuration station building method based on WEB and industrial configuration system thereof

Technical Field

The invention relates to the field of webpage construction, in particular to an industrial configuration station building method based on WEB and an industrial configuration system thereof.

Background

At present, in the industrial control field, the conventional configuration software based on the C/S architecture is most widely used, however, there are many disadvantages in this architecture: can only be accessed by single machine deployment, occupies large space resources, cannot adapt to resolution ratio and the like.

Disclosure of Invention

In order to solve the defects of the prior art, the invention aims to provide a WEB-based industrial configuration station building method and an industrial configuration system for realizing data real-time refreshing by using a full-duplex WebSocket communication protocol.

In order to achieve the above object, the present invention adopts the following technical scheme:

the industrial configuration station building method based on the WEB is characterized by comprising the following specific steps of: s1, confirming functional requirements, analyzing the functional requirements and acquiring engineering related data; s2, engineering page design; s3, simplifying the design, and enabling the system to customize a plurality of grammar sugars in order to reduce the difficulty of script writing of users and simplify the script quantity required to be written; s4, engineering configuration; s5, compiling and publishing engineering; s6, real-time data communication.

As a further preferred aspect of the present invention, in the step S2, the engineering page design includes the following specific steps: s2.1, engineering creation: determining the name of the project, the color of the project theme and a functional module according to the requirements of the user; s2.2, page setting: creating a page, drawing page elements through canvas, and setting basic attributes and animation attributes of the page elements; s2.3, page interaction binding: including data source binding and user interaction event binding.

As a further preferred aspect of the present invention, in the step S2.3, the data source binding procedure specifically includes the steps of: s2.3.1.1, selecting a control of a data source to be bound; s2.3.1.2, judging whether the number of the equipment to which the control belongs is known; s2.3.1.3, if not, selecting a building or unit; s2.3.1.4, selecting a device; s2.3.1.4, generating a device unique number; s2.3.1.6, if known, manually inputting the equipment number; s2.3.1.7 selecting parameters to be bound, wherein the parameters comprise current, voltage, active power, reactive power, apparent power, current average harmonic, current harmonic, voltage average harmonic, voltage harmonic, frequency, total power factor, current rheology ratio, active total power, last day power, last month power, last year power, switch-on/off, status point, cable temperature, set temperature, indoor temperature, humidity, illuminance and total water; s2.3.1.8, according to the user's requirement, writing the action script executed after the data change, if not, not writing.

As a further preferred aspect of the present invention, in the step S2.3, the user interaction event binding procedure specifically includes the following steps: s2.3.2.1 selecting a control to be bound for an event; s2.3.2.2, selecting an event type; the event types comprise left mouse button clicking, left mouse button double clicking, control content changing, mouse pressing, mouse loosening, mouse suspending, mouse moving away and keyboard returning; s2.3.2.3, the system generates necessary event scripts; s2.3.2.4, writing script content by a user; s2.3.2.5, checking a script; s2.3.2.6, if failed, repeat S2.3.2.4; s2.3.2.7, ending if successful.

As a further preferred aspect of the present invention, the grammatical sugar comprises:

< U > represents the real-time voltage value of the currently bound device (U is the device parameter number);

< a1_1.U > represents the real-time voltage value of the device a1_1 (a1_1 is the device number);

the < @ represents a jquery object of the current control;

the < @U > represents a node with the device parameter type set as U under the current control;

< @ p1 > represents the jquery object of the control of id=p1;

the < @p1.U > represents a node with a device parameter type U under a control of id=p1;

representing the device number of the current binding;

* Bind, representing that all text nodes under the current control bind real-time data values automatically. The user can use the grammar sugar to replace the original complicated script, thereby reducing the page design difficulty and improving the page design efficiency.

As a further preferred aspect of the present invention, the engineering configuration includes engineering logo, engineering operation menu, menu icon, page for configuring default access and data center access address, i.e. address of data server connected after engineering release operation.

As a further preferred aspect of the present invention, the engineering compilation issues: after the engineering page design is completed, the system compiles page elements drawn by a user through visual operation and written scripts into elements which can be identified by a browser, packages all necessary files of the engineering and distributes the necessary files to a web server.

As a further preferred aspect of the present invention, the real-time data communication includes a real-time data communication framework, the real-time data communication framework includes a user side, a server, a data acquisition center, a data persistence layer and a device layer, the user side includes a plurality of clients, the clients include a WEB configuration operation interface, the user side sends login and heartbeat package instructions to the server, and the server pushes the real-time data to the user side; the data persistence layer carries out persistence storage on service data and provides a data query interface for a user side and a server; the data center comprises OpenLNS, MQTT, OPCUA, GPRS and others, the data collection center performs active collection to the equipment layer, the equipment layer performs active report to the data collection center, the latest data can be actively pushed to the user side after the equipment layer data collected by the data collection center changes, the user side does not need to send a data refreshing instruction to the server at regular time, the second-level refreshing of the user side data can be realized, and the data collection center stores the data to the data persistence layer.

As a further preferred embodiment of the present invention, the server uses a WebSocket communication protocol of full duplex.

An industrial configuration system employing any of the WEB-based industrial configuration website building methods of claims 1-5, wherein the industrial configuration system comprises an industrial page design, a WEB server, and a database server, the industrial configuration page design comprising an SVG canvas, a control library, a template library, a script editor, and an engineering configuration module, the SVG canvas, the control library, the template library being for page rendering, attribute setting, and animation setting; when the page design is carried out, SVG element labels are mainly used for realizing, the script editor is used for binding user events, the engineering configuration module is used for integrating data of page drawing, attribute setting, animation setting and user event binding to form engineering menus and graphic configuration, after the engineering page design is completed, compiling is carried out and the engineering page design is distributed to a web server, the web server comprises a nginx agency and an IIS middleware, and data transmission is carried out between the database server and the engineering page design and between the database server and the web server respectively.

The invention has the advantages that: the invention uses the WebSocket communication protocol to establish the secure communication connection, thereby ensuring the real-time performance and reliability of the data; by adopting grammar sugar, the compiling process is simplified; the data acquisition center is used for actively acquiring and actively reporting the equipment layer, and a user side is not required to send a data refreshing instruction to the server at regular time; SVG graphics are adopted, and the SVG graphics are independent of resolution of a screen, support for various graphic elements, support for scripts and CSS, support for user interaction and the like.

Drawings

FIG. 1 is a topology of an industrial configuration system of the present invention;

FIG. 2 is a data source binding flow diagram;

FIG. 3 is a user interaction event binding flow diagram;

fig. 4 is a diagram of a real-time data communication architecture.

Detailed Description

The invention is described in detail below with reference to the drawings and the specific embodiments.

Example 1:

referring to fig. 1, the industrial configuration system comprises an industrial page design, a web server and a database server, wherein the industrial configuration page design comprises an SVG canvas, a control library, a template library, a script editor and an engineering configuration module, and the SVG canvas, the control library and the template library are used for carrying out page drawing, attribute setting and animation setting; when the page design is carried out, SVG element labels are mainly used for realizing, the script editor is used for binding user events, the engineering configuration module is used for integrating data of page drawing, attribute setting, animation setting and user event binding to form engineering menus and graphic configuration, after the engineering page design is completed, compiling is carried out and the engineering page design is distributed to a web server, the web server comprises a nginx agency and an IIS middleware, and data transmission is carried out between the database server and the engineering page design and between the database server and the web server respectively.

Embodiment two:

the industrial configuration station building method based on the WEB is characterized by comprising the following specific steps of:

s1, confirming function requirements, analyzing the function requirements, and acquiring engineering related data.

S2, engineering page design.

The engineering page design comprises the following specific steps:

s2.1, engineering creation: determining the name of the project, the color of the project theme and a functional module according to the requirements of the user;

s2.2, page setting: and creating a page, drawing page elements through canvas, and setting basic attributes and animation attributes of the page elements.

S2.3, page interaction binding: including data source binding and user interaction event binding.

The binding procedure of the data source specifically comprises the following steps in combination with fig. 2:

s2.3.1.1, selecting a control of a data source to be bound;

s2.3.1.2, judging whether the number of the equipment to which the control belongs is known;

s2.3.1.3, if not, selecting a building or unit;

s2.3.1.4, selecting a device;

s2.3.1.4, generating a device unique number;

s2.3.1.6, if known, manually inputting the equipment number;

s2.3.1.7 selecting parameters to be bound, wherein the parameters comprise current, voltage, active power, reactive power, apparent power, current average harmonic, current harmonic, voltage average harmonic, voltage harmonic, frequency, total power factor, current rheology ratio, active total power, last day power, last month power, last year power, switch-on/off, status point, cable temperature, set temperature, indoor temperature, humidity, illuminance and total water;

s2.3.1.8, according to the user's requirement, writing the action script executed after the data change, if not, not writing.

The binding procedure of the user interaction event specifically comprises the following steps in combination with fig. 3:

s2.3.2.1 selecting a control to be bound for an event;

s2.3.2.2, selecting an event type; the event types comprise left mouse button clicking, left mouse button double clicking, control content changing, mouse pressing, mouse loosening, mouse suspending, mouse moving away and keyboard returning;

s2.3.2.3, the system generates necessary event scripts;

s2.3.2.4, writing script content by a user;

s2.3.2.5, checking a script;

s2.3.2.6, if failed, repeat S2.3.2.4;

s2.3.2.7, ending if successful.

S3, simplifying the design, and enabling the system to customize a plurality of grammar sugars in order to reduce the difficulty of script writing of users and simplify the script quantity required to be written.

The grammatical sugar comprises:

< U > represents the real-time voltage value of the currently bound device (U is the device parameter number);

< a1_1.U > represents the real-time voltage value of the device a1_1 (a1_1 is the device number);

the < @ represents a jquery object of the current control;

the < @U > represents a node with the device parameter type set as U under the current control;

< @ p1 > represents the jquery object of the control of id=p1;

the < @p1.U > represents a node with a device parameter type U under a control of id=p1;

representing the device number of the current binding;

* Bind, representing that all text nodes under the current control bind real-time data values automatically. The user can use the grammar sugar to replace the original complicated script, thereby reducing the page design difficulty and improving the page design efficiency.

S4, engineering configuration.

The engineering configuration comprises engineering logo, engineering operation menu, menu icon, page for configuring default access and data center access address, namely the address of a data server connected after engineering release operation.

S5, compiling and publishing engineering.

Engineering compiling and publishing: after the engineering page design is completed, the system compiles page elements drawn by a user through visual operation and written scripts into elements which can be identified by a browser, packages all necessary files of the engineering and distributes the necessary files to a web server.

S6, real-time data communication.

Referring to fig. 4, the real-time data communication includes a real-time data communication framework, the real-time data communication framework includes a user side, a server, a data acquisition center, a data persistence layer and a device layer, the user side includes a plurality of clients, the clients include a WEB configuration operation interface, the user side sends login and heartbeat package instructions to the server, and the server pushes the real-time data to the user side; the data persistence layer carries out persistence storage on service data and provides a data query interface for a user side and a server; the data center comprises OpenLNS, MQTT, OPCUA, GPRS and others, the data collection center performs active collection to the equipment layer, the equipment layer performs active report to the data collection center, the latest data can be actively pushed to the user side after the equipment layer data collected by the data collection center changes, the user side does not need to send a data refreshing instruction to the server at regular time, the second-level refreshing of the user side data can be realized, and the data collection center stores the data to the data persistence layer.

The server adopts a full duplex WebSocket communication protocol.

The invention has the advantages that: the invention uses the WebSocket communication protocol to establish the secure communication connection, thereby ensuring the real-time performance and reliability of the data; by adopting grammar sugar, the compiling process is simplified; the data acquisition center is used for actively acquiring and actively reporting the equipment layer, and a user side is not required to send a data refreshing instruction to the server at regular time; SVG graphics are adopted, and the SVG graphics are independent of resolution of a screen, support for various graphic elements, support for scripts and CSS, support for user interaction and the like.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be appreciated by persons skilled in the art that the above embodiments are not intended to limit the invention in any way, and that all technical solutions obtained by means of equivalent substitutions or equivalent transformations fall within the scope of the invention.

Claims (10)

1. The industrial configuration station building method based on the WEB is characterized by comprising the following specific steps of: s1, confirming functional requirements, analyzing the functional requirements and acquiring engineering related data; s2, engineering page design; s3, simplifying the design, and enabling the system to customize a plurality of grammar sugars in order to reduce the difficulty of script writing of users and simplify the script quantity required to be written; s4, engineering configuration; s5, compiling and publishing engineering; s6, real-time data communication.

2. The WEB-based industrial configuration website building method according to claim 1, wherein in the step S2, the engineering page design comprises the following specific steps: s2.1, engineering creation: determining the name of the project, the color of the project theme and a functional module according to the requirements of the user; s2.2, page setting: creating a page, drawing page elements through canvas, and setting basic attributes and animation attributes of the page elements; s2.3, page interaction binding: including data source binding and user interaction event binding.

3. The WEB-based industrial configuration website building method according to claim 1, wherein in step S2.3, the data source binding procedure specifically comprises the following steps: s2.3.1.1, selecting a control of a data source to be bound; s2.3.1.2, judging whether the number of the equipment to which the control belongs is known; s2.3.1.3, if not, selecting a building or unit; s2.3.1.4, selecting a device; s2.3.1.4, generating a device unique number; s2.3.1.6, if known, manually inputting the equipment number; s2.3.1.7 selecting parameters to be bound, wherein the parameters comprise current, voltage, active power, reactive power, apparent power, current average harmonic, current harmonic, voltage average harmonic, voltage harmonic, frequency, total power factor, current rheology ratio, active total power, last day power, last month power, last year power, switch-on/off, status point, cable temperature, set temperature, indoor temperature, humidity, illuminance and total water; s2.3.1.8, according to the user's requirement, writing the action script executed after the data change, if not, not writing.

4. The WEB-based industrial configuration website building method according to claim 1, wherein in the step S2.3, the user interaction event binding procedure specifically comprises the following steps: s2.3.2.1 selecting a control to be bound for an event; s2.3.2.2, selecting an event type; the event types comprise left mouse button clicking, left mouse button double clicking, control content changing, mouse pressing, mouse loosening, mouse suspending, mouse moving away and keyboard returning; s2.3.2.3, the system generates necessary event scripts; s2.3.2.4, writing script content by a user; s2.3.2.5, checking a script; s2.3.2.6, if failed, repeat S2.3.2.4; s2.3.2.7, ending if successful.

5. The WEB-based industrial configuration website building method of claim 1, wherein the grammatical sugar comprises:

< U > represents the real-time voltage value of the currently bound device (U is the device parameter number);

< a1_1.U > represents the real-time voltage value of the device a1_1 (a1_1 is the device number);

the < @ represents a jquery object of the current control;

the < @U > represents a node with the device parameter type set as U under the current control;

< @ p1 > represents the jquery object of the control of id=p1;

the < @p1.U > represents a node with a device parameter type U under a control of id=p1;

representing the device number of the current binding;

* Bind, representing that all text nodes under the current control bind real-time data values automatically.

6. The WEB-based industrial configuration website building method according to claim 1, wherein the engineering configuration comprises engineering logo, engineering operation menu, menu icon, page for configuring default access and data center access address, namely address of a data server connected after engineering release operation.

7. The WEB-based industrial configuration website building method according to claim 1, wherein the engineering compiling and publishing: after the engineering page design is completed, the system compiles page elements drawn by a user through visual operation and written scripts into elements which can be identified by a browser, packages all necessary files of the engineering and distributes the necessary files to a web server.

8. The WEB-based industrial configuration website building method according to claim 1, wherein the real-time data communication comprises a real-time data communication framework, the real-time data communication framework comprises a user side, a server, a data acquisition center, a data persistence layer and a device layer, the user side comprises a plurality of clients, the clients comprise a WEB configuration operation interface, the user side sends login and heartbeat package instructions to the server, and the server pushes real-time data to the user side; the data persistence layer carries out persistence storage on service data and provides a data query interface for a user side and a server; the data acquisition center performs active acquisition to the equipment layer, the equipment layer performs active reporting to the data acquisition center, the data acquisition center stores data to the data persistence layer, the data persistence layer performs persistence storage to service data, and a data query interface is provided for a user side and a server.

9. The WEB-based industrial configuration website building method of claim 8, wherein the server employs a full duplex WebSocket communication protocol.

10. An industrial configuration system employing any of the WEB-based industrial configuration website building methods of claims 1-9, wherein the industrial configuration system comprises an industrial page design, a WEB server, and a database server, the industrial configuration page design comprising an SVG canvas, a control library, a template library, a script editor, and an engineering configuration module, the SVG canvas, the control library, the template library being for page rendering, attribute setting, and animation setting; the script editor is used for binding user events, the engineering configuration module is used for integrating data of page drawing, attribute setting, animation setting and user event binding to form engineering menus and graphic configuration, after engineering page design is completed, compiling is carried out, the engineering page is distributed to the web server, the web server comprises a nginx proxy and an IIS middleware, and data transmission is carried out among the database server, the engineering page design and the web server respectively.

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