CN110222403B - Electrical design system and method based on application scene - Google Patents

Abstract

The invention belongs to the field of industrial automation and the field of electric power systems such as buildings, and particularly relates to an electric design system and method based on an application scene. In order to solve the problems that the traditional electrical design has no unified standard and the drawing efficiency is low, the electrical design system comprises: the database is used for providing a model of a scene to be applied and a component matched with the scene to be applied; the input unit is used for inputting design parameters under the condition that the scene to be applied and the component matched with the scene to be applied are selected; and the processing unit is used for generating an electrical schematic diagram according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters. The invention shortens the time of electrical design, accelerates the working efficiency of electrical design, ensures the rationality of electrical design, standardizes the electrical design mode and reduces the error probability of electrical design.

Description

Electrical design system and method based on application scene

Technical Field

The invention belongs to the field of industrial automation and the field of electric power systems such as buildings, and particularly relates to an electric design system and method based on an application scene.

Background

The traditional electrical design industry is all based on drawing directly, utilizes the instrument to carry out the drawing of schematic diagram by electrical design engineer (electrical engineer when receiving the project, will make design scheme, comb design thought earlier, then with the help of special drawing software, draw the design thought into the drawing with one stroke), and each major hardware manufacturer also only provides respective primitive, makes things convenient for the engineer to use. Each large manufacturer only subdivides the brand, and specific parameters are set respectively, so that the uniform classification processing cannot be realized. When using each component, the electrical engineer needs to comprehensively know the component and then can use the component, and the specific scene in which the component is used is also determined by the engineer according to the field situation. There is no systematic scene classification and parameter planning.

The present invention has been made in view of the above circumstances.

Disclosure of Invention

In order to solve the above problems in the prior art, that is, to solve the problems that the conventional electrical design has no unified standard and the drawing efficiency is low, the present invention provides an electrical design system based on an application scenario, where the electrical design system includes: the database is used for providing a model of a scene to be applied and a component matched with the scene to be applied; the input unit is used for inputting design parameters under the condition that the scene to be applied and the component matched with the scene to be applied are selected; and the processing unit is used for generating an electrical schematic diagram according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters.

In a preferred embodiment of the above application scenario-based electrical design system, the electrical design system further includes a display unit, and the display unit is configured to display the electrical schematic diagram generated by the processing unit.

In a preferred embodiment of the above application scenario-based electrical design system, the electrical design system further includes a drawing parameter setting unit, and the drawing parameter setting unit is configured to input drawing parameters to adjust the electrical schematic diagram after the electrical schematic diagram is generated.

In a preferred embodiment of the above application scenario-based electrical design system, the processing unit includes: the first submodule is used for forming a parameterized application scene according to the model of the scene to be applied, the components matched with the scene to be applied and input design parameters; a second submodule for forming structured design data from the parameterized application scenario; a third sub-module for operating on the structured design data; and the fourth submodule is used for calculating the operation result of the third submodule and generating electrical schematic data.

In a preferred embodiment of the above electrical design system based on the application scenario, the processing unit is located in a cloud server or in a local server.

The invention also provides an electrical design method based on the application scene, which comprises the following steps: s110, providing a model of a scene to be applied and a component matched with the scene to be applied; s120, inputting design parameters; and S130, generating an electrical schematic diagram according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters.

In a preferred embodiment of the above electrical design method based on application scenarios, the electrical design method further includes: and S140, displaying the generated electrical schematic diagram at the user side.

In a preferred embodiment of the above electrical design method based on application scenarios, the electrical design method further includes: and S150, inputting drawing parameters to adjust the electrical schematic diagram.

In a preferred embodiment of the electrical design method based on the application scenario, step S130 specifically includes: forming a parameterized application scene according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters; forming structured design data according to the parameterized application scenarios; operating on the structured design data; and calculating the operation result and generating electrical schematic diagram data.

In the preferred embodiment of the electrical design method based on the application scene, the model of the scene to be applied and the component matched with the scene to be applied are pre-established.

Compared with the traditional drawing method of the electrical schematic diagram (namely, compared with the traditional drawing method of the electrical schematic diagram, the method combines the electrical element library and the electrical image library and then draws manually), the method selects the application scene of the electrical equipment and configures necessary parameters in the application scene, and then uploads the parameters to the server for calculation and then returns to the user side for direct display, so that the process of drawing a little by the existing software is omitted. The time of electrical design is further shortened, the working efficiency of electrical design is greatly accelerated, the rationality of electrical design is ensured, the electrical design mode is standardized, and the error probability of electrical design is reduced.

Drawings

FIG. 1 is a schematic diagram of an electrical design system based on an application scenario;

FIG. 2 is a schematic structural diagram of one embodiment of the present invention;

FIG. 3 is a main flow chart of the electrical design method based on application scenarios of the present invention.

Detailed Description

In order to make the embodiments, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the embodiments are some, but not all embodiments of the present invention. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention.

Referring first to fig. 1, fig. 1 is a schematic structural diagram of an electrical design system based on an application scenario of the present invention. As shown in fig. 1, the electrical design system of the present invention mainly includes a database 1, an input unit 2, and a processing unit 3. The database 1 is used for providing a model of a scene to be applied and a component matched with the scene to be applied, specifically, the database 1 stores pre-established models of different application scenes, and the component can be an existing component of various brands and models and is used for establishing different application scene models. As an example, when a user needs to create a new project, a needed application scene model may be selected from the database, then a needed component in the application scene is selected (a proper brand and model is selected), and in a case where a to-be-applied scene and a component matched with the to-be-applied scene are selected, the user may input design parameters through the input unit 2; the processing unit generates an electrical schematic diagram (specifically, data for generating the electrical schematic diagram) according to the model of the scene to be applied, the component matched with the scene to be applied and the input design parameters. Therefore, the user only needs to select the application scene model in the database 1 to combine the components, modify the requirement details by modifying the inherent parameters, and directly give the final graph by the processing unit. And the intelligent calculation replaces manual drawing, so that the drawing accuracy is ensured.

Further, the electrical design system of the present invention further comprises a display unit for displaying the electrical schematic diagram generated by the processing unit to a user.

In a specific embodiment, the processing unit comprises four sub-modules. Referring to fig. 2, fig. 2 is a schematic structural diagram of an embodiment of the present invention. As shown in fig. 2, after the input unit 2 inputs design parameters, first, the first submodule 31 of the processing unit 3 forms a parameterized application scenario according to the model of the scenario to be applied, the components matched with the scenario to be applied, and the input design parameters; the second submodule 32 then forms the structured design data from the parameterized application scenario; and the third submodule 33 performs calculation on the structured design data (i.e. performs correlation analysis on the design calculation and the data), and finally, the fourth submodule 34 performs calculation on the calculation result of the third submodule 33 to generate electrical schematic data. It should be noted that the algorithm involved in each sub-module of the processing unit 3 may be selected by a person skilled in the art flexibly, and the specific algorithm is not limited herein. For example, the fourth sub-module 34 may be mapped using an electrical schematic algorithm, which may be selected from any suitable algorithm.

Preferably, the electrical design system of the present invention further includes a drawing parameter setting unit for inputting drawing parameters to adjust the electrical schematic after the electrical schematic is generated. As shown in fig. 2, after the electrical schematic is generated, drawing parameters may be set, which further standardizes the generated electrical schematic.

The processing unit 3 may be located in a local server or a cloud server. In a more specific embodiment, when the processing unit 3 is located in a cloud server, after a user inputs design parameters, the generated parameterized application scenario is uploaded to the server, and then the server performs operations and returns the finally generated electrical schematic diagram to the user side for display.

Compared with the traditional drawing method of the electrical schematic diagram (namely, compared with the traditional drawing method of the electrical schematic diagram, the method combines the electrical element library and the electrical image library and then draws manually), the method selects the application scene of the electrical equipment and configures necessary parameters in the application scene, and then uploads the parameters to the server for calculation and then returns to the user side for direct display, so that the process of drawing a little by the existing software is omitted. The time of electrical design is further shortened, the working efficiency of electrical design is greatly accelerated, the rationality of electrical design is ensured, the electrical design mode is standardized, and the error probability of electrical design is reduced.

The invention also provides an electrical design method based on the application scene. Referring to fig. 3, fig. 3 is a main flowchart of the electrical design method based on application scenarios of the present invention. As shown in fig. 3, the electrical design method of the present invention includes the following steps: s110, providing a model of a scene to be applied and a component matched with the scene to be applied; s120, inputting design parameters; and S130, generating an electrical schematic diagram according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters. Step S130 specifically includes: forming a parameterized application scene according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters; forming structured design data from the parameterized application scenarios; performing operation on the structured design data; and calculating the operation result and generating electrical schematic data. Further, after step S130, the electrical design method further includes a step of displaying the generated electrical schematic diagram on the user side and inputting drawing parameters to adjust the electrical schematic diagram, which is specifically referred to above and is not described herein again. In addition, in step S110, the model of the scene to be applied and the component matched with the scene to be applied are pre-established.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.

Claims (8)

1. An electrical design system based on an application scenario, the electrical design system comprising:

the database is used for providing a model of a scene to be applied and a component matched with the scene to be applied; the database stores pre-established models of different application scenes, and the components are the existing components of various brands and models and are used for establishing different application scene models;

the input unit inputs design parameters under the condition that the scene to be applied and the component matched with the scene to be applied are selected;

the processing unit is used for generating an electrical schematic diagram according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters; the processing unit includes: the first submodule is used for forming a parameterized application scene according to the model of the scene to be applied, the components matched with the scene to be applied and input design parameters; a second submodule for forming structured design data from the parameterized application scenario; a third sub-module for performing operations on the structured design data to perform correlation analysis on the design calculations and the data; the fourth submodule is used for calculating the operation result of the third submodule and generating electrical schematic data;

the drawing parameter setting unit is used for inputting drawing parameters to adjust and standardize the electrical schematic diagram after the electrical schematic diagram is generated;

when a user needs to build a new project, a needed application scene model is selected from the database, then the components needed in the application scene are selected, under the condition that the to-be-applied scene and the components matched with the to-be-applied scene are selected, the user inputs design parameters through the input unit, and the processing unit generates an electrical schematic diagram according to the model of the to-be-applied scene, the components matched with the to-be-applied scene and the input design parameters.

2. The application scenario based electrical design system of claim 1, further comprising a display unit,

the display unit is used for displaying the electrical schematic diagram generated by the processing unit.

3. The application scenario-based electrical design system of claim 1, wherein the processing unit is located in a cloud server or in a local server.

4. An electrical design method based on application scenarios, characterized in that the electrical design method is based on the electrical design system based on application scenarios of any one of claims 1-3, and comprises the following steps:

s110, providing a model of a scene to be applied and a component matched with the scene to be applied;

s120, inputting design parameters;

and S130, generating an electrical schematic diagram according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters.

5. The electrical design method of claim 4, further comprising:

and S140, displaying the generated electrical schematic diagram at the user side.

6. The electrical design method of claim 5, further comprising:

and S150, inputting drawing parameters to adjust the electrical schematic diagram.

7. The electrical design method according to any one of claims 5 to 6, wherein step S130 specifically comprises:

forming a parameterized application scene according to the model of the scene to be applied, the components matched with the scene to be applied and the input design parameters;

forming structured design data according to the parameterized application scenarios;

operating on the structured design data;

and calculating the operation result and generating electrical schematic diagram data.

8. The electrical design method according to claim 4, wherein in step S110, a model of a scene to be applied and a component matching the scene to be applied are pre-established.

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