CN113258676A - Power monitoring system interactively integrated with BIM (building information modeling) model and interactive integration method - Google Patents

Abstract

The invention discloses a power monitoring system interactively integrated with a BIM (building information modeling) model and an interactive integration method, wherein the power monitoring system comprises a generation module, a matching module and an output module, the generation module converts the BIM model generated in a construction or design stage into a three-dimensional model, the matching module matches an equipment three-dimensional model with equipment in the power monitoring system according to a standard with consistent names and establishes a mapping relation, and the output module interactively integrates the three-dimensional model with the power monitoring system according to the mapping relation; according to the invention, the ready-made BIM is directly used for generating the three-dimensional model, the modeling workload is greatly compressed, the three-dimensional model and the equipment database are named and integrated through the same naming rule, and the computer can realize the rapid matching and interactive integration of the three-dimensional model and the power monitoring system based on the principle of the same name, so that the interactive integration efficiency is greatly improved, and the workload is reduced; and the matching rule is simple, the naming rule is simple, the calculation amount of a computer is reduced to the maximum extent, and the matching efficiency and accuracy are improved.

Description

Power monitoring system interactively integrated with BIM (building information modeling) model and interactive integration method

Technical Field

The invention relates to the technical field of power control equipment, in particular to a power monitoring system interactively integrated with a BIM (building information modeling) model and an interactive integration method.

Background

In recent years, along with the development requirements of refined, intelligent and efficient management in the field of power supply dispatching of China railways, the requirement on human-computer interaction of PSCADA is continuously increased. The HMI module is one of the most important parts in the PSCADA system, a monitoring picture graph of the HMI module is displayed in a two-dimensional logic graph mode at present, and telemetering, telecommand and other information of the power supply equipment received by a PSCADA background is displayed on an equipment icon. In order to improve the interaction capability of the HMI module of the PSCADA system, a feasible approach is to introduce a three-dimensional presentation and interaction technology.

The conventional three-dimensional HMI integration scheme adopted by the PSCADA system at present is to manually establish a three-dimensional model, process and convert model data, integrate the model data into the system and then manually configure a data mapping relation. This approach requires a large amount of resources to be invested in carrying out the operations of mapping, acquisition, three-dimensional modeling and model configuration, and it is difficult to ensure the data accuracy and the data mapping relationship accuracy.

Disclosure of Invention

Aiming at the defect of large interactive workload of a power control system in the prior art, the invention discloses a power monitoring system interactively integrated with a BIM (building information modeling) model.

The invention realizes the aim through the following technical scheme:

a BIM model and power monitoring system interactive integration method comprises the following steps:

s1, formulating a naming rule according to the actual working condition;

s2, acquiring a BIM (building information model) generated by each power supply device in a construction or design stage, generating a three-dimensional model of each power supply device based on the BIM, naming the three-dimensional model of each power supply device based on the naming rule in the step S1 to generate a three-dimensional model library containing all the power supply devices, and generating a first name list related to the three-dimensional model;

s3, acquiring each power supply equipment database in the power monitoring system, splicing and recombining data in the power supply equipment database based on the naming rule in the step S1, and acquiring a second name list related to the power supply equipment;

s4, inputting the first name list and the second name list in the steps S2 and S3 into a matching module, and enabling the matching module to match the three-dimensional model base with the power supply equipment database one by one according to the principle that the names are the same to generate a unique mapping relation;

and S5, integrating the three-dimensional models in the three-dimensional model library into the power monitoring system according to the mapping relation in the step S4 by the output module, and finally outputting the three-dimensional power monitoring system integrated with the three-dimensional models.

Preferably, the mapping relationship in step S4 includes a necessary mapping relationship between necessary matching items and an unnecessary mapping relationship between unnecessary matching items; the step S4 further includes an error detection procedure for checking the necessary mapping relationship.

Preferably, the error detection procedure comprises the steps of:

b1, extracting a first data list and a second data list containing all unmatched object data from the first name list and the second name list respectively;

b2, according to the remark content of each item, screening out a second character string which must match the item from the second data list in the step B1, then checking a corresponding first character string in the first data list according to the second character string, and modifying the first character string according to the naming rule;

b3, repeating the step B2 to complete the modification of all the data of the items which need to be matched in the first name list, and then reintroducing the modified first name list into the matching module for automatic matching;

b4, repeating the steps B1 to B3 until the data in the first name list and the second name list are completely matched.

Preferably, if there is no second string in the second data list of step B2 that must match the item, the subsequent steps are terminated or continued.

Preferably, in step S5, an index list reflecting the mapping relationship between the first name list and the second name list is further created and stored in the database; the index list is a HASH index list.

Preferably, the naming rule in step S1 includes a device naming expression, a component naming expression, and a subcomponent naming expression, where the device naming expression is: device name + running number;

the component naming expression is: the device name expression + component name + operation number;

the expression of the subcomponent grouping naming rule is: the component name expression + subcomponent name + run number.

Correspondingly, the invention discloses an electric power monitoring system interactively integrated with a BIM (building information modeling) model, which comprises a generating module, a matching module and an output module, wherein the generating module is used for generating a corresponding three-dimensional model according to the BIM model of power supply equipment and forming a three-dimensional model library of all the power supply equipment;

the matching module retrieves the three-dimensional model library and the power monitoring system equipment library, matches the three-dimensional model library with the power monitoring system equipment library according to a preset matching rule, and establishes a unique mapping relation between two objects which are successfully matched;

and the output module embeds each three-dimensional model in the three-dimensional model library into the power monitoring system according to the mapping relation established by the matching module, and finally outputs the power monitoring system integrated with the three-dimensional models.

Preferably, the generating module comprises a BIM generating module and a power monitoring system generating module, and the BIM generating module comprises a BIM structure and data reading plug-in and a first device and component list generating module which are respectively used for importing the BIM model; the power monitoring system generating module comprises a second equipment and component list generating module;

the matching module comprises a data analysis module for receiving the relevant data of the generation module and a data matching analysis module for matching the data;

the output module comprises a mapping result management module for receiving the matching result and an index generation module for generating an index list and interactively integrating.

Preferably, the power monitoring system generating module further includes a necessary item setting module, and the necessary item setting module is configured to manage the output result of the second device and component list generating module, and mark a necessary matching item mark therein.

Preferably, the output end of the mapping result management module is respectively connected with the matching unsuccessful output module and the successful matching output module;

the matching unsuccessful output module is used for managing and outputting all unsuccessful matching items and generating a corresponding list;

and the successful matching output module is used for managing all successful matching items and mapping relations thereof. Compared with the prior art, the invention has the following beneficial effects:

1. the power monitoring system comprises a generation module, a matching module and an output module, wherein the generation module converts a BIM (building information modeling) model into a corresponding three-dimensional model, the matching module matches the three-dimensional model with the power monitoring system according to a preset naming rule and establishes a mapping relation, and finally the output module realizes interactive integration of the three-dimensional model and the power monitoring system according to the mapping relation;

the invention also discloses a corresponding interactive integration method, firstly formulating a naming rule according to the actual working condition, then extracting the BIM generated in the construction stage or the equipment design stage through a generating module, converting the BIM into a corresponding three-dimensional model, and naming each three-dimensional model according to the naming rule after the model conversion is finished; meanwhile, extracting a power supply equipment database from the motor monitoring system, and recombining the inlet and outlet of the power supply equipment database according to a naming rule; finally, a mapping relation is established between the three-dimensional model and a power supply equipment database according to the rule with the same name, and finally the three-dimensional model and the power monitoring system are integrated in an interactive mode through an output module according to the mapping relation;

compared with the prior art, the method has the advantages that the three-dimensional model is generated directly through the BIM model formed in the construction or design stage, on one hand, the data source is wide, and meanwhile, the data accuracy is high; on the other hand, the modeling time and workload of the BIM can be greatly reduced by directly adopting the ready-made BIM, so that the integration interaction efficiency of the equipment is improved;

compared with the mode of manually mapping by investing a large amount of resources and manually drawing a three-dimensional model through mapping data in the prior art, due to the reasons of resources, technology and the like, a mapping personnel can not disassemble the equipment for mapping, so that the personnel mainly map the whole equipment, but the equipment has large volume, is extremely inconvenient to map and cannot ensure the mapping accuracy, and the primary mapping and matching work of parts and subcomponents cannot be basically completed through the mode;

the BIM model generated in the construction or design stage is from an initial original file, so that the precision is higher, the refinement degree of the BIM is higher, the sizes of components and subcomponents can be accurately reflected, the working efficiency can be improved by directly applying the files, and the corresponding matching relationship between the components and the subcomponents can be quickly and accurately established, so that the invention realizes higher-level interactive matching by skillfully applying the BIM model and improves the monitoring performance of the power monitoring system; the BIM software also has a rich set of additional functions,

secondly, the three-dimensional model and related data in the equipment database are named and integrated through a unified naming rule, and a corresponding first name list and a corresponding second name list are formed, the names of the same part in the first name list and the second name list are necessarily the same because the naming rule is the same, and the matching between the three-dimensional model and the power monitoring system can be realized through the computer by quickly searching the matched same names;

in addition, the invention can realize matching and mapping only by name, thus not only the data volume of the computer needing to be searched and matched is obviously reduced, but also the operation matching speed of the computer can be effectively accelerated; meanwhile, compared with a manual matching mode, the method can release workers from repeated labor to the maximum extent, and improve matching efficiency;

2. according to the invention, the generating module of the power and power monitoring system also comprises a necessary item setting module for setting a necessary matching item, and through the module, a worker can independently note important equipment as the necessary matching item in the process of generating the second name list, so that the interactive integration quality of the system can be improved, and meanwhile, a computer can automatically read the necessary matching item according to the setting in the later period, thereby avoiding the low efficiency and the omission of manually searching the necessary matching item, and further improving the working efficiency and the accuracy of the system.

3. According to the invention, the output end of the mapping result management module is respectively connected with the matching unsuccessful output module and the matching successful output module, and the matching results are automatically distinguished through the modules, so that the rapid and accurate work of the subsequent modules can be ensured, the low efficiency and the missing of searching can be avoided, and the working efficiency and the accuracy of the system can be further improved.

4. The invention also comprises an error detection program which must match items, and the detection program ensures that key monitoring components in the power monitoring system are always in a monitoring state, thereby ensuring the integrity of monitoring information;

5. the invention also establishes an index list of the mapping relation between the first name list and the second name list, stores the index list in the database, establishes the index list by establishing the index list, stores the mapping relation between the first name list and the second name list in the database for a long time by the index list, and directly calls the index mark to inquire the related content by the computer when in use, thereby realizing the quick and repeated search of the mapping relation, shortening the retrieval time of the computer and improving the working efficiency.

6. The naming rules of the invention are respectively as follows: the method comprises the following steps of adding equipment names and operation numbers, adding a belonging equipment naming expression and a component name and an operation number, and adding a belonging component naming expression and a subcomponent name and an operation number; firstly, the naming rule is the same as the naming rule widely applied in the prior art, so that the compatibility of the naming rule with the existing system can be improved to the maximum extent, and the matching efficiency and accuracy are improved;

secondly, the method has stronger universality with the coding rule in the prior art, can reduce the adaptation time of workers, and simultaneously improves the efficiency of naming the workers and manually searching and matching.

Finally, the name rule combines the name and the operation number of the equipment, the existing data resources are utilized to the maximum extent, meanwhile, the name is concise, the workers can read and understand the data resources quickly, and the workers at different posts can use the data resources conveniently.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of the structure of each module of the present invention

FIG. 3 is a schematic flow chart of information according to the present invention;

fig. 4 is an interactive integration flowchart according to embodiment 1 of the present invention;

fig. 5 is a flowchart of interactive integration in embodiment 2 of the present invention.

Reference numerals: 1. the device comprises a generating module, 2, a matching module, 3, an output module, 11, a BIM generating module, 12, a power monitoring system generating module, 111, a BIM structure and data reading plug-in, 112, a first device and part list generating module, 121, a second device and part list generating module, 122, a necessary item setting module, 21, a data analyzing module, 22, a data matching analyzing module, 31, a mapping result management module, 32, an index generating module, 311, a matching unsuccessful output module, 312 and a successful matching output module.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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.

Embodiment mode 1

As shown in fig. 1 to 5, the present embodiment provides a power monitoring system interactively integrated with a BIM model, including a generating module 1, a matching module 2 and an output module 3; the generating module comprises a BIM generating module and an electric power monitoring system generating module, wherein the BIM module comprises a BIM structure and a data reading plug-in, corresponding development and compatibility transformation can be carried out according to different modeling software, and a worker introduces a BIM model generated in a construction or design stage through the reading plug-in; meanwhile, the BIM module also comprises a first equipment and component list generation module, and after the BIM is converted into a three-dimensional model, a worker names the three-dimensional model through the module and generates a first name list;

the power monitoring system generation module comprises a second device and attribute list generation module and a necessary item setting module, and a worker integrates and recombines a database extracted from the power monitoring system through the module and finally generates a second name list; meanwhile, the power monitoring system also comprises a necessary item setting module, and workers manage the second name list through the module and mark items which need to be matched;

the matching module comprises a data analyzing module and a data matching analyzing module, the first name list and the second name list generated by the first equipment and component list generating module and the second equipment and component list generating module are input into the data analyzing module, an analyzing result is output to the data matching analyzing module, and the data matching analyzing module judges whether the first name list and the second name list are matched according to a matching rule;

the output module comprises a mapping result management module and an index generation module, all matching results of the data matching analysis module are transmitted to the mapping result management module, the mapping result management module receives corresponding data and then transmits the data to the matching unfinished output module and the successfully matched output module respectively according to whether a mapping relation exists, the index generation module generates and stores an index list according to related parameters of the successfully matched output module, and the unmatched successful output module feeds the results back to workers for manual intervention at the later stage; and meanwhile, the index module also interactively integrates the three-dimensional model and the power monitoring system according to the related parameters successfully matched with the output module, and finally outputs the power monitoring system integrated with the three-dimensional model.

Embodiment mode 2

The present embodiment is another basic embodiment of the present invention, and discloses an interactive integration method of a BIM model and a power monitoring system, which includes the following steps:

s1, formulating a corresponding naming rule according to the actual operating condition, wherein in this embodiment, a coding naming rule combining the device name and the device internal number is adopted, and a naming expression for the whole device is: device name + running number; transformer equipment as numbered 1B, named transformer _ 1B; while the named expression for the component is: the device name expression + component name + operation number; for example, the iron core numbered 01 in the transformer, it should be named transformer _1B _ 01; for the sub-components under the components, the naming expressions of the sub-components are named expressions of the sub-components, sub-component names and running numbers, when the sub-components exist in multiple levels, the sub-components are sequentially extended backwards according to the dependency relationship, and meanwhile, for separators among different names, a \, or a, or;

s2, acquiring BIM models of various power supply equipment from a construction department or an equipment design and manufacture department, inputting the models into a generation module through BIM structures and data reading plug-ins compatible with the BIM models, and automatically converting the BIM models into three-dimensional models compatible with a power monitoring system by the generation module;

based on the naming rule in step S1, the staff names each generated power supply device and each component and sub-component included therein one by one through the first device and component list generation module, and after all the devices and components are named, the first device and component list generation module summarizes the names and generates a corresponding first name list;

s3, the power monitoring system generation module extracts a database of each power supply device from the power monitoring system, wherein the database comprises names of each device and each component, and based on the rule in the step S1, the staff reorganizes the names of each power supply device and each component through the second device and attribute list generation module to enable the names to meet the requirement of the naming rule; the second equipment and component list generation module summarizes the names and generates a corresponding second name list;

s4, the data analysis module in the matching module receives the first name list and the second name list in the steps S2 and S3;

reading the first-ranked name extracted from the second name list according to the sequence, marking the first-ranked name as a second character string, and taking the second character string as a comparison standard; scanning and reading the whole first name list, extracting a first name, recording the first name as a first character string, comparing the first character string with a second character string serving as a standard, and transmitting a comparison result to a data matching analysis module;

based on the principle that the names are the same, the data matching analysis module analyzes the related results, if the matching results are correct, a unique determined mapping relation is generated between the matched objects, and the related results are transmitted to the next program; meanwhile, a related result is fed back to the data analysis module, and the data analysis feedback result removes corresponding names in the first name list and the second name list;

repeating the steps until the matching of the whole second name list is completed;

and S5, inputting the mapping relation received from the step S4 into an index generating module by a mapping relation management module in the output module to generate an index list, establishing a corresponding calling relation between the three-dimensional model in the three-dimensional model library and the corresponding point of the power monitoring system by the index generating module according to the index list, repeating the operation until all the mapping relations are established, and thus finishing the interactive integration of the three-dimensional model and the power control system and finally outputting the three-dimensional power monitoring system integrated with the three-dimensional model.

Embodiment 3

As another preferred embodiment of the present invention, the present embodiment discloses an interactive integration method of a BIM model and a power monitoring system, including the following steps:

s2, acquiring BIM models of various power supply equipment from a construction department or an equipment design and manufacture department, inputting the models into a generation module through BIM structures and data reading plug-ins compatible with the BIM models, and automatically converting the BIM models into three-dimensional models compatible with a power monitoring system by the generation module;

based on the naming rule in step S1, the staff names each generated power supply device and each component and sub-component included therein one by one through the first device and component list generation module, and after all the devices and components are named, the first device and component list generation module summarizes the names and generates a corresponding first name list;

s3, the power monitoring system generation module extracts a database of each power supply device from the power monitoring system, wherein the database comprises names of each device and each component, and based on the rule in the step S1, the staff reorganizes the names of each power supply device and each component through the second device and attribute list generation module to enable the names to meet the requirement of the naming rule; the second equipment and component list generation module summarizes the names and generates a corresponding second name list;

the staff manages the second name list through the necessary item setting module and marks a necessary matching box in the second name list;

s4, the data analysis module in the matching module receives the first name list and the second name list in the steps S2 and S3;

reading the first-ranked name extracted from the second name list according to the sequence, marking the first-ranked name as a second character string, and taking the second character string as a comparison standard; scanning and reading the whole first name list, extracting a first name, recording the first name as a first character string, comparing the first character string with a second character string serving as a standard, and transmitting a comparison result to a data matching analysis module;

based on the principle that the names are the same, the data matching analysis module analyzes the related results, if the matching results are correct, a unique determined mapping relation is generated between the matched objects, and the related results are transmitted to the next program; meanwhile, a related result is fed back to the data analysis module, and the data analysis feedback result removes corresponding names in the first name list and the second name list;

if the matching is judged to be incorrect, the information is fed back to the data analysis module, the data analysis module extracts the subsequent names in the first name list to be compared again, and the steps are repeated until the matching is completed;

if the data analysis module scans the whole first name list and can not be matched correctly, the data matching module judges that the second character string can not be matched, terminates the matching operation and continues the matching of the next name;

repeating the steps until the matching of the whole second name list is completed;

s5, the mapping result management module receives the data sent by the data matching analysis module in the step S4, if the data is successfully matched, the data is distributed to the successful matching module, and if the data is determined to be an unsuccessful matching item, the data is distributed to the unsuccessful matching output module;

the matching unsuccessful output module distinguishes the data according to the first name list or the second name list from which the data comes and respectively outputs a first data list and a second data list which contain all unmatched object data;

s6, setting relevant marks of the modules according to the essential items, screening the essential matching items from the second data list in the step S5 by the staff, extracting second character strings of the essential matching items, checking each item of data in the first data list one by one according to the second character strings, screening corresponding items, extracting first character strings of the corresponding items, and checking and modifying the first character strings and the second character strings according to the naming rules in the step S1;

repeating the steps until the correction work of all the items which need to be matched in the second data list is completed; for the rest non-essential matching items, determining whether modification is needed according to actual working requirements, repeating the operation if the modification is needed, and directly skipping if the modification is not needed;

s7, the first name list and the second name list modified in the step S6 are reintroduced into a data analysis module in the matching module, the step S4 is repeated for automatic matching, and a corresponding result is output;

if the necessary matching items do not complete matching, repeating the steps from S5 to S7 to complete corresponding matching operation or directly modifying the mapping relation in a manner of manually establishing the mapping relation until all the necessary matching items establish a unique mapping relation;

and S8, inputting the mapping relations in the steps S5 to S7 into an index generating module by the successful matching output module, generating an index list by the index generating module according to the related data, establishing corresponding calling relations between the three-dimensional models in the three-dimensional model library and corresponding points of the power monitoring system by the index generating module according to the index list, repeating the operations until all the calling relations are established according to the mapping relations, and thus finishing the interactive integration of the three-dimensional models and the power control system and finally outputting the three-dimensional power monitoring system integrated with the three-dimensional models.

Compared with the prior art, the method has the advantages that the BIM generated in the construction stage is directly utilized to generate the corresponding three-dimensional model, so that the process of manually establishing the three-dimensional model is omitted, the BIM modeling time and workload are greatly reduced, and the working efficiency is improved; the BIM models of the construction unit and the design unit are higher in accuracy, and the accuracy of the models can be effectively improved;

secondly, the three-dimensional model and the related data in the equipment database are named and integrated through a unified naming rule, and a corresponding first name list and a corresponding second name list are formed, so that the names of the same part in the first name list and the second name list are necessarily the same, the computer can realize the matching between the three-dimensional model and the power monitoring system through quickly searching and matching the same names, the unique mapping relation can be established between the three-dimensional model and the power monitoring system through a set of naming rules, the result is reliable, the matching rule is simple, the matching program can be simplified to the maximum extent, the operation amount of the computer is reduced, and the matching efficiency is improved;

meanwhile, the naming rule adopted by the invention is a naming mode combining name and work code, which is the same as the naming mode of the common and practical equipment management mode in the prior art, so that the method has better application foundation, and workers can adapt quickly and perform various operations; meanwhile, the naming mode can generate unique names for complex equipment and components, the names are simple, the data volume of the first name list can be greatly reduced, the matching operation speed of a computer is improved, meanwhile, the naming mode is matched with an original file for generating the second name list, a worker does not need to name the equipment any more, and only recombination is needed to quickly generate the second name list, so that the matching efficiency can be further accelerated, and the workload of the worker is reduced.

Claims (10)

1. A BIM model and power monitoring system interactive integration method comprises the following steps:

s1, formulating a naming rule according to the actual working condition;

s2, the generation module acquires a BIM (building information model) generated by each power supply device in the construction or design stage, generates a three-dimensional model of each power supply device based on the BIM, generates a three-dimensional model library containing all the power supply devices by naming the three-dimensional model of each power supply device according to the naming rule in the step S1, and generates a first name list related to the three-dimensional model;

s3, the generation module extracts databases of power supply equipment in the power monitoring system, assembles and reorganizes data in the databases of the power supply equipment based on the naming rules of the step S1, and acquires a second name list of the power supply equipment;

s4, inputting the first name list and the second name list in the steps S2 and S3 into a matching module, and enabling the matching module to match the three-dimensional model base with the power supply equipment database one by one according to the principle that the names are the same to generate a unique mapping relation;

and S5, integrating the three-dimensional models in the three-dimensional model library into the power monitoring system according to the mapping relation in the step S4 by the output module, and finally outputting the three-dimensional power monitoring system integrated with the three-dimensional models.

2. The method of claim 1 for interactive integration of a BIM model with a power monitoring system, wherein: the mapping relationship in the step S4 includes a necessary mapping relationship between necessary matching items and an unnecessary mapping relationship between unnecessary matching items.

3. The method of claim 2 for interactive integration of a BIM model with a power monitoring system, wherein: the step S4 further includes an error detection procedure for checking a necessary mapping relationship, including the following steps:

b1, extracting a first data list and a second data list containing all unmatched object data from the first name list and the second name list respectively;

b2, screening a second character string of the item which needs to be matched from the second data list in the step S1, checking a corresponding first character string in the first data list according to the second character string, and modifying the first character string according to the naming rule;

b3, repeating the step S2 to complete the modification of all the data of the items which need to be matched in the first name list, and then reintroducing the modified first name list into the matching module for automatic matching;

b4, repeating the steps B1 to B3 until the data in the first name list and the second name list are completely matched.

4. The BIM model and power monitoring system interactive integration method of claim 3, wherein: if the second data list of step B2 does not have the second string of the necessary matching item, the subsequent steps are terminated or continued.

5. The method of claim 1 for interactive integration of a BIM model with a power monitoring system, wherein: an index list reflecting the mapping relation between the first name list and the second name list is also established in the step S5; the index list is a HASH index list.

6. The method of claim 1 for interactive integration of a BIM model with a power monitoring system, wherein: the naming rule in step S1 includes a device naming expression, a component naming expression, and a subcomponent naming expression, where the device naming expression is: device name + running number;

the component naming expression is: the device name expression + component name + operation number;

the expression of the subcomponent grouping naming rule is: the component name expression + subcomponent name + run number.

7. The power monitoring system interactively integrated with the BIM comprises a generating module (1), a matching module (2) and an output module (3), wherein the generating module (1) is used for generating a corresponding three-dimensional model according to the BIM of power supply equipment and forming a three-dimensional model library of all the power supply equipment;

the matching module (2) retrieves the three-dimensional model library and the electric power monitoring system equipment library, matches the three-dimensional model library with the electric power monitoring system equipment library according to a preset matching rule, and establishes a unique mapping relation between two objects which are successfully matched;

and the output module (3) embeds each three-dimensional model in the three-dimensional model library into the power monitoring system according to the mapping relation established by the matching module, and finally outputs the power monitoring system integrated with the three-dimensional models.

8. The power monitoring system interactively integrated with a BIM model according to claim 7, wherein: the generating module (1) comprises a BIM generating module (11) and a power monitoring system generating module (12), wherein the BIM generating module (11) comprises a BIM structure and data reading plug-in (111) and a first equipment and component list generating module (112) which are respectively used for importing a BIM model; the power monitoring system generation module (12) comprises a second equipment and component list generation module (121);

the matching module (2) comprises a data analysis module (21) for receiving the data relevant to the generation module (1) and a data matching analysis module (22) for matching the data;

the output module (3) comprises a mapping result management module (31) for receiving the matching result and an index generation module (32) for generating an index list and an interactive integration result.

9. The power monitoring system interactively integrated with a BIM model according to claim 8, wherein: the power monitoring system generation module (12) further comprises a necessary item setting module (122), and the necessary item setting module (122) is used for managing the output result of the second device and component list generation module (121) and marking a necessary matching item mark therein.

10. The power monitoring system interactively integrated with a BIM model according to claim 8, wherein: the output end of the mapping result management module (31) is respectively connected with a matching unsuccessful output module (311) and a successful matching output module (312);

the matching unsuccessful output module (311) is used for managing and outputting all unsuccessful matching items and generating a corresponding list;

the successful matching output module (312) is used for managing all successful matching items and mapping relations thereof.

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