CN111931888B - Dynamic duplicate code generation method and device based on electric power data - Google Patents

Abstract

The embodiment of the application provides a dynamic rework code generation method and device based on electric power data, and the method comprises the steps of constructing a virtual prism according to the type of rework data of a target enterprise; obtaining rework data of a target enterprise, and converting the rework data into electric power data; displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time; calculating the rework progress of each side surface of the virtual prism at regular time, and displaying a rework code of a corresponding target enterprise obtained based on a calculation result on the bottom surface of the virtual prism; wherein each side of the virtual prism corresponds to a rework data category. The accuracy of the rework progress calculation is improved by converting the rework data of various aspects into electric quantity data capable of being uniformly metered; in addition, based on the reworking codes updated in each aspect of progress at regular time, the latest reworking progress of the target enterprise can be directly obtained, and the steps for obtaining the reworking information of the target enterprise are reduced.

Description

Dynamic duplicate code generation method and device based on electric power data

Technical Field

The application belongs to the field of data processing, and particularly relates to a dynamic duplicate code generation method and device based on electric power data.

Background

The rework code in the prior art is a two-dimensional code formed by dot matrix patterns, the two-dimensional code needs to be scanned, information such as the specific rework and rework progress of an enterprise can be acquired after page jump is performed by means of a third-party tool such as a browser, the operation is complex when the rework and rework information is acquired every time, if the network condition is not good, detailed information can be acquired by long-time buffering, and inconvenience is brought to practical use.

Disclosure of Invention

In order to overcome the defects and shortcomings in the prior art, the dynamic rework code generation method and device based on the electric power data are provided, the rework code is generated according to the obtained rework data and is updated in real time, and the accuracy of a target enterprise in the aspect of displaying rework and rework information is improved.

Specifically, on one hand, the application provides a dynamic duplicate code generation method based on power data, which includes:

constructing a virtual prism according to the rework data type of the target enterprise;

obtaining rework data of a target enterprise, and converting the rework data into electric power data;

displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time;

calculating the rework progress of each side surface of the virtual prism at regular time, and displaying a rework code of a corresponding target enterprise obtained based on a calculation result on the bottom surface of the virtual prism;

wherein each side of the virtual prism corresponds to a rework data category.

Optionally, the constructing a virtual prism according to the rework data type of the target enterprise includes:

determining the rework data type of the target enterprise;

and constructing an initial virtual prism, and adjusting the number of the side faces of the initial virtual prism based on the type of the rework data to obtain a virtual prism with the number of the side faces consistent with the type of the rework data.

Optionally, the obtaining of the rework data of the target enterprise and converting the rework data into the power data includes:

establishing a corresponding relation between the rework data and the power data based on the property of the rework data;

and acquiring the rework data of the target enterprise, and converting each type of rework data into electric power data according to the established corresponding relation.

Optionally, the displaying, in real time, a rework progress calculated based on the electric power data on the side surface of the virtual prism includes:

step one, acquiring full-scale power data corresponding to each rework data category;

calculating the percentage of the target power data relative to the full-rated power data in each rework data category to obtain a rework progress corresponding to a percentage result;

refreshing a rework progress image on the side face of the virtual prism corresponding to the target power data based on the obtained rework progress;

and executing the contents of the first step to the third step at preset intervals.

Optionally, the calculating the rework progress of each side surface of the virtual prism at regular time, and displaying the rework codes of the corresponding target enterprises obtained based on the calculation result on the bottom surface of the virtual prism includes:

the reworking progress of each side face on the virtual prism is obtained at preset intervals, and a reworking overall data set corresponding to a target enterprise is generated by combining the reworking data category corresponding to each side face;

calculating the rework progress values of corresponding target enterprises in the rework plan data set according to different weights of each rework data category;

and according to the obtained rework progress value, combining enterprise information of the target enterprise and obtaining a rework code corresponding to the target enterprise through a two-dimensional code generation algorithm.

On the other hand, the present application also provides a dynamic duplicate code generation device based on power data, the device includes:

the virtual construction unit is used for constructing a virtual prism according to the rework data type of the target enterprise;

the data conversion unit is used for acquiring the rework data of the target enterprise and converting the rework data into electric power data;

the progress display unit is used for displaying the rework progress calculated based on the electric power data on the side face of the virtual prism in real time;

the image code generating unit is used for calculating the rework progress of each side surface of the virtual prism at regular time and displaying the rework codes of the corresponding target enterprises obtained based on the calculation result on the bottom surface of the virtual prism;

wherein each side of the virtual prism corresponds to a rework data category.

Optionally, the virtual building unit includes:

the data classification subunit is used for determining the rework data type of the target enterprise;

and the prism construction subunit is used for constructing an initial virtual prism, and adjusting the number of the side faces of the initial virtual prism based on the type of the rework data to obtain a virtual prism with the number of the side faces consistent with the type of the rework data.

Optionally, the data conversion unit includes:

the relation establishing subunit is used for establishing a corresponding relation between the rework data and the power data based on the property of the rework data;

and the data conversion subunit is used for acquiring the rework data of the target enterprise and converting each type of rework data into electric power data according to the established corresponding relation.

Optionally, the progress display unit includes:

the data acquisition subunit is used for acquiring full-scale power data corresponding to each rework data category;

the progress determining subunit is used for calculating the percentage of the target power data relative to the full-rated power data in each rework data category to obtain the rework progress corresponding to the percentage result;

the progress refreshing subunit is used for refreshing the rework progress image on the side face of the virtual prism corresponding to the target electric power data based on the obtained rework progress;

and executing the contents of the first step to the third step at preset intervals.

Optionally, the graph code generating unit includes:

the progress acquiring subunit is used for acquiring the rework progress of each side surface on the virtual prism at preset intervals, and generating a rework overall data set of the corresponding target enterprise by combining the rework data category corresponding to each side surface;

the progress calculation operator unit is used for calculating the rework progress values of the corresponding target enterprises in the rework plan data set according to different weights of the rework data types;

and the graph code drawing subunit is used for obtaining the multiplex code corresponding to the target enterprise through a two-dimensional code generation algorithm according to the obtained multiplex progress value and the enterprise information of the target enterprise.

The beneficial effect that technical scheme that this application provided brought is:

1) the accuracy of the rework progress calculation is improved by converting the rework data of various aspects into electric quantity data capable of being uniformly metered;

2) the reworking code updated regularly based on all aspects of progress has the characteristic of updating regularly, so that the latest reworking progress of a target enterprise can be directly obtained, a remote server does not need to be connected for updating the reworking progress, the steps of obtaining the reworking information of the target enterprise are reduced, and the effectiveness of the reworking code is improved.

Drawings

In order to more clearly illustrate the technical solutions of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a flowchart of a dynamic duplicate code generation method based on power data according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram illustrating an effect of a virtual prism according to an embodiment of the present disclosure;

fig. 3 is a structural diagram of a dynamic duplicate code generation device based on power data according to an embodiment of the present application.

Detailed Description

To make the structure and advantages of the present application clearer, the structure of the present application will be further described with reference to the accompanying drawings.

Example one

The application provides a dynamic duplicate code generation method based on power data, as shown in fig. 1, including:

11. constructing a virtual prism according to the rework data type of the target enterprise;

12. obtaining rework data of a target enterprise, and converting the rework data into electric power data;

13. displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time;

14. calculating the rework progress of each side surface of the virtual prism at regular time, and displaying a rework code of a corresponding target enterprise obtained based on a calculation result on the bottom surface of the virtual prism;

wherein each side of the virtual prism corresponds to a rework data category.

In implementation, in order to visually display the rework progress of a target enterprise, the embodiment of the application provides a dynamic rework code generation method, the rework progress of the target enterprise in different aspects is displayed simultaneously in a virtual prism mode, and each type of progress is updated in real time. Compared with the mode of displaying by means of a chart or pure data in the prior art, on one hand, the effectiveness of the re-work and re-production progress can be improved, and on the other hand, the visual effect of data displaying can also be improved by means of the virtual prism displaying mode.

It should be noted that the virtual prism used in the present application is a three-dimensional dynamic image generated in drawing software, and the image integrally presents the basic shape of the prism, as shown in fig. 2, the number of the side faces of the virtual prism is adjusted according to the type of rework data, so that the number of the side faces is exactly equal to the number of the rework data to be displayed. And then the reworking progress is dynamically displayed on each side surface according to the reworking data of the corresponding category, and finally the dynamic display effect of the reworking and reworking progress of the target enterprise is completed.

In addition, in the embodiment of the application, the electric power data is adopted when the re-work and re-production progress is displayed, and the fact that the power consumption cannot be kept in the aspects of production, sales, life of workers and the like of a target enterprise is considered, so that the electric power data can be used for comprehensively describing all aspects of the enterprise including production.

Based on the above technical description, the processing idea of the technical solution proposed by this embodiment is as follows:

first, the rework data category of the target enterprise is determined. Specifically, the step 11 of constructing the virtual prism according to the rework data type of the target enterprise includes:

determining the rework data type of the target enterprise;

and constructing an initial virtual prism, and adjusting the number of the side faces of the initial virtual prism based on the type of the rework data to obtain a virtual prism with the number of the side faces consistent with the type of the rework data.

In implementation, typical rework data types include two types of production power consumption and staff life power consumption, the specific production power consumption further includes a typical three-section processing process of raw material cleaning (primary processing) power consumption, finished product production (secondary processing) and finished product cleaning (final processing), the staff life power consumption includes staff 220V consumption power consumption, staff 380V conversion equipment power consumption (such as domestic water filtering facilities) and the like, the production power consumption can be obtained according to the power consumption of a target enterprise in the same period and same scale production stage, and the staff life power consumption can be obtained by performing same-proportion conversion according to the staff number of the target enterprise. For example, the number of employees in the past year is 1500, and the number of employees in the present year is 1200, namely, the employees can be obtained by multiplying the power consumption of the past year by a coefficient 1200/1500.

And secondly, converting the previous work-doing data of the target enterprise into electric power data. Specifically, the obtaining of the rework data of the target enterprise and converting the rework data into the power data in step 12 includes:

establishing a corresponding relation between the rework data and the power data based on the property of the rework data;

and acquiring the rework data of the target enterprise, and converting each type of rework data into electric power data according to the established corresponding relation.

In the implementation, the electricity consumption obtained in the previous step includes the electricity consumption for production and the electricity consumption for life of the staff, and since part of the electricity consumption is consumed in other energy consumption devices such as a lathe, a water pump, a high-pressure water gun and the like, in order to facilitate the processing of the rework and production replication data in the subsequent step, other energy sources in the two types of electricity consumption data need to be converted into electricity data in the step. Typically, for example, a water pump can convert all energy consumption related to the water pump into power data according to data such as usage time, power, water consumption and the like of the water pump, and further, in order to improve accuracy of converting into the power data, it is necessary to obtain real power consumption of equipment instead of equivalent power consumption by dividing by work efficiency of corresponding equipment in the data conversion process.

And finally, displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time. Typically, the real-time display of the rework progress calculated based on the power data on the side surface of the virtual prism in step 13 includes:

step one, acquiring full-scale power data corresponding to each rework data category;

calculating the percentage of the target power data relative to the full-rated power data in each rework data category to obtain a rework progress corresponding to a percentage result;

and thirdly, refreshing the rework progress image on the side face of the virtual prism corresponding to the target power data based on the obtained rework progress.

In implementation, the virtual prisms with the number of side faces equal to the type of the rework data are constructed through common three-dimensional drawing software, different rework data types to be displayed are defined for each side face of the virtual prisms, meanwhile, calculation is carried out on each rework data based on current data, and the percentage of the rework data is displayed in the form of corresponding side face area percentage, so that the rework progress of the rework data is reflected. An exemplary virtual prism is shown in fig. 2, which shows different rework schedules for a rework data category with a preset data size of 6. In consideration of the actual display effect, the virtual prism is displayed in a mode of slowly rotating along the axis, so that different types of rework progress can be displayed on different sides, and the rework progress display effect of a target enterprise is improved.

Furthermore, the contents of the first step to the third step are executed at preset intervals, so that the rework progress displayed by the virtual prism can represent the current latest condition, and the real-time performance of the rework progress display of the target enterprise is improved.

Considering that the mode that the virtual prisms are displayed in the side areas cannot display detailed rework data types and detailed data, a technical scheme for acquiring and displaying rework codes is also provided. Specifically, the calculating the rework progress of each side surface of the virtual prism at the timing set forth in step 14, and displaying the rework codes of the corresponding target enterprises obtained based on the calculation result on the bottom surface of the virtual prism, includes:

the reworking progress of each side face on the virtual prism is obtained at preset intervals, and a reworking overall data set corresponding to a target enterprise is generated by combining the reworking data category corresponding to each side face;

calculating the rework progress values of corresponding target enterprises in the rework plan data set according to different weights of each rework data category;

and according to the obtained rework progress value, combining enterprise information of the target enterprise and obtaining a rework code corresponding to the target enterprise through a two-dimensional code generation algorithm.

In implementation, the rework progress (typically percentage data) of each side surface of the virtual prism is calculated regularly, and then the rework codes of the corresponding target enterprises obtained based on the calculation results are displayed on one or two bottom surfaces of the prism. Thus, a user who needs detailed rework data can obtain detailed content of detailed rework progress through scanning the multidimensional codes.

Example two

On the other hand, the present application also proposes a dynamic duplicate code generation apparatus 3 based on power data, as shown in fig. 3, the apparatus includes:

the virtual construction unit 31 is used for constructing a virtual prism according to the rework data type of the target enterprise;

the data conversion unit 32 is configured to acquire rework data of a target enterprise, and convert the rework data into power data;

the progress display unit 33 is used for displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time;

the figure code generating unit 34 is used for calculating the rework progress of each side surface of the virtual prism at regular time, and displaying the rework codes of the corresponding target enterprises obtained based on the calculation results on the bottom surface of the virtual prism;

wherein each side of the virtual prism corresponds to a rework data category.

In implementation, in order to visually display the rework progress of a target enterprise, an embodiment of the application provides a dynamic rework code generating device, which displays the rework progress of the target enterprise in different aspects by means of a virtual prism, and each type of progress is updated in real time. Compared with the mode of displaying by means of a chart or pure data in the prior art, on one hand, the effectiveness of the re-work and re-production progress can be improved, and on the other hand, the visual effect of data displaying can also be improved by means of the virtual prism displaying mode.

It should be noted that the virtual prism used in the present application is a three-dimensional dynamic image generated in drawing software, and the image integrally presents the basic shape of the prism, as shown in fig. 2, the number of the side faces of the virtual prism is adjusted according to the type of rework data, so that the number of the side faces is exactly equal to the number of the rework data to be displayed. And then the reworking progress is dynamically displayed on each side surface according to the reworking data of the corresponding category, and finally the dynamic display effect of the reworking and reworking progress of the target enterprise is completed.

In addition, in the embodiment of the application, the electric power data is adopted when the re-work and re-production progress is displayed, and the fact that the power consumption cannot be kept in the aspects of production, sales, life of workers and the like of a target enterprise is considered, so that the electric power data can be used for comprehensively describing all aspects of the enterprise including production.

Based on the above technical description, the processing idea of the technical solution proposed by this embodiment is as follows:

first, the rework data category of the target enterprise is determined. Specifically, the virtual construction unit 31 for constructing a virtual prism according to the rework data type of the target enterprise specifically includes:

the data classification subunit is used for determining the rework data type of the target enterprise;

and the prism construction subunit is used for constructing an initial virtual prism, and adjusting the number of the side faces of the initial virtual prism based on the type of the rework data to obtain a virtual prism with the number of the side faces consistent with the type of the rework data.

In implementation, typical rework data types include two types of production power consumption and staff life power consumption, the specific production power consumption further includes a typical three-section processing process of raw material cleaning (primary processing) power consumption, finished product production (secondary processing) and finished product cleaning (final processing), the staff life power consumption includes staff 220V consumption power consumption, staff 380V conversion equipment power consumption (such as domestic water filtering facilities) and the like, the production power consumption can be obtained according to the power consumption of a target enterprise in the same period and same scale production stage, and the staff life power consumption can be obtained by performing same-proportion conversion according to the staff number of the target enterprise. For example, the number of employees in the past year is 1500, and the number of employees in the present year is 1200, namely, the employees can be obtained by multiplying the power consumption of the past year by a coefficient 1200/1500.

And secondly, converting the previous work-doing data of the target enterprise into electric power data. Specifically, the data conversion unit 32, configured to obtain rework data of the target enterprise and convert the rework data into power data, includes:

the relation establishing subunit is used for establishing a corresponding relation between the rework data and the power data based on the property of the rework data;

and the data conversion subunit is used for acquiring the rework data of the target enterprise and converting each type of rework data into electric power data according to the established corresponding relation.

In the implementation, the electricity consumption obtained in the previous step includes the electricity consumption for production and the electricity consumption for life of the staff, and since part of the electricity consumption is consumed in other energy consumption devices such as a lathe, a water pump, a high-pressure water gun and the like, in order to facilitate the processing of the rework and production replication data in the subsequent step, other energy sources in the two types of electricity consumption data need to be converted into electricity data in the step. Typically, for example, a water pump can convert all energy consumption related to the water pump into power data according to data such as usage time, power, water consumption and the like of the water pump, and further, in order to improve accuracy of converting into the power data, it is necessary to obtain real power consumption of equipment instead of equivalent power consumption by dividing by work efficiency of corresponding equipment in the data conversion process.

And finally, displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time. Typically, the progress display unit 33 for displaying the rework progress calculated based on the power data on the side of the virtual prism in real time includes:

the system is used for acquiring full-rated power data corresponding to each rework data category;

the system comprises a data processing unit, a data processing unit and a data processing unit, wherein the data processing unit is used for calculating the percentage of target power data relative to full-rated power data in each rework data category to obtain a rework progress corresponding to a percentage result;

the system comprises a virtual prism, a rework progress image and a data processing module, wherein the virtual prism is used for generating a rework progress image;

in implementation, the virtual prisms with the number of side faces equal to the type of the rework data are constructed through common three-dimensional drawing software, different rework data types to be displayed are defined for each side face of the virtual prisms, meanwhile, calculation is carried out on each rework data based on current data, and the percentage of the rework data is displayed in the form of corresponding side face area percentage, so that the rework progress of the rework data is reflected. An exemplary virtual prism is shown in fig. 2, which shows different rework schedules for a rework data category with a preset data size of 6. In consideration of the actual display effect, the virtual prism is displayed in a mode of slowly rotating along the axis, so that different types of rework progress can be displayed on different sides, and the rework progress display effect of a target enterprise is improved.

Furthermore, corresponding operations are executed on the data acquisition subunit, the progress determination subunit and the progress refreshing subunit at preset intervals, so that the rework progress displayed by the virtual prism can represent the current latest condition, and the real-time performance of rework progress display of a target enterprise is improved.

Considering that the mode that the virtual prisms are displayed in the side areas cannot display detailed rework data types and detailed data, a technical scheme for acquiring and displaying rework codes is also provided. Specifically, the image code generating unit 34 is configured to calculate the rework progress of each side surface of the virtual prism at regular time, and display the rework code of the corresponding target enterprise obtained based on the calculation result on the bottom surface of the virtual prism, and includes:

the progress acquiring subunit is used for acquiring the rework progress of each side surface on the virtual prism at preset intervals, and generating a rework overall data set of the corresponding target enterprise by combining the rework data category corresponding to each side surface;

the progress calculation operator unit is used for calculating the rework progress values of the corresponding target enterprises in the rework plan data set according to different weights of the rework data types;

and the graph code drawing subunit is used for obtaining the multiplex code corresponding to the target enterprise through a two-dimensional code generation algorithm according to the obtained multiplex progress value and the enterprise information of the target enterprise.

In implementation, the rework progress (typically percentage data) of each side surface of the virtual prism is calculated regularly, and then the rework codes of the corresponding target enterprises obtained based on the calculation results are displayed on one or two bottom surfaces of the prism. Thus, a user who needs detailed rework data can obtain detailed content of detailed rework progress through scanning the multidimensional codes.

The sequence numbers in the above embodiments are merely for description, and do not represent the sequence of the assembly or the use of the components.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (4)

1. The method for generating the dynamic duplicate code based on the power data is characterized by comprising the following steps of:

constructing a virtual prism according to the rework data type of the target enterprise;

obtaining rework data of a target enterprise, and converting the rework data into electric power data;

displaying the rework progress calculated based on the electric power data on the side surface of the virtual prism in real time;

calculating the rework progress of each side surface of the virtual prism at regular time, and displaying a rework code of a corresponding target enterprise obtained based on a calculation result on the bottom surface of the virtual prism;

wherein each side of the virtual prism corresponds to one rework data category;

the virtual prism is constructed according to the rework data type of the target enterprise, and the method comprises the following steps:

determining the rework data type of the target enterprise;

constructing an initial virtual prism, and adjusting the number of side faces of the initial virtual prism based on the type of rework data to obtain a virtual prism with the number of side faces consistent with the type of the rework data;

wherein, show the rework progress that obtains based on electric power data calculation in real time on the side of virtual prism includes:

step one, acquiring full-scale power data corresponding to each rework data category;

calculating the percentage of the target power data relative to the full-rated power data in each rework data category to obtain a rework progress corresponding to a percentage result;

refreshing a rework progress image on the side face of the virtual prism corresponding to the target power data based on the obtained rework progress;

executing the contents of the first step to the third step at preset intervals;

the timing calculation of the rework progress of each side surface of the virtual prism, and the display of the rework codes of the corresponding target enterprises obtained based on the calculation results on the bottom surface of the virtual prism, include:

the reworking progress of each side face on the virtual prism is obtained at preset intervals, and a reworking overall data set corresponding to a target enterprise is generated by combining the reworking data types corresponding to the side faces;

calculating the rework progress values of corresponding target enterprises in the rework plan data set according to different weights of each rework data category;

and according to the obtained rework progress value, combining enterprise information of the target enterprise and obtaining a rework code corresponding to the target enterprise through a two-dimensional code generation algorithm.

2. The method for generating the dynamic rework code based on the power data according to claim 1, wherein the obtaining the rework data of the target enterprise and converting the rework data into the power data includes:

establishing a corresponding relation between the rework data and the power data based on the property of the rework data;

and acquiring the rework data of the target enterprise, and converting each type of rework data into electric power data according to the established corresponding relation.

3. A dynamic duplicate code generation device based on power data, the device comprising:

the virtual construction unit is used for constructing a virtual prism according to the rework data type of the target enterprise;

the data conversion unit is used for acquiring the rework data of the target enterprise and converting the rework data into electric power data;

the progress display unit is used for displaying the rework progress calculated based on the electric power data on the side face of the virtual prism in real time;

the image code generating unit is used for calculating the rework progress of each side surface of the virtual prism at regular time and displaying the rework codes of the corresponding target enterprises obtained based on the calculation result on the bottom surface of the virtual prism;

wherein each side of the virtual prism corresponds to one rework data category;

the virtual building unit comprises:

the data classification subunit is used for determining the rework data type of the target enterprise;

the prism construction subunit is used for constructing an initial virtual prism, and adjusting the number of the side faces of the initial virtual prism based on the type of the rework data to obtain a virtual prism with the number of the side faces consistent with the type of the rework data;

the progress display unit includes:

the data acquisition subunit is used for acquiring full-scale power data corresponding to each rework data category;

the progress determining subunit is used for calculating the percentage of the target power data relative to the full-rated power data in each rework data category to obtain the rework progress corresponding to the percentage result;

the progress refreshing subunit is used for refreshing the rework progress image on the side face of the virtual prism corresponding to the target electric power data based on the obtained rework progress;

controlling the data acquisition subunit, the progress determination subunit and the progress refreshing subunit to execute corresponding operations at preset intervals;

the graph code generating unit comprises:

the progress acquiring subunit is used for acquiring the rework progress of each side surface on the virtual prism at preset intervals, and generating a rework overall data set of the corresponding target enterprise by combining the rework data types corresponding to each side surface;

the progress calculation operator unit is used for calculating the rework progress values of the corresponding target enterprises in the rework plan data set according to different weights of the rework data types;

and the graph code drawing subunit is used for obtaining the multiplex code corresponding to the target enterprise through a two-dimensional code generation algorithm according to the obtained multiplex progress value and the enterprise information of the target enterprise.

4. The power data-based dynamic duplicate code generation device according to claim 3, wherein the data conversion unit comprises:

the relation establishing subunit is used for establishing a corresponding relation between the rework data and the power data based on the property of the rework data;

and the data conversion subunit is used for acquiring the rework data of the target enterprise and converting each type of rework data into electric power data according to the established corresponding relation.

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