CN112528371A - Electrical design method for water treatment project - Google Patents

Abstract

The invention provides an electrical design method for water treatment engineering, which integrates a model selection principle used in design into a parameter matching table on the basis of manufacturer recommendation and a standard data manual, two states of a variable and a parameter are set in the matching table, when the content of the variable changes, the parameter is linked with the variable and automatically matched with external input data, rules are generated according to prefabricated drawings of different types of equipment, and finally, the data in the parameter matching table is combined with various drawing rules, all power distribution information in all equipment lists is listed in a preset system diagram table, and the drawing mode completed by the existing data is automatically identified, analyzed and matched, so that various repeated steps can be optimized, the defect of model selection carelessness or filling errors can be avoided, the working efficiency can be improved, and the working time can be saved.

Description

Electrical design method for water treatment project

Technical Field

The invention relates to the technical field of electrical design of water treatment engineering, in particular to an electrical design method of water treatment engineering.

Background

In the current electrical system design of water treatment engineering, in view of the fact that the selection rules of components and cables of a corresponding power distribution loop are relatively fixed during the design of an electrical low-voltage power distribution system, the design of a low-voltage power distribution system of a sewage treatment project is generally made, all process and non-process electric equipment are operated repeatedly according to the quantity often according to an electrical selection principle, the repeated workload is dozens or even hundreds of times, and finally, the results of the selection are arranged and combined according to the process of an electrical product to form a system drawing, so that the operation process is relatively mechanical in the whole view, which is not beneficial to improving the convenience and the reliability of the electrical system design of the water treatment project.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an electrical design method of a water treatment project, which comprises the steps of combing an electric equipment table, filling equipment names, equipment numbers, equipment powers and equipment classifications in professional funding contents of corresponding electric equipment in the electric equipment table line by line according to preset requirements, forming a list of the corresponding electric equipment table, calculating parameter configuration, automatically matching calculation parameters corresponding to the electric equipment table in an existing parameter matching table, setting conditions of an electrical system, setting necessary conditions generated by the electrical system, checking calculation results, automatically calculating common parameters of project electrical load calculation through the calculation table, automatically recommending the capacity and the installation number of transformers to be selected, calculating the average load rate of the transformers and the guarantee rate of second-level and above loads, finally, recommending the number and position information of the power distribution rooms to be set, generating a design drawing, uploading the calculation results to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation results with component calculation books in the server by using a server program to obtain a corresponding power distribution loop, combining and splicing the power distribution loop into a finished electrical cabinet system diagram according to the modulus of the electrical cabinets, and finally exporting the electrical cabinet system diagram to a CAD file; the method is characterized in that a model selection principle used in the design is integrated into a parameter matching table on the basis of manufacturer recommendation and a standard data manual, two states of variables and parameters are set in the matching table, when the content of the variables changes, the parameters are linked with the variables and automatically matched with external input data, rules are generated according to different types of equipment prefabrication drawings, and finally the data in the parameter matching table and various drawing rules are combined together, all power distribution information in all equipment lists are listed in a preset system diagram table, and the drawing mode completed by automatically identifying, analyzing and matching the existing data can optimize various repeated steps, avoid the defect of model selection carelessness or wrong filling, improve the working efficiency and save the working time.

The invention provides an electrical design method for a water treatment project, which is characterized by comprising the following steps:

step S1, combing the electric equipment list, and filling the equipment name, the equipment number, the equipment power and the equipment classification in the professional funding content of the corresponding electric equipment in the electric equipment list line by line according to the preset requirements so as to form a corresponding list of the electric equipment list;

step S2, calculating parameter configuration, which is to automatically match the corresponding calculation parameters in the electric equipment table in the existing parameter matching table;

step S3, setting conditions for the electrical system, which sets the necessary conditions for the electrical system to generate;

step S4, checking the calculation result, after the steps S1-S3 are finished, automatically calculating the common parameters of the project electrical load calculation through a calculation table, automatically recommending the capacity and the installation number of the transformer to be selected, calculating the average load rate of the transformer and the guarantee rate of the secondary and above loads, and finally recommending the number and the position information of the distribution rooms to be set;

step S5, generating a design drawing, uploading the calculation result of the step S4 to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding power distribution loop, combining and splicing the power distribution loop into a finished electrical cabinet system diagram according to the modulus of the electrical cabinet, and finally exporting the electrical cabinet system diagram to a CAD file;

further, in step S2, calculating a parameter configuration, where automatically matching, in an existing parameter matching table, a corresponding calculated parameter in the electric device table specifically includes:

automatically matching calculation parameters of required coefficients, power factors and tangent values corresponding to the electric equipment table in an existing parameter matching table, and matching all related parameters from the parameter matching table after the equipment type is selected;

further, in step S3, the condition setting is performed on the electrical system, and the setting of the requirements generated by the electrical system specifically includes:

setting conditions of the electrical system, and setting key information of fire load attributes, power supply load grades, the codes of the affiliated power distribution rooms, the codes of the transformers and the codes of the secondary power distribution boxes generated by the electrical system, so that load distribution is performed according to the key information when an electrical system diagram is generated subsequently;

further, in the step S4, the calculation result check step automatically calculates the common parameters for the project electrical load calculation through the calculation table after the steps S1-S3 are completed, automatically recommends the transformer capacity and the number of installed transformers to be selected, calculates the average load rate of the transformers and the guarantee rate of the secondary and above loads, and finally recommends the number of the distribution rooms and the location information to be installed, and specifically includes:

checking the calculation result, after the steps S1-S3 are finished, automatically calculating the common parameters of the active power, the reactive power, the apparent power and the reactive compensation capacity of the project electrical load calculation through a calculation table, automatically recommending the transformer capacity and the installation quantity to be selected, calculating the average load rate of the transformer and the guarantee rate of the secondary and above loads, finally recommending the quantity and the position information of the distribution rooms to be set so as to judge whether the calculation result is reasonable, modifying the calculation result when the calculation result is not reasonable, and storing the calculation result after the calculation result is confirmed to be correct so as to serve as the generation basis of the electrical system;

further, in step S5, generating a design drawing, uploading the calculation result of step S4 to a server, generating an electrical load calculation table of a corresponding item, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding distribution circuit, combining and splicing the distribution circuits according to a modulus of an electrical cabinet to form a complete electrical cabinet system diagram, and finally exporting the electrical cabinet system diagram to a CAD file specifically includes:

generating a design drawing, uploading the calculation result of the step S4 to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program, filling selected information of rated current of the circuit breaker, transformer transformation ratio and cable section into a single loop module, simultaneously processing corresponding special equipment types according to a preset rule to respectively carry out double-loop distribution on the circuit from different transformer side feeder circuits, gathering equipment with the same regional secondary distribution box label in the equipment table and automatically generating a single-line system diagram, simultaneously distributing a corresponding main distribution loop at a primary low-voltage cabinet side to obtain a corresponding distribution loop, and then combining and splicing the distribution loops according to the modulus of the electrical cabinets to form a finished electrical cabinet system diagram, finally, exporting the electrical cabinet system diagram to a CAD file;

further, step S501, the generation server calls a low-voltage system diagram data interface through the API, loads the component calculation book and the electrical load calculation table to the memory by using the server program, analyzes the loaded electrical load calculation table by using the server program, and merges the devices under the same secondary distribution box by using the server program according to the attributes of the secondary distribution box to which the server program belongs;

step S502, classifying the equipment according to the power distribution room and the transformer, forming a data dictionary set corresponding to the transformer after classification, classifying each element of the data dictionary set corresponding to the transformer again according to the equipment type, and finally, classifying different types of sets of the transformer according to the power distribution room and the transformer;

step S503, counting the total amount of the equipment in each type, designing the number of the standby loops according to 20% of the number, and respectively carrying out logic processing on each equipment in different types one by one;

step S504, obtain the relevant parameter information meeting the component specification in the component calculation book according to the power of the apparatus, set up the corresponding data according to the type information, produce a component specification for the apparatus, according to the modulus of each cupboard 72E of the specification, verify whether the present data is equal to 72E strictly, meet and start a new cupboard information additionally, continue adding less than 72E, greater than 72E, carry on the operation of backspacing, and insert and make it become the spare module of modulus of 72E;

step S505, completing a component information data set of low-voltage distribution equipment, counting the total power of equipment to which each secondary distribution box belongs, circularly processing each secondary distribution box, searching a component calculation book according to the total power to obtain a corresponding component specification model, searching a component specification model corresponding to each equipment, and generating a component information set to which the secondary distribution box belongs;

step S506, the server program returns the low-voltage distribution equipment component information data set and the component information set to which the secondary distribution box belongs to the file generation server, the file generation server analyzes the data returned by the server program, the file generation server calls different drawing blocks to synthesize a low-voltage system drawing according to the data to divide the generated drawing calling an A2 drawing frame, the file generation server calls a secondary distribution box template, the component information set to which the secondary distribution box belongs is used for filling the template to generate a corresponding secondary distribution box drawing, and finally the generated drawing is stored in a new file.

Compared with the prior art, the electrical design method of the water treatment project comprises the steps of combing the electric equipment table, filling equipment names, equipment quantity, equipment power and equipment classification in professional investment promotion content of corresponding electric equipment in the electric equipment table line by line according to preset requirements to form a corresponding list of the electric equipment table, calculating parameter configuration, automatically matching corresponding calculation parameters in the electric equipment table in the existing parameter matching table, carrying out condition setting on an electric system, setting necessary conditions generated by the electric system, checking calculation results, automatically calculating common parameters of project electric load calculation through the calculation table, automatically recommending the capacity and installation quantity of transformers which are selected, calculating the average load rate of the transformers and the guarantee rate of secondary and above loads, and finally recommending the quantity and position information of distribution rooms which need to be set, finally, generating a design drawing, uploading the calculation result to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding distribution loop, combining and splicing the distribution loop into a finished electrical cabinet system diagram according to the modulus of the electrical cabinet, and finally exporting the electrical cabinet system diagram to a CAD (computer-aided design) file; the method is characterized in that a model selection principle used in the design is integrated into a parameter matching table on the basis of manufacturer recommendation and a standard data manual, two states of variables and parameters are set in the matching table, when the content of the variables changes, the parameters are linked with the variables and automatically matched with external input data, rules are generated according to different types of equipment prefabrication drawings, and finally the data in the parameter matching table and various drawing rules are combined together, all power distribution information in all equipment lists are listed in a preset system diagram table, and the drawing mode completed by automatically identifying, analyzing and matching the existing data can optimize various repeated steps, avoid the defect of model selection carelessness or wrong filling, improve the working efficiency and save the working time.

Drawings

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

Fig. 1 is a schematic flow chart of an electrical design method of a water treatment project provided by the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a schematic flow chart of the electrical design method of the water treatment project provided by the present invention is shown. The electrical design method of the water treatment project comprises the following steps:

step S1, combing the electric equipment list, and filling the equipment name, the equipment number, the equipment power and the equipment classification in the professional funding content of the corresponding electric equipment in the electric equipment list line by line according to the preset requirements so as to form a corresponding list of the electric equipment list;

step S2, calculating parameter configuration, which automatically matches the corresponding calculation parameter in the electric equipment table in the existing parameter matching table;

step S3, setting conditions for the electrical system, which sets the necessary conditions for the electrical system to generate;

step S4, checking the calculation result, after the steps S1-S3 are finished, automatically calculating the common parameters of the project electrical load calculation through a calculation table, automatically recommending the capacity and the installation number of the transformer to be selected, calculating the average load rate of the transformer and the guarantee rate of the secondary and above loads, and finally recommending the number and the position information of the distribution rooms to be set;

and S5, generating a design drawing, uploading the calculation result of the step S4 to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding power distribution loop, combining and splicing the power distribution loop into a finished electrical cabinet system diagram according to the modulus of the electrical cabinet, and finally exporting the electrical cabinet system diagram to a CAD file.

The beneficial effects of the above technical scheme are that: the electrical design method for the water treatment engineering is characterized in that a model selection principle used in design is integrated into a parameter matching table on the basis of manufacturer recommendation and a standard data manual, two states of variables and parameters are set in the matching table, when the content of the variables changes, the parameters are linked with the variables and automatically matched with external input data, rules are generated according to prefabricated drawings of different types of equipment, and finally the data in the parameter matching table and various drawing rules are combined together, all power distribution information in all equipment lists is listed in a preset system diagram form, and the drawing mode completed by automatically identifying, analyzing and matching existing data can optimize various repeated steps, avoid the defect of model selection carelessness or filling errors, improve the working efficiency and save the working time.

Preferably, in step S2, the calculating the parameter configuration, wherein automatically matching the corresponding calculated parameter in the electric device table in the existing parameter matching table specifically includes:

in the existing parameter matching table, the corresponding calculation parameters of the required coefficient, the power factor and the tangent value in the electric equipment table are automatically matched, and after the equipment type is selected, all the related parameters are matched from the parameter matching table.

Preferably, in step S3, condition setting is performed on the electrical system, and the setting of the necessary conditions generated by the electrical system specifically includes:

and carrying out condition setting on the electrical system so as to set key information of fire protection load attribute, power supply load grade, the code number of the power distribution room, the code number of the transformer and the code number of the secondary power distribution box generated by the electrical system, thereby facilitating load distribution according to the key information when an electrical system diagram is generated subsequently.

Preferably, in step S4, the calculation result check automatically calculates the common parameters for calculating the project electrical load through the calculation table after the steps S1-S3 are completed, automatically recommends the transformer capacity and the number of installed transformers to be selected, calculates the average load rate of the transformers and the guarantee rate of the secondary and above loads, and finally recommends the number of distribution rooms and the location information to be installed, and specifically includes:

and checking the calculation result, namely after the steps S1-S3 are finished, automatically calculating the common parameters of the active power, the reactive power, the apparent power and the reactive compensation capacity of the project electrical load calculation through a calculation table, automatically recommending the transformer capacity and the installation quantity to be selected, calculating the average load rate of the transformer and the guarantee rate of the secondary and above loads, finally recommending the quantity and the position information of the distribution rooms to be set so as to judge whether the calculation result is reasonable, modifying the calculation result when the calculation result is not reasonable, and storing the calculation result after the calculation result is confirmed to be correct so as to serve as the generation basis of the electrical system.

Preferably, in step S5, the generating of the design drawing uploads the calculation result of step S4 to the server, generates an electrical load calculation table of a corresponding item, matches the uploaded calculation result with a component calculation book in the server by using a server program, so as to obtain a corresponding power distribution loop, combines and splices the power distribution loop into a completed electrical cabinet system diagram according to a modulus of an electrical cabinet, and finally exports the electrical cabinet system diagram to a CAD file specifically includes:

generating a design drawing, uploading the calculation result of the step S4 to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program, filling selected information of rated current of the circuit breaker, transformer transformation ratio and cable section into a single loop module, simultaneously processing corresponding special equipment types according to a preset rule to respectively carry out double-loop distribution on the circuit from different transformer side feeder circuits, gathering equipment with the same regional secondary distribution box label in the equipment table and automatically generating a single-line system diagram, simultaneously distributing a corresponding main distribution loop at a primary low-voltage cabinet side to obtain a corresponding distribution loop, and then combining and splicing the distribution loops according to the modulus of the electrical cabinets to form a finished electrical cabinet system diagram, and finally exporting the electrical cabinet system diagram to a CAD file.

Preferably, in step S501, the generation server calls a low-voltage system diagram data interface through the API, loads the component calculation book and the electrical load calculation table to the memory by using the server program, analyzes the loaded electrical load calculation table by using the server program, and merges the devices under the same secondary distribution box by using the server program according to the attributes of the secondary distribution box to which the server program belongs;

step S502, classifying the equipment according to the power distribution room and the transformer, forming a data dictionary set corresponding to the transformer after classification, classifying each element of the data dictionary set corresponding to the transformer again according to the equipment type, and finally, classifying different types of sets of the transformer according to the power distribution room and the transformer;

step S503, counting the total amount of the equipment in each type, designing the number of the standby loops according to 20% of the number, and respectively carrying out logic processing on each equipment in different types one by one;

step S504, obtain the relevant parameter information meeting the component specification in the component calculation book according to the power of the apparatus, set up the corresponding data according to the type information, produce a component specification for the apparatus, according to the modulus of each cupboard 72E of the specification, verify whether the present data is equal to 72E strictly, meet and start a new cupboard information additionally, continue adding less than 72E, greater than 72E, carry on the operation of backspacing, and insert and make it become the spare module of modulus of 72E;

step S505, completing a component information data set of low-voltage distribution equipment, counting the total power of equipment to which each secondary distribution box belongs, circularly processing each secondary distribution box, searching a component calculation book according to the total power to obtain a corresponding component specification model, searching a component specification model corresponding to each equipment, and generating a component information set to which the secondary distribution box belongs;

step S506, the server program returns the low-voltage distribution equipment component information data set and the component information set to which the secondary distribution box belongs to the file generation server, the file generation server analyzes the data returned by the server program, the file generation server calls different drawing blocks to synthesize a low-voltage system drawing according to the data to divide the generated drawing calling an A2 drawing frame, the file generation server calls a secondary distribution box template, the component information set to which the secondary distribution box belongs is used for filling the template to generate a corresponding secondary distribution box drawing, and finally the generated drawing is stored in a new file.

It can be known from the content of the above embodiment that the electrical design method of the water treatment project includes combing the electric equipment table, filling the equipment name, the equipment number, the equipment power and the equipment classification in the professional investment content of the corresponding electric equipment in the electric equipment table line by line according to the preset requirements, forming the corresponding list of the electric equipment table, calculating the parameter configuration, automatically matching the corresponding calculation parameters in the electric equipment table in the existing parameter matching table, performing condition setting on the electrical system, setting the necessary conditions generated by the electrical system, checking the calculation result, automatically calculating the common parameters of the project electrical load calculation through the calculation table, automatically recommending the capacity and the installation number of the transformer which should be selected, calculating the average load rate of the transformer and the guarantee rate of the second-level and above loads, and finally recommending the number and the position information of the distribution rooms which need to be set, finally, generating a design drawing, uploading the calculation result to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding distribution loop, combining and splicing the distribution loop into a finished electrical cabinet system diagram according to the modulus of the electrical cabinet, and finally exporting the electrical cabinet system diagram to a CAD (computer-aided design) file; the method is characterized in that a model selection principle used in the design is integrated into a parameter matching table on the basis of manufacturer recommendation and a standard data manual, two states of variables and parameters are set in the matching table, when the content of the variables changes, the parameters are linked with the variables and automatically matched with external input data, rules are generated according to different types of equipment prefabrication drawings, and finally the data in the parameter matching table and various drawing rules are combined together, all power distribution information in all equipment lists are listed in a preset system diagram table, and the drawing mode completed by automatically identifying, analyzing and matching the existing data can optimize various repeated steps, avoid the defect of model selection carelessness or wrong filling, improve the working efficiency and save the working time.

Claims (6)

1. The electrical design method of the water treatment project is characterized by comprising the following steps:

step S1, combing the electric equipment list, and filling the equipment name, the equipment number, the equipment power and the equipment classification in the professional funding content of the corresponding electric equipment in the electric equipment list line by line according to the preset requirements so as to form a corresponding list of the electric equipment list;

step S2, calculating parameter configuration, which is to automatically match the corresponding calculation parameters in the electric equipment table in the existing parameter matching table;

step S3, setting conditions for the electrical system, which sets the necessary conditions for the electrical system to generate;

step S4, checking the calculation result, after the steps S1-S3 are finished, automatically calculating the common parameters of the project electrical load calculation through a calculation table, automatically recommending the capacity and the installation number of the transformer to be selected, calculating the average load rate of the transformer and the guarantee rate of the secondary and above loads, and finally recommending the number and the position information of the distribution rooms to be set;

and S5, generating a design drawing, uploading the calculation result of the step S4 to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding power distribution loop, combining and splicing the power distribution loops into a finished electrical cabinet system diagram according to the modulus of the electrical cabinets, and finally exporting the electrical cabinet system diagram to a CAD file.

2. The electrical design method of water treatment engineering according to claim 1, characterized in that:

in step S2, the step of calculating parameter configuration, where automatically matching, in an existing parameter matching table, the calculation parameters corresponding to the electric device table specifically includes:

in the existing parameter matching table, automatically matching the calculation parameters of the needed coefficient, the power factor and the tangent value corresponding to the electric equipment table, and matching all the related parameters from the parameter matching table after the equipment type is selected.

3. The electrical design method of water treatment engineering according to claim 2, characterized in that:

in step S3, the condition setting is performed on the electrical system, and the setting of the requirement generated by the electrical system specifically includes:

and carrying out condition setting on the electrical system so as to set key information of fire protection load attribute, power supply load grade, the code number of the power distribution room, the code number of the transformer and the code number of the secondary power distribution box generated by the electrical system, thereby facilitating load distribution according to the key information when an electrical system diagram is generated subsequently.

4. The electrical design method of water treatment engineering according to claim 3, characterized in that:

in step S4, the calculation result is checked, after the steps S1-S3 are completed, common parameters for calculating the electrical loads of the project are automatically calculated through a calculation table, the capacity and the number of installed transformers to be selected are automatically recommended, the average load rate of the transformers and the guarantee rate of the secondary and above loads are calculated, and finally, the recommended number and position information of the distribution rooms to be installed specifically include:

and checking the calculation result, namely after the steps S1-S3 are finished, automatically calculating the common parameters of the active power, the reactive power, the apparent power and the reactive compensation capacity of the project electrical load calculation through a calculation table, automatically recommending the transformer capacity and the installation quantity to be selected, calculating the average load rate of the transformer and the guarantee rate of the secondary and above loads, finally recommending the quantity and the position information of the distribution rooms to be set so as to judge whether the calculation result is reasonable, modifying the calculation result when the calculation result is not reasonable, and storing the calculation result after the calculation result is confirmed to be correct so as to serve as the generation basis of the electrical system.

5. The electrical design method of water treatment engineering according to claim 4, characterized in that:

in step S5, generating a design drawing, uploading the calculation result of step S4 to a server, generating an electrical load calculation table of a corresponding item, matching the uploaded calculation result with a component calculation book in the server by using a server program to obtain a corresponding distribution circuit, combining and splicing the distribution circuits according to the modulus of the electrical cabinets to form a complete electrical cabinet system diagram, and finally exporting the electrical cabinet system diagram to a CAD file specifically includes:

generating a design drawing, uploading the calculation result of the step S4 to a server, generating an electrical load calculation table of a corresponding project, matching the uploaded calculation result with a component calculation book in the server by using a server program, filling selected information of rated current of the circuit breaker, transformer transformation ratio and cable section into a single loop module, simultaneously processing corresponding special equipment types according to a preset rule to respectively carry out double-loop distribution on the circuit from different transformer side feeder circuits, gathering equipment with the same regional secondary distribution box label in the equipment table and automatically generating a single-line system diagram, simultaneously distributing a corresponding main distribution loop at a primary low-voltage cabinet side to obtain a corresponding distribution loop, and then combining and splicing the distribution loops according to the modulus of the electrical cabinets to form a finished electrical cabinet system diagram, and finally exporting the electrical cabinet system diagram to a CAD file.

6. The electrical design method of water treatment engineering according to claim 5, characterized in that:

in step S5, the method further includes:

step S501, a generation server calls a low-voltage system diagram data interface through an API (application program interface), a component calculation book and an electrical load calculation table are loaded to a memory by using a server program, the loaded electrical load calculation table is analyzed by using the server program, and equipment under the same secondary distribution box is merged by using the server program according to the attribute of the secondary distribution box;

step S502, classifying the equipment according to the power distribution room and the transformer, forming a data dictionary set corresponding to the transformer after classification, classifying each element of the data dictionary set corresponding to the transformer again according to the equipment type, and finally, classifying different types of sets of the transformer according to the power distribution room and the transformer;

step S503, counting the total amount of the equipment in each type, designing the number of the standby loops according to 20% of the number, and respectively carrying out logic processing on each equipment in different types one by one;

step S504, obtain the relevant parameter information meeting the component specification in the component calculation book according to the power of the apparatus, set up the corresponding data according to the type information, produce a component specification for the apparatus, according to the modulus of each cupboard 72E of the specification, verify whether the present data is equal to 72E strictly, meet and start a new cupboard information additionally, continue adding less than 72E, greater than 72E, carry on the operation of backspacing, and insert and make it become the spare module of modulus of 72E;

step S505, completing a component information data set of low-voltage distribution equipment, counting the total power of equipment to which each secondary distribution box belongs, circularly processing each secondary distribution box, searching a component calculation book according to the total power to obtain a corresponding component specification model, searching a component specification model corresponding to each equipment, and generating a component information set to which the secondary distribution box belongs;

step S506, the server program returns the low-voltage distribution equipment component information data set and the component information set to which the secondary distribution box belongs to the file generation server, the file generation server analyzes the data returned by the server program, the file generation server calls different drawing blocks to synthesize a low-voltage system drawing according to the data to divide the generated drawing calling an A2 drawing frame, the file generation server calls a secondary distribution box template, the component information set to which the secondary distribution box belongs is used for filling the template to generate a corresponding secondary distribution box drawing, and finally the generated drawing is stored in a new file.

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