CN115423928B

CN115423928B - BIM coding plug-in creation method based on intelligent building operation system

Info

Publication number: CN115423928B
Application number: CN202210893648.0A
Authority: CN
Inventors: 方瑾; 林秋桂; 陈润东
Original assignee: Huajian Shuchuang Shanghai Technology Co ltd
Current assignee: Huajian Shuchuang Shanghai Technology Co ltd
Priority date: 2022-07-27
Filing date: 2022-07-27
Publication date: 2023-11-17
Anticipated expiration: 2042-07-27
Also published as: CN115423928A

Abstract

The invention discloses a method for creating BIM coding plug-in based on an intelligent building operation system, which is used for building the intelligent building operation system; creating a component coding table and a component coding rule, and endowing each large class of components of the component coding table with component codes; making a model delivery requirement; taking a component coding rule and a model delivery requirement as logic, developing an ArcPointCode coding automatic adding tool; and packaging the codes of the ArcPointCode code automatic adding tool into pages, and manufacturing a Revit code plug-in. The invention firstly standardizes the model delivery content by making a model delivery guideline, and based on the logic of the model delivery requirement, implements coding, solves the defects of low coding efficiency, easy error and low input-output ratio of manual addition, and meanwhile, ensures the coding rule, rationality and applicability by using the landing coding logic and coding rule, and supports the platform to further develop based on the requirements and the application of the model in each stage of project engineering.

Description

BIM coding plug-in creation method based on intelligent building operation system

Technical Field

The invention relates to the technical field of building information model batched coding adding tools, in particular to a Building Information Model (BIM) coding plug-in creation method based on an intelligent building operation system.

Background

The building information model (Building Information Modeling, BIM) technology is used as an important tool for digital transformation in the engineering construction industry, and data of the whole life cycle of engineering projects are comprehensively integrated. If all the data information is directly bound with the model, the model data volume is excessively heavy, and the data is maintained through the model, so that the efficiency is low, and the threshold of software operation is high. Therefore, the current data maintenance mode generally adopts a mode of separating the model and the data, the data is summarized into an Excel table, management and maintenance are carried out outside the model, and the model and the data are bound through a unique code. The number of component models of a common business project BIM model can reach hundreds of thousands of orders, if the component models are added one by one manually, the efficiency is low, the error rate is high, and the input-output ratio is extremely low.

Disclosure of Invention

According to the embodiment of the invention, a building information model batched coding adding tool is provided, which comprises the following steps:

building an intelligent building operation system;

creating a component coding table and a component coding rule, and endowing each large class of components of the component coding table with component codes;

making a model delivery requirement;

taking a component coding rule and a model delivery requirement as logic, developing an ArcPointCode coding automatic adding tool;

and packaging the codes of the ArcPointCode code automatic adding tool into pages, and manufacturing a Revit code plug-in.

Further, the electro-mechanical professions of the component encoding tables are summarized in a hierarchical relationship of "subdivision profession" to "components or piping or end" to "specific general class of components".

Further, the non-electromechanical professions of the component encoding table are summarized in a hierarchical relationship from "profession" to "specific broad class of components".

Further, the model delivery requirements include: model version requirements, model splitting requirements, model naming requirements, and ArcPointCode encoding rules;

model version requirements are Revit2016, revit2018, revit2020;

the model splitting requirement is splitting according to three hierarchical splitting modes of building number-specialty-floor, building number-specialty and building number-structural functional partition/partition-specialty-floor;

the model naming requirements comprise model file naming requirements and model component naming requirements, the model component naming requirements consist of 'component major class names' and 'component minor class names', the model component naming requirements are named according to model splitting requirements in a combination mode of combining numbers, english and symbols, and the model file naming requirements comprise three naming modes of 'project number-building number-specialty-floor', 'project number-building number-specialty', 'project number-building number-structural function partition/partition-specialty-floor';

the ArcPointCode coding rule consists of component codes, floor numbers, building numbers and serial numbers of the specifications of the floors, and the ArcPointCode coding rule adopts a combination form of combining numbers, english and symbols.

Further, the ArcPointCode code automatic add-on tool is based on the c# language.

Further, the logic of the ArcPointCode code automatic add-on tool includes parsing by single floor model files and parsing by multi-floor model files.

Further, the analysis logic for analyzing the model file according to the single floor is as follows:

reading a first field of a model file name and a last field of the model file name of a BIM of the intelligent building operating system;

analyzing the BIM model, reading a named field in front of a symbol in a component model name of the BIM model, and adding equipment codes for the component model according to the mapping relation between components in a component coding table and the component codes;

reading the total number of the same type of components in the same floor in the BIM model;

the total amount of the components of the same type in the same analyzed floor is sequenced in a U-shaped sequence in the north-south direction, and component serial numbers which are gradually increased from '001' are obtained;

combining the component codes, the floor numbers of the model files and the sequenced component serial numbers, and adding ArcPointCode codes for the components of the BIM according to the format of 'equipment codes, floor numbers, the specification serial numbers of the floors';

outputting the ArcPointCode code addition result and the component ID of the component to which the ArcPointCode code has not been added successfully.

Further, the code of the parsing logic parsed by the single floor model file is packaged into a single floor model file with a manually selectable page.

Further, the parsing logic for the multi-floor model file is as follows:

reading the first field of the model file name;

adding floor attributes to components of a BIM model of the intelligent building operating system in a view screening or manual frame selection mode;

reading the floor information of the components in the BIM model, and analyzing the total number of the components with the same floor information and the same type in the BIM model;

the total quantity of the components with the same analyzed floor information and the same type is sequenced in a U-shaped sequence in the north-south direction;

combining the component codes, the read floor numbers, the floor numbers and the sequenced serial numbers, and adding ArcPointCode codes for the components of the BIM model according to the format of' equipment codes, floor numbers, the format of the specification numbers of the floor;

Further, the code of the parsing logic parsed by the multi-floor model file is packaged into a multi-floor model file with pages manually selectable.

According to the method for creating the BIM coding plug-in based on the intelligent building operation system, firstly, the model delivery rules are formulated, the model delivery content is standardized, coding is toolized based on logic required by model delivery, the defects of low coding efficiency, easiness in error and low input-output ratio of manual addition are overcome, meanwhile, the coding logic and the coding rules which can be landed are guaranteed, the coding rules, rationality and applicability are guaranteed, and a support platform is further developed based on requirements and applications of the model in each stage of project engineering.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and are intended to provide further explanation of the technology claimed.

Drawings

FIG. 1 is a flow chart of a method of creating a BIM coding plug-in based on a smart building operating system in accordance with an embodiment of the present invention;

FIG. 2 is a flow chart of parsing logic for single floor model file parsing in accordance with an embodiment of the present invention;

FIG. 3 is a flow chart of parsing logic for multi-floor model file parsing in accordance with an embodiment of the present invention;

fig. 4 is a flowchart of the page operation after the source code of this embodiment is packaged.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the attached drawings, which further illustrate the present invention.

Firstly, a method for creating a BIM coding plug-in based on an intelligent building operation system according to an embodiment of the invention will be described with reference to fig. 1 to 4, and the method is used for coding auditing of a BIM model and has a wide application scene.

As shown in fig. 1, the method for creating a BIM coding plug-in based on an intelligent building operating system according to the embodiment of the present invention includes the following steps:

in S1, as shown in fig. 1, a smart building operating system is built.

In S2, as shown in fig. 1, a component encoding table and a component encoding rule are created, and a component encoding is given to each large class of components of the component encoding table.

In S3, as shown in fig. 1, a model delivery requirement is formulated.

model version requirements are Revit2016, revit2018, revit2020;

the model splitting requirement is splitting according to three hierarchical splitting modes of building number-specialty-floor, building number-specialty and building number-structure functional partition/partition-specialty-floor, and the specific splitting mode is processing according to project business requirements, generally, if the project has no MEP system traceability requirement, splitting is carried out according to the building number-specialty-floor. For projects with smaller building body, the model files are split in a form of building number-specialty. For building monomers with larger single-layer area, namely, the single-layer area exceeds 10 ten thousand square meters, splitting is carried out according to the building number-structural function partition/partition-professional-floor;

the model naming requirements comprise model file naming requirements and model component naming requirements, the model file naming requirements are corresponding file naming according to split conditions, the model component naming requirements are composed of component major names and component minor names, the model component naming requirements are named in a combination mode of combining numbers, english and symbols, in the embodiment, building numbers are named according to actual conditions of projects, and building numbers are named according to 'A & S' (civil construction), 'CW' (curtain wall), 'MEP' (electromechanical) professionals. The floors are named according to the number and F, the interlayers are named according to the number and MF, the naming requirements of the model files are named according to the model splitting requirements, and the model files comprise three naming modes of project number-building number-specialty-floors, project number-building number-specialty, project number-building number-structural function partition/partition-specialty-floors;

the ArcPointCode coding rule consists of component codes, floor numbers and serial numbers of the specification of the floor, and the ArcPointCode coding rule adopts a combination form of combining numbers, english and symbols to ensure the uniqueness of the ArcPointCode codes.

In S4, as shown in fig. 1, an ArcPointCode code automatic addition tool is developed with the logic of the component code rule and the model delivery requirement.

in S411, as shown in fig. 2, the first field of the model file name and the last field of the model file name of the BIM model of the smart building operating system, i.e., the building number and the floor, are read.

In S412, as shown in fig. 2, the BIM model is parsed, the named fields in front of the "-" symbol in the component model name of the BIM model are read, the device code is added to the component model according to the mapping relationship between the components in the component code table and the component code, in this embodiment, if the component in the model is named "heat pump-air source", the named fields in front of the "-" symbol are read as "heat pump", and the matching codes are 30-40.15.00 according to the component code table.

In S413, as shown in fig. 2, the total number of the same type of members in the same floor within the BIM model is read.

In S414, as shown in fig. 2, the total number of the same type of components in the same floor is sorted in the north-south direction in the U-shape order, and the component serial numbers increasing one by one from "001" are obtained.

In S415, as shown in fig. 2, the component code, the floor number of the model file, and the ordered component serial number are combined, and the ArcPointCode is added to the component of the BIM model in the format of "equipment code, floor number, specification number" of the floor.

In S416, as shown in fig. 2, the ArcPointCode code addition result is output, and the ArcPointCode encodes the component ID of the component to which success has not been added.

Further, the parsing logic for the multi-floor model file is as follows:

in S421, as shown in fig. 3, the first field of the model file name, i.e., the building number, is read.

In S422, as shown in fig. 3, floor attributes are added to the building elements of the BIM model of the intelligent building operating system by means of view screening or manual framing.

In S423, as shown in fig. 3, the BIM model is analyzed, the named field preceding the "-" symbol in the component model name of the BIM model is read, and the device code is added to the component model according to the mapping relationship between the component and the component code in the component code table.

In S424, as shown in fig. 3, the floor information of the components in the BIM model is read, and the total number of the components having the same floor information and the same type in the BIM model is analyzed.

In S425, as shown in fig. 3, the total number of the components having the same type and the same floor information are sorted in the order of U-shape in the north-south direction.

In S426, as shown in fig. 3, the component code, the read floor number, the floor number, and the ordered serial number are combined, and the ArcPointCode is added to the component of the BIM model in the format of "equipment code, floor number, this specification number".

In S427, as shown in fig. 3, the ArcPointCode code addition result is output, and the ArcPointCode encodes the component ID of the component to which success has not been added.

In S5, as shown in fig. 1, the code of the ArcPointCode automatic adding tool is packaged into a page, and manufactured into a Revit code plug-in.

As shown in fig. 4, the plug-in is named ArcAutoCode, and the logic flow of the page prototype is as follows:

manually clicking a single-layer model or a multi-layer model on an additional module interface of the Revit coding plug-in, automatically analyzing building numbers and floor names when clicking the single-layer model, automatically filling a text box for use, supporting editing of the automatically filled building numbers and floor names, selecting a storage path for output of an automatically coded result, clicking 'determination', and outputting the automatically coded result; when the multi-layer model is selected, adding floor attributes to the component in any mode of 'view-by-view' or 'component-by-component' is manually selected; when the view is selected, the component-based analysis module is gray-displayed, the plug-in automatically analyzes all three-dimensional view names in the model and all components in each view to display all three-dimensional view names in a pull-down option frame, any view is selected to be added with floor names by pull-down, after clicking for confirmation, namely all components in the view are added with attribute values corresponding to the floor names, all the views can be named one by the mode, and the floor names cannot be repeated; when the "press component" is selected, the "press view" analysis module grey displays, after clicking the "select component", automatically jumps to the Revit interface, frames the component, automatically analyzes the ID of the component, supports to do "deselect" on the analyzed component in the list box, adds the attribute value of the floor name for the selected component, selects the storage path for the output result, clicks the "confirm", and outputs the automatically coded result.

It should be noted that, in this embodiment, if an individual component is not found in the component code table, the component code table needs to be supplemented, and a synchronous update iteration is performed in the background database of the encoding plug-in.

In the above, the method for creating the BIM coding plug-in based on the intelligent building operation system according to the embodiment of the invention is described with reference to fig. 1-4, firstly, the model delivery rules are formulated, the model delivery content is standardized, the coding is toolized based on the logic of the model delivery requirement, the defects of low coding efficiency, easy error and low input-output ratio of manual addition are overcome, meanwhile, the coding logic and coding rules which can fall to the ground are ensured, the coding rules, rationality and applicability are ensured, and the support platform is further developed based on the requirements and the application of the model in each stage of project engineering.

It should be noted that in this specification the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other like elements in a process, method, article or apparatus that comprises the element.

While the present invention has been described in detail through the foregoing description of the preferred embodiment, it should be understood that the foregoing description is not to be considered as limiting the invention. Many modifications and substitutions of the present invention will become apparent to those of ordinary skill in the art upon reading the foregoing. Accordingly, the scope of the invention should be limited only by the attached claims.

Claims

1. The method for creating the BIM coding plug-in based on the intelligent building operation system is characterized by comprising the following steps of:

building an intelligent building operation system;

creating a component coding table and a component coding rule, and endowing each major component of the component coding table with component coding;

making a model delivery requirement;

taking the component coding rules and the model delivery requirements as logic, developing an ArcPointCode coding automatic adding tool;

packaging the codes of the ArcPointCode code automatic adding tool into pages, and manufacturing a Revit coding plug-in;

the model delivery requirements include: model version requirements, model splitting requirements, model naming requirements, and ArcPointCode encoding rules;

the model version requirements are Revit2016, revit2018 and Revit2020;

the model splitting requirement is splitting according to three hierarchical splitting modes of building number-specialty-floor, building number-specialty and building number-structural function partition/partition-specialty-floor;

the model naming requirements comprise model file naming requirements and model member naming requirements, the model member naming requirements consist of a 'member major class name' and a 'member minor class name', the model member naming requirements adopt a combination mode of combining numbers, english and symbols, the model file naming requirements are named according to the model splitting requirements, and the model file naming requirements comprise three naming modes of 'project number-building number-specialty-floor', 'project number-building number-specialty', 'project number-building number-structural functional partition/partition-specialty-floor';

the ArcPointCode coding rule consists of component codes, floor numbers, serial numbers of the floor numbers and the floor specifications, and adopts a combination form of combining numbers, english and symbols;

logic of the ArcPointCode code automatic adding tool comprises analysis according to a single floor model file and analysis according to a multi-floor model file;

the analysis logic for analyzing the model file according to the single floor is as follows:

analyzing the BIM model, reading a named field in front of a symbol in a component model name of the BIM model, and adding equipment codes for the component model according to the mapping relation between components in the component code table and the component codes;

reading the total number of the same type of members in the same floor in the BIM model;

the total amount of the components of the same type in the same floor is analyzed to be sequenced in a U-shaped sequence in the north-south direction, and component serial numbers which are gradually increased from '001' are obtained;

combining the component codes, the floor numbers of the model files and the sequenced component serial numbers, and adding ArcPointCode codes for the components of the BIM according to the format of equipment codes, floor numbers and floor specification serial numbers;

outputting the ArcPointCode code addition result and the component ID of the component to which the ArcPointCode code is not added successfully;

the analysis logic for analyzing the multi-floor model file is as follows:

reading the first field of the model file name;

adding floor attributes to components of the BIM model of the intelligent building operating system in a view screening or manual frame selection mode;

reading floor information of components in the BIM model, and analyzing the total number of the components with the same floor information and the same type in the BIM model;

the total quantity of the components which are identical in type and identical in floor information and analyzed are sequenced in a U-shaped sequence in the north-south direction;

combining the component codes, the read floor numbers, the floor numbers and the sequenced serial numbers, and adding ArcPointCode codes for the components of the BIM model according to the format of equipment codes, floor numbers, floor specification serial numbers;

outputting the ArcPointCode code addition result, and the component ID of the component to which the ArcPointCode code was not added successfully.

2. The method of creating a BIM coding plug-in based on a smart building operating system of claim 1, wherein the electro-mechanical expertise of the building code table is summarized in a hierarchical relationship of "subdivision expertise" to "building elements or piping or end" to "specific major class building elements".

3. The method for creating a BIM coding plug-in based on a smart building operating system according to claim 1, wherein the non-electromechanical major of the building code table is summarized in a hierarchical relationship from "major" to "specific major class building".

4. The method for creating a BIM code plug-in based on a smart building operating system according to claim 1, wherein the ArcPointCode code automatic adding tool is based on the c# language.

5. The method of creating a BIM coding plug-in based on a smart building operating system of claim 1, wherein the code of the parsing logic parsed by the single floor model file is packaged into a single floor model file with pages manually selectable.

6. The method of creating a BIM coding plug-in based on a smart building operating system of claim 1, wherein the code of the parsing logic parsed by the multi-floor model file is packaged into a multi-floor model file with pages manually selectable.