CN110737980B - Electrical design system and electrical design method - Google Patents
Electrical design system and electrical design method Download PDFInfo
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Abstract
The present utility model provides an electrical design system comprising: a data selection module; a graphic data module; a read/convert module connected to the pattern selection data module, receiving the input data, and generating intermediate data based on the input data querying the input query parameter set in the pattern selection data module; and a drawing module connected to the reading/converting module and the graphic data module, receiving the intermediate data from the reading/converting module, and generating output data including a typical electrical circuit graphic and a plurality of element parameters corresponding to a plurality of elements in the typical electrical circuit graphic based on querying the graphic data module for the intermediate data. By means of the electrical design system according to the utility model, it is possible to simply and efficiently generate an electrical design drawing with specific component parameters or to modify such an electrical design drawing on the basis of the basic demand parameters and a plurality of previously stored data sets. The utility model also provides an electrical design method.
Description
The present application claims priority from the patent application of the utility model, named "electrical design system", filed in the national intellectual property agency of China, having application number 201920254803.8, 28, 2019, 02.
Technical Field
The present utility model relates to an electrical design system and an electrical design method.
Background
In the engineering design process, element parameter design is required according to the requirement parameters, and then corresponding drawings marked with the element design parameters are drawn. Engineering drawing software such as CAD, EPLAN P8, etc. is also currently available on the market. However, since these engineering drawing software separates the design from the drawing, it takes a long time to manually design the component design parameters according to the required parameters and then to draw according to the component design parameters. In addition, after a part of demand parameters in engineering are modified, the whole drawing is required to be manually verified or modified, so that labor is consumed, and omission and errors are easy to occur.
Disclosure of Invention
The utility model provides an electrical design system which can assist in drawing an electrical design diagram, combines system parameter design with drawing, effectively improves working efficiency and is beneficial to avoiding manual errors.
According to one aspect of the utility model, an electrical design system includes: a model selection data module storing a plurality of model selection data sets, each model selection data set comprising an input query parameter set, a plurality of parameter identifiers, a plurality of element parameters, and a mapping between the plurality of parameter identifiers and the plurality of element parameters; a graphic data module storing a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern; a read/convert module connected to the pattern selection data module, the read/convert module receiving input data, the input data including a graphical identifier and input electrical parameters, the read/convert module further generating intermediate data based on the input data querying an input query parameter set in the pattern selection data module, the intermediate data including the graphical identifier, a plurality of parameter identifiers, a plurality of queried element parameters, and a mapping between the plurality of parameter identifiers and the plurality of queried element parameters; and a drawing module connected to the reading/converting module and the graphic data module, the drawing module receiving the intermediate data from the reading/converting module and generating output data including a typical electrical circuit pattern and a plurality of element parameters corresponding to a plurality of elements in the typical electrical circuit pattern based on querying the graphic data module for the intermediate data.
First, the electrical design system according to the present utility model has not only a drawing function but also a design function, compared to the conventional CAD, EPLAN design system. Secondly, the electrical design system according to the utility model enables a simple, fast and efficient generation of electrical designs with specific component parameters or modification of such electrical designs based on demand parameters and a plurality of pre-stored data sets. Further, since most of the steps of generating the electrical design drawing (e.g., including selection of specific element parameters, marking of element parameters, etc.) are automatically completed, occurrence of human error can be avoided, and drawing quality can be improved. Finally, conventional design systems typically make model and parameter selections and drawings manually, so often different designers choose different parameters and models, and the electrical design drawings drawn are different, and because the electrical design system according to the present utility model has relatively uniform form, layout, and parameter and model selection criteria, the resulting electrical design drawings are relatively standardized and uniform.
According to some embodiments, the electrical design system further comprises: an input interface connected to a read/convert module that receives input data from the input interface; and an output interface connected to the drawing module, the output interface receiving output data from the drawing module and displaying the electrical design drawing based on the output data.
According to some embodiments, the electrical design system further comprises an intermediate data storage module connected between the read/convert module and the drawing module, and storing intermediate data, the drawing module receiving the intermediate data from the read/convert module from the intermediate data storage module.
According to another aspect of the utility model, an electrical design system includes: a model selection data module storing a plurality of model selection data sets, each model selection data set comprising an input query parameter set, a plurality of parameter identifiers, a plurality of element parameters, and a mapping between the plurality of parameter identifiers and the plurality of element parameters; a graphic data module storing a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern; a plan data module storing plan model data including a plurality of circuit identifiers and connections between respective electrical circuits identified by the plurality of circuit identifiers; a read/convert module coupled to the pattern selection data module, the read/convert module receiving input data, the input data comprising a plurality of input data sets, each input data set comprising a loop identifier, a graphical identifier, and an input electrical parameter, the read/convert module further generating intermediate data based on the input data querying the input query parameter sets in the pattern selection data module, the intermediate data comprising a plurality of intermediate data sets, each intermediate data set comprising a loop identifier, a graphical identifier, a plurality of parameter identifiers, a plurality of discovered element parameters, and a mapping between the plurality of parameter identifiers and the plurality of discovered element parameters; and a drawing module connected to the read/convert module, the graphic data module, and the design drawing data module, the drawing module receiving the intermediate data from the read/convert module, and generating output data including a plurality of typical electrical circuit patterns, a plurality of element parameters corresponding to a plurality of elements in each of the typical electrical circuit patterns, and connections between the plurality of typical electrical circuit patterns based on querying the graphic data module and querying the design drawing data module for the intermediate data.
According to some embodiments, the electrical design system further comprises: an input interface connected to a read/convert module that receives input data from the input interface; and an output interface connected to the drawing module, the output interface receiving output data from the drawing module and displaying the electrical design drawing based on the output data.
According to some embodiments, the electrical design system further comprises an intermediate data storage module connected between the read/convert module and the drawing module, and storing intermediate data, the drawing module receiving the intermediate data from the read/convert module from the intermediate data storage module.
According to some embodiments, the drawing module is further connected to the input interface, the drawing module further receiving a design choice command from the input interface, wherein the design choice command is a function of the design choice command.
According to another aspect of the utility model, an electrical design method includes: receiving input data, the input data comprising a graphical identifier and an input electrical parameter; generating intermediate data based on the input data query parameter set in the input data query selection data module; and generating output data based on the intermediate data query graphic data module. The pattern selection data module stores a plurality of pattern selection data sets, each pattern selection data set including the input query parameter set, a plurality of parameter identifiers, a plurality of component parameters, and a mapping between a plurality of parameter identifiers and a plurality of component parameters. The graphic data module stores a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern. The intermediate data includes a graphical identifier, a plurality of parameter identifiers, a plurality of discovered component parameters, and a mapping between the plurality of parameter identifiers and the plurality of discovered component parameters. The output data includes a typical electrical circuit pattern and a plurality of component parameters corresponding to a plurality of components in the typical electrical circuit pattern.
According to another aspect of the utility model, an electrical design method includes: receiving input data, the input data comprising a plurality of input data sets, each input data set comprising a loop identifier, a graphical identifier, and an input electrical parameter; generating intermediate data based on the input data query parameter set in the input data query selection data module; and generating output data based on the intermediate data query graph data module and the query plan data module. The model selection data module stores a plurality of model selection data sets, each model selection data set including an input query parameter set, a plurality of parameter identifiers, a plurality of component parameters, and a mapping between the plurality of parameter identifiers and the plurality of component parameters. The graphic data module stores a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern. The design graph data module stores design graph model data including a plurality of circuit identifiers and connections between respective electrical circuits identified by the plurality of circuit identifiers. The intermediate data includes a plurality of intermediate data sets, each intermediate data set including a loop identifier, a graphic identifier, a plurality of parameter identifications, a plurality of discovered component parameters, and a mapping between the plurality of parameter identifications and the plurality of discovered component parameters. The output data includes a plurality of representative electrical circuit patterns, a plurality of component parameters corresponding to a plurality of components in each representative electrical circuit pattern, and connections between the plurality of representative electrical circuit patterns.
Drawings
Other features and advantages of the present utility model will become apparent from a reading of the following description. The following description, with reference to the accompanying drawings, is purely illustrative in that:
FIG. 1 illustrates an example electrical design diagram that an electrical design system according to a first embodiment of the utility model may use to draw;
FIG. 2 shows a diagram of an electrical design system according to a first embodiment of the utility model; and is also provided with
Fig. 3 shows a diagram of an electrical design system according to a second embodiment of the utility model.
Detailed Description
Hereinafter, an electrical design system according to an embodiment of the present utility model is described in detail with reference to the accompanying drawings. For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model.
Thus, the following detailed description of the embodiments of the utility model, as presented in conjunction with the accompanying drawings, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
The singular forms include the plural unless the context defines otherwise. Throughout the specification, the terms "comprises," "comprising," "has," "having," and the like are used herein to specify the presence of stated features, integers, steps, operations, elements, components, or groups thereof, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or groups thereof.
Fig. 1 shows an example electrical design diagram that an electrical design system according to a first embodiment of the utility model may use to draw. It should be understood that the electrical design is for illustrative purposes only and is not intended to limit the present utility model. The electrical design according to the utility model may comprise a single line diagram, a schematic diagram or an electronic diagram, etc.
The electrical design drawing drawn by the electrical design system according to the first embodiment shows one electrical circuit, such as a motor circuit. A first embodiment according to the present utility model will be described below with a design of a motor circuit as an example of an electrical design. As shown in fig. 1, the electric circuit includes a motor M, a circuit breaker Q, a contactor KM, and the like.
In designing the motor circuit, other electrical components (e.g., the circuit breaker Q and the contactor KM) need to be parametrically designed according to parameters of the motor (e.g., the motor M), such as a motor model, a rated voltage, a power factor, etc., and finally, an electrical design diagram of the electrical circuit having the components marked with the component parameters thereof as shown in fig. 1 is drawn to be provided to customers. However, the parametric design of other electrical components and the drawing of electrical designs of electrical circuits having components marked with their component parameters is often manual, time consuming, costly and prone to error.
Fig. 2 shows a diagram of an electrical design system according to a first embodiment of the utility model, which may automatically parameter design or pattern other electrical elements in an electrical circuit based on input electrical parameters, and may then automatically generate an electrical design diagram representing the electrical circuit marked with design parameters, thereby combining the parameter design with a drawing.
As shown in fig. 2, the electrical design system according to the first embodiment of the present utility model includes an input interface 11, a pattern selection data module 13, a reading/conversion module 12, a graphic data module 16, a drawing module 15, and an output interface 17, wherein the input interface 11 and the pattern selection data module 13 are respectively connected to the reading/conversion module 12, the reading/conversion module 12 is connected to the drawing module 15, the graphic data module 16 is also connected to the drawing module 15, and the drawing module 15 is connected to the output interface 17. The "connection" may be a direct connection or an indirect connection, and may be a wired connection or a wireless connection.
The profile data module 13 stores a plurality of profile data sets, each profile data set including an input query parameter set, a plurality of parameter identifiers, a plurality of component parameters, and a mapping between the plurality of parameter identifiers and the plurality of component parameters. For example, one example set of input query parameters may include one or more of motor model, rated power, rated current, frequency, efficiency, power factor, starting torque, starting current, maximum torque, and the like. For example, the component parameter may be a breaker model, a breaker rated operating current, a breaker instantaneous trip current, a contactor model, a contactor rated operating voltage, or other parameters, and the parameter identifier may be an identifier (or code number, or marker) corresponding to the component parameters one to one. The profile data module 13 may be a non-transitory memory.
The graphic data module 16 stores a plurality of graphic data sets each including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern. The graphic identifier may be used to identify each graphic data set containing a different typical electrical circuit graphic, which is represented as a plurality of component graphics and connections between the plurality of component graphics. However, since the design of the component parameters has not been performed, a typical electrical circuit pattern is only a pattern, and the component parameters are not included in the pattern data set. The graphics data module 16 may be a non-transitory memory.
The input interface 11 may be an input device such as a keyboard, mouse, etc. that may receive input commands from a user to generate input data, which may include graphical identifiers and input electrical parameters. The entered graphic identifier is used to match a graphic identifier in a particular graphic data set to select that particular graphic data set that includes a particular typical electrical circuit pattern. The input electrical parameters may be designed to be a subset of the input query parameter set. For an example motor circuit, the input electrical parameters may include one or more of motor model, rated power, rated current, frequency, efficiency, power factor, starting torque, starting current, maximum torque, and the like.
The reading/converting module 12 receives input data from the input interface 11 and generates intermediate data based on the input query parameters in the input data query pattern selecting data module 13. The intermediate data includes a graphical identifier, a plurality of parameter identifiers, a plurality of discovered component parameters, and a mapping between the plurality of parameter identifiers and the plurality of discovered component parameters.
Querying the input query parameter set in the model selection data module 13 based on the input data may include looking up a particular input query parameter set that includes parameters that match the input electrical parameters in the input data. A plurality of parameter identifiers, a plurality of discovered component parameters, and a mapping between the plurality of parameter identifiers and the plurality of discovered component parameters of the intermediate data are derived based on the particular input electrical parameter, which are included in the same set of profile data as the particular input query parameter set.
The read/convert module 12 may be a Power Query module of EXCEL software.
The format of the intermediate data may be a file format that can be read by the drawing module 15, for example, an excel file format, a txt file format, or an xml file format.
The drawing module 15 receives the intermediate data from the reading/converting module 12 and queries the graphic data module 16 based on the intermediate data to generate output data including a typical electrical circuit graphic and a plurality of component parameters corresponding to a plurality of components in the typical electrical circuit graphic.
Querying the graphic data module 16 based on the intermediate data to generate output data includes selecting a particular graphic data set using the graphic identifiers, and matching a plurality of components in a particular typical electrical circuit graphic with a plurality of discovered component parameters using a plurality of parameter identifiers in the particular graphic data set and a plurality of parameter identifiers in the intermediate data.
The drawing module 15 may be EPLAN software or AutoCAD software.
The output interface 17 receives the output data from the drawing module 15, and displays an electrical design drawing based on the output data, and the output interface 17 may be a display or the like.
Optionally, the electrical design system according to the first embodiment may further comprise an intermediate data storage module 14 connected between the reading/conversion module 12 and the drawing module 15. The intermediate data storage module 14 stores intermediate data, which is received from the reading/converting module 12 and stored, and then transfers the intermediate data to the drawing module 15.
An example use case of the electrical design system according to the first embodiment is described below.
A given user needs to map the electrical design of the motor circuit in which the component model of each component needs to be displayed. As an example, the motor model is determined according to the demand, and the motor model is input as an input electrical parameter in the input data via the input interface 11. It is noted that the input electrical parameters according to the utility model are not limited to motor models, and the applications according to the utility model are not limited to motor circuits.
The reading/converting module 12 is, for example, a Power Query module of EXCEL software, which receives the motor model number, and queries the option data module 13 based on the motor model number. The pattern data module 13 may be a pre-established EXCEL database that stores a plurality of pattern data sets. The intermediate data may be generated when the motor model matches the motor model in the set of input query parameters of the particular model selection data set. The plurality of parameter identifiers, the plurality of element parameters, and the mapping between the plurality of parameter identifiers and the plurality of element parameters in the particular selection data set may be retrieved for use as the plurality of parameter identifiers, the plurality of element parameters, and the mapping between the plurality of parameter identifiers and the plurality of element parameters in the intermediate data. For example, the plurality of parameter identifiers in the intermediate data may include typemotor representing a MOTOR model, typecutter representing a BREAKER model, and typeconnector representing a CONTACTOR model, the plurality of detected element parameters may include MOTOR model MOTOR1, BREAKER model break 1, and CONTACTOR model CONTACTOR1, and the mapping between the plurality of parameter identifiers and the plurality of detected element parameters may be typemotor=motor 1, typecutter=break 1, and typeconnector=contactor 1. That is, the component parameters in the electrical circuit can be automatically designed or selected by querying the profile data module 13. In addition, the intermediate data includes a graphical identifier. It should be noted that the component parameters are not limited to the component model number, but may be other parameters of the component, and the component parameters corresponding to each component are not limited to one, and may be none or more than one.
The intermediate data is stored in the intermediate data storage module 14 and then can be transferred to the drawing module 15, and the drawing module 15 can be computer aided design software such as AutoCAD, EPLAN.
The drawing module 15 generates output data based on the intermediate data query graphic data module 16. The graphic data module includes a plurality of graphic data sets having graphic identifiers. The drawing module 15 may select a specific graphic data group from a plurality of graphic data groups in the graphic data module 16 based on the graphic identifier in the intermediate data. The specific pattern data set includes a specific typical electrical circuit pattern including, for example, patterns representing components such as a motor, a circuit breaker, and a contactor, respectively, and connections therebetween. The graphics data module generates output data based on the intermediate data and the particular graphics data set. The particular graphic data set also includes a plurality of parameter identifiers corresponding to the graphics of those elements in the particular typical electrical circuit graphic. The plurality of parameter identifiers may include an identifier typemotor representing a motor model corresponding to a motor graphic, an identifier typebreaker representing a breaker model corresponding to a breaker graphic, and an identifier typeconnector representing a contactor model corresponding to a contactor graphic. The graphic data set does not include the component parameters of these components and therefore it cannot be used to map a complete electrical design drawing.
Specifically, based on the matching of the parameter identifier typemotor, typebreaker and the typeconnector common to the intermediate data and the specific pattern data group, a specific typical electrical circuit pattern and a plurality of element parameters corresponding to a plurality of elements in the specific typical electrical circuit pattern, that is, a parameter MOTOR1 corresponding to a MOTOR pattern in the specific typical electrical circuit pattern, a parameter break 1 corresponding to a BREAKER pattern, and a parameter CONTACTOR1 corresponding to a CONTACTOR pattern are generated.
The output data is displayed as an electrical design drawing through the output interface 17 and a complete electrical design drawing (not shown) including a representative electrical circuit graphical representation and component parametric representation.
Fig. 3 shows a diagram of an electrical design system according to a second embodiment of the utility model.
The electrical design system according to the second embodiment of the present utility model includes an input interface 21, a selection data module 23, a reading/conversion module 22, a graphic data module 26, an intermediate data storage module 24, a drawing module 25, and an output interface 27. Unlike the first embodiment shown in fig. 2, the electrical design system further comprises a design drawing data module 28, which is connected to the drawing module 25. The plan data module 28 stores plan model data including a plurality of circuit identifiers and connections between corresponding electrical circuits identified by the plurality of circuit identifiers.
The electrical design system according to the second embodiment may be used to draw an electrical design drawing including a plurality of electrical circuits. The plurality of electrical circuits are identified by a circuit identifier.
The profile data module 23 stores a plurality of profile data sets, each profile data set including an input query parameter set, a plurality of parameter identifiers, a plurality of component parameters, and a mapping between the plurality of parameter identifiers and the plurality of component parameters.
The graphic data module 26 stores a plurality of graphic data sets, each including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern.
The user inputs input data via the input interface 21. The input data includes a plurality of input data sets, each input data set including a circuit identifier, a graphical identifier, and an input electrical parameter. The user may select a desired graphic data set (or, alternatively, a typical electrical circuit pattern that meets the drawing requirements) from among the plurality of graphic data sets in the graphic data module 26 for each electrical circuit to be drawn by entering the circuit identifier and the graphic identifier. For example, the input data indicates that the first electrical circuit selection of circuit identifier a employs a first graphic data set comprising a first typical electrical circuit pattern of graphic identifier i and the second electrical circuit selection of circuit identifier b employs a first graphic data set comprising a second typical electrical circuit pattern of graphic identifier ii.
The read/convert module 22 receives the input data and generates intermediate data by querying the input query parameter set in the pattern selection data module 23 based on the input data, the intermediate data comprising a plurality of intermediate data sets, each intermediate data set comprising a loop identifier, a graphic identifier, a plurality of parameter identifications, a plurality of discovered component parameters, and a mapping between the plurality of parameter identifications and the plurality of discovered component parameters.
The intermediate data may be stored in the intermediate data storage module 24.
Drawing module 25 may receive intermediate data from intermediate data storage module 24 and generate output data including a plurality of representative electrical circuit patterns, a plurality of component parameters corresponding to a plurality of components in each representative electrical circuit pattern, and a connection between the plurality of representative electrical circuit patterns based on intermediate data query pattern data module 26 and design pattern data module 28. Each intermediate data set corresponds to an electrical circuit. Drawing module 25 queries graphic data module 26 based on the circuit identifiers and graphic identifiers in the intermediate data sets to select the graphic data set to be employed for each electrical circuit. The mapping module 25 also obtains, for each electrical circuit, a typical electrical circuit pattern for each electrical circuit and component parameters for the components therein based on the plurality of the discovered component parameters and the plurality of parameter identifications in the graphic data set and the corresponding intermediate data set and the mapping between the plurality of discovered component parameters. The drawing module 25 also queries the design drawing module 28 to generate output data. The drawing module 25 matches the circuit identifier of each circuit with a plurality of circuit identifiers in the design drawing model data to generate output data.
Optionally, the layout module 28 may also be connected to the input interface 21, for example in case the layout data module stores a plurality of layout model data. The drawing module 25 receives a design drawing selection command from the input interface 21 and selects one of a plurality of design drawing model data based on the design drawing selection command.
It should be noted that the above-described reading/converting modules 12, 22, the option data modules 13, 23, the intermediate data storage modules 14, 24, the drawing modules 15, 25, the graphic data modules 16, 26, and the design data module 28 are not limited to being physically separated. For example, the above-described selection data modules 13, 23, intermediate data storage modules 14, 24, graphics data modules 16, 26, and design data module 28 may be different partitions of a block of memory.
The scope of the utility model is not to be limited by the embodiments described above, but by the appended claims and their equivalents.
Claims (9)
1. An electrical design system, comprising:
a model selection data module storing a plurality of model selection data sets, each model selection data set comprising an input query parameter set, a plurality of parameter identifiers, a plurality of element parameters, and a mapping between the plurality of parameter identifiers and the plurality of element parameters;
a graphic data module storing a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern;
a read/convert module connected to the pattern selection data module, the read/convert module receiving input data, the input data including a graphical identifier and input electrical parameters, the read/convert module further generating intermediate data based on the input data querying an input query parameter set in the pattern selection data module, the intermediate data including the graphical identifier, a plurality of parameter identifiers, a plurality of queried element parameters, and a mapping between the plurality of parameter identifiers and the plurality of queried element parameters; and
and a drawing module connected to the reading/converting module and the graphic data module, the drawing module receiving the intermediate data from the reading/converting module and generating output data including a typical electrical circuit pattern and a plurality of element parameters corresponding to a plurality of elements in the typical electrical circuit pattern based on querying the graphic data module for the intermediate data.
2. The electrical design system of claim 1, further comprising:
an input interface connected to a read/convert module that receives input data from the input interface; and
and the output interface is connected to the drawing module, receives the output data from the drawing module and displays the electrical design diagram based on the output data.
3. The electrical design system of claim 1, wherein,
the electrical design system further includes an intermediate data storage module coupled between the read/convert module and the drawing module, and storing intermediate data, the drawing module receiving the intermediate data from the read/convert module from the intermediate data storage module.
4. An electrical design system, comprising:
a model selection data module storing a plurality of model selection data sets, each model selection data set comprising an input query parameter set, a plurality of parameter identifiers, a plurality of element parameters, and a mapping between the plurality of parameter identifiers and the plurality of element parameters;
a graphic data module storing a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of component patterns in the typical electrical circuit pattern;
a plan data module storing plan model data including a plurality of circuit identifiers and connections between respective electrical circuits identified by the plurality of circuit identifiers;
a read/convert module coupled to the pattern selection data module, the read/convert module receiving input data, the input data comprising a plurality of input data sets, each input data set comprising a loop identifier, a graphical identifier, and an input electrical parameter, the read/convert module further generating intermediate data based on the input data querying the input query parameter sets in the pattern selection data module, the intermediate data comprising a plurality of intermediate data sets, each intermediate data set comprising a loop identifier, a graphical identifier, a plurality of parameter identifiers, a plurality of discovered element parameters, and a mapping between the plurality of parameter identifiers and the plurality of discovered element parameters; and
and a drawing module connected to the read/convert module, the graphic data module, and the design drawing data module, the drawing module receiving the intermediate data from the read/convert module, and generating output data including a plurality of typical electrical circuit patterns, a plurality of element parameters corresponding to a plurality of elements in each of the typical electrical circuit patterns, and connections between the plurality of typical electrical circuit patterns based on the intermediate data querying the graphic data module and the query design drawing data module.
5. The electrical design system of claim 4, further comprising:
an input interface connected to a read/convert module that receives input data from the input interface; and
and the output interface is connected to the drawing module, receives the output data from the drawing module and displays the electrical design diagram based on the output data.
6. The electrical design system of claim 4, wherein,
the electrical design system further includes an intermediate data storage module coupled between the read/convert module and the drawing module, and storing intermediate data, the drawing module receiving the intermediate data from the read/convert module from the intermediate data storage module.
7. The electrical design system of claim 4, wherein,
the drawing module is further coupled to the input interface, the drawing module further receives a design drawing selection command from the input interface, wherein,
the schematic data module stores a plurality of schematic model data, each comprising a plurality of circuit identifiers and connections between respective electrical circuits identified by the plurality of circuit identifiers,
the drawing module selects one of a plurality of design drawing model data based on a design drawing selection command.
8. An electrical design method, comprising:
receiving input data, the input data comprising a graphical identifier and an input electrical parameter;
generating intermediate data based on the input data query parameter set in the input data query selection data module; and
generating output data based on the intermediate data query pattern data module,
wherein the model selection data module stores a plurality of model selection data sets, each model selection data set comprising the input query parameter set, a plurality of parameter identifiers, a plurality of element parameters, and a mapping between the plurality of parameter identifiers and the plurality of element parameters;
wherein the graphic data module stores a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of element patterns in the typical electrical circuit pattern;
wherein the intermediate data includes a graphical identifier, a plurality of parameter identifiers, a plurality of discovered element parameters, and a mapping between the plurality of parameter identifiers and the plurality of discovered element parameters; and is also provided with
Wherein the output data includes a typical electrical circuit pattern and a plurality of component parameters corresponding to a plurality of components in the typical electrical circuit pattern.
9. An electrical design method, comprising:
receiving input data, the input data comprising a plurality of input data sets, each input data set comprising a loop identifier, a graphical identifier, and an input electrical parameter;
generating intermediate data based on the input data query parameter set in the input data query selection data module; and
generating output data based on the intermediate data query graph data module and the query plan graph data module,
wherein the pattern selection data module stores a plurality of pattern selection data sets, each pattern selection data set comprising an input query parameter set, a plurality of parameter identifiers, a plurality of element parameters, and a mapping between the plurality of parameter identifiers and the plurality of element parameters;
wherein the graphic data module stores a plurality of graphic data sets, each graphic data set including a graphic identifier, a typical electrical circuit pattern, and a plurality of parameter identifiers corresponding to a plurality of element patterns in the typical electrical circuit pattern;
wherein the plan data module stores plan model data including a plurality of circuit identifiers and connections between respective electrical circuits identified by the plurality of circuit identifiers;
wherein the intermediate data comprises a plurality of intermediate data sets, each intermediate data set comprising a loop identifier, a graphical identifier, a plurality of parameter identifications, a plurality of discovered component parameters, and a mapping between the plurality of parameter identifications and the plurality of discovered component parameters; and is also provided with
The output data comprises a plurality of typical electrical circuit patterns, a plurality of element parameters corresponding to a plurality of elements in each typical electrical circuit pattern, and connections between the plurality of typical electrical circuit patterns.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201920254803 | 2019-02-28 | ||
| CN2019202548038 | 2019-02-28 |
Publications (2)
| Publication Number | Publication Date |
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| CN110737980A CN110737980A (en) | 2020-01-31 |
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Citations (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103400007A (en) * | 2013-08-06 | 2013-11-20 | 山东爱普电气设备有限公司 | Automatic generation method of secondary electrical schematic diagrams based on Auto CAD |
| KR101430176B1 (en) * | 2013-04-10 | 2014-08-14 | 한전케이디엔주식회사 | System and method for auto-drawing of single Line Diagram based on SCL |
| CN106528910A (en) * | 2016-09-13 | 2017-03-22 | 北京金雨科创自动化技术股份有限公司 | Electric design platform and method for same |
| CN107729682A (en) * | 2017-11-06 | 2018-02-23 | 四川电力设计咨询有限责任公司 | Electrical system and design method for the electric factory of thermal power project |
| CN107784139A (en) * | 2016-08-26 | 2018-03-09 | 沈阳鼓风机集团自动控制系统工程有限公司 | Compressor control system electrical schematic diagram automatic generation method |
-
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- 2019-10-12 CN CN201910968731.8A patent/CN110737980B/en active Active
Patent Citations (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| KR101430176B1 (en) * | 2013-04-10 | 2014-08-14 | 한전케이디엔주식회사 | System and method for auto-drawing of single Line Diagram based on SCL |
| CN103400007A (en) * | 2013-08-06 | 2013-11-20 | 山东爱普电气设备有限公司 | Automatic generation method of secondary electrical schematic diagrams based on Auto CAD |
| CN107784139A (en) * | 2016-08-26 | 2018-03-09 | 沈阳鼓风机集团自动控制系统工程有限公司 | Compressor control system electrical schematic diagram automatic generation method |
| CN106528910A (en) * | 2016-09-13 | 2017-03-22 | 北京金雨科创自动化技术股份有限公司 | Electric design platform and method for same |
| CN107729682A (en) * | 2017-11-06 | 2018-02-23 | 四川电力设计咨询有限责任公司 | Electrical system and design method for the electric factory of thermal power project |
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