CN112182705A - BIM technology-based simulation model data analysis method - Google Patents

Abstract

The invention discloses a BIM technology-based simulation model data analysis method, which comprises the following steps: s1: acquiring and analyzing DELMIA data, and uploading the DELMIA data to a visual platform; s2: DELMIA data downloading is carried out by utilizing the process framework and the step attribute of the DELMIA platform; s3: and performing simulation editing by using the downloaded DELMIA data to complete the analysis of the simulation model data. The invention provides the function of docking with a visual platform, realizes data intercommunication and efficiently performs DELMIA modeling. The DELMIA system realizes data interaction with the visual platform by calling the class library of the WebAPI of the visual platform. The data of DELMIA is discretized and uploaded to a platform for management. And data management is carried out in the visualization platform, and the functions of data reuse, data visualization and cross-platform use are realized.

Description

BIM technology-based simulation model data analysis method

Technical Field

The invention belongs to the technical field of data analysis, and particularly relates to a simulation model data analysis method based on a BIM (building information modeling) technology.

Background

In the field of large-scale engineering construction such as nuclear power, rail transit, airports, hydropower, environmental protection and intelligent buildings, more and more projects are subjected to engineering simulation by using a BIM technology in a planning and designing stage, a bidding stage, a construction stage and an operation and maintenance stage, and complex objects or programs can be visually, clearly and dynamically expressed through animation in an expression form like a film, so that the objects can be accepted, understood and communicated with one another conveniently. However, in the current use of BIM technology, a number of technical problems arise: 1. the existing BIM modeling technologies are many, such as CATIA, REVIT, TEKLA, MicroStation and the like, and the identification of common BIM modeling software formats and the disassembly and transformation technologies are not deeply involved; 2. the simulation animation is manufactured based on the BIM model, and the data reprocessing technology based on the simulation animation is not deeply involved, such as re-chartlet rendering, model display optimization setting and the like are not provided; 3. BIM simulation animation analysis processing technology aiming at various source formats is not provided. Based on the above-mentioned situations, it is necessary for those skilled in the art to solve the corresponding technical problems.

Disclosure of Invention

The invention aims to solve the problem of data analysis of a simulation model, and provides a BIM technology-based simulation model data analysis method.

The technical scheme of the invention is as follows: a BIM technology-based simulation model data analysis method comprises the following steps:

s1: acquiring and analyzing DELMIA data, and uploading the DELMIA data to a visual platform;

s2: DELMIA data downloading is carried out by utilizing the process framework and the step attribute of the DELMIA platform;

s3: and performing simulation editing by using the downloaded DELMIA data to complete the analysis of the simulation model data.

The invention has the beneficial effects that:

(1) the invention provides the function of docking with a visual platform, realizes data intercommunication and efficiently performs DELMIA modeling.

(2) The DELMIA system realizes data interaction with the visual platform by calling the class library of the WebAPI of the visual platform. The data of DELMIA is discretized and uploaded to a platform for management.

(3) In order to realize data intercommunication between a visualization platform and a DELMIA system, eliminate information islands, quickly perform data interaction and improve the working efficiency, secondary development is performed on the DELMIA system, so that a user can access the data of the visualization platform in the DELMIA system and realize uploading and downloading functions.

(4) And data management is carried out in the visualization platform, and the functions of data reuse, data visualization and cross-platform use are realized.

Further, step S1 includes the following sub-steps:

s11: accessing the PPR structure tree through a secondary development interface of the DELMIA platform to obtain DELMIA data, wherein the DELMIA data comprises a Product data Product, a Resource data Resource and an Activity data Activity;

s12: identifying the types of Product data Product, Resource data Resource and Activity data Activity through the process container;

s13: accessing Product data Product, Resource data Resource and Activity data Activity through the interface;

s14: writing the accessed and obtained data into a database and extracting triangular patch data and vertex data;

s15: and writing the triangular patch data and the vertex data into an SQLITE file, and uploading to a visualization platform.

The beneficial effects of the further scheme are as follows: in the invention, through analyzing DELMIA data, discretizing the data, extracting the required triangular patch and vertex, generating an SQLITE file by process simulation data, uploading the SQLITE file to a visual platform, managing the data in the visual platform, and realizing the functions of data reuse, data visualization and cross-platform use. The Product is a Product to be simulated, the Resource is a Resource required for simulation, the Activity is a specific simulation Activity, and the Activity describes how the Product performs simulation activities with the help of the Resource.

Further, in step S13, the method for accessing the Product data Product includes: geometry data Geometries, visibility, and child nodes childProducts of the Product data Product are recursively acquired and all Geometries are acquired.

Further, in step S13, the method for accessing Resource data Resource includes: acquiring Mechanisms Mechanisms, a joint list JointList, a command list CommandList and an initial command value InitialCmdValue in Resource data.

Further, in step S13, the method for accessing Activity data Activity includes: acquiring an Item of the simulation Activity of the Activity data Activity and a Resource of the simulation Activity.

Further, in step S14, for the Product data Product and the Resource data Resource, the method for extracting the triangle patch and the vertex includes: and traversing the structure trees of the Product data Product and the Resource data Resource to obtain the entity body, triangulating the entity body by using a DELMIA (Deltaimid) patch function, and extracting triangular patch data and vertex data.

The beneficial effects of the further scheme are as follows: in the present invention, all the entity Body in the Product data Product and Resource data Resource are required.

Further, the step S3 includes the following sub-steps:

s31: downloading a process frame and step attributes from a visual platform by a user;

s32: inserting the process framework and the step attributes into the PPR structure tree;

s33: downloading a three-dimensional scene from a visual platform by a user, and carrying out rapid assembly;

s24: and simulating and editing DELMIA data by using the process frame, the step attributes, the PPR structure tree and the three-dimensional scene to complete the analysis of the simulation model data.

The beneficial effects of the further scheme are as follows: in the invention, the process frame and the step attribute are uploaded after the user defines the process frame and the step attribute in DELMIA. The process frame and the step attributes are inserted into the PPR structure tree, so that a user can quickly use the defined frame and attributes, repeated work content is greatly reduced, and efficiency is improved. The three-dimensional scene Product is built in the DELMIA itself. The uploading of the data is for repeated use, the data downloading is editing capable of utilizing the data to carry out rapid simulation, a user can download a defined process frame and step attributes from the platform, directly insert the process frame and the step attributes into the current PPR structure tree, download a required three-dimensional scene Product from the platform to realize rapid assembly of the scene, and finally the user only needs to define a simulation process, so that the process can be completed, and the application requirements of the user and the requirements of later-stage data management are met.

Drawings

FIG. 1 is a flow chart of a method for analyzing simulation model data.

Detailed Description

The embodiments of the present invention will be further described with reference to the accompanying drawings.

Before describing specific embodiments of the present invention, in order to make the solution of the present invention more clear and complete, the definitions of the abbreviations and key terms appearing in the present invention will be explained first:

BIM technique: the abbreviation of Building Information Modeling can realize two-dimensional to three-dimensional collaborative design, integration of more Information and compatibility of different software technologies.

DELMIA data: the acronym, titled DIGITAL ENTERPRISE LEAN MANUFACTURING INTERACTIVE APPLICATION, implies that digital enterprises make lean MANUFACTURING INTERACTIVE APPLICATIONs, which are divided into 3 parts, DELMIA E5(DPE), DELMIA V5(DPM), DELMIA D5 (QUEST). These three relatively independent parts may be connected together by a PPR (Process, Product, Resource) Hub, with the general normal operation of formulating manufacturing processes and Resource plans by E5, simulation by V5 and D5, and data transfer by the PPR Hub.

As shown in fig. 1, the invention provides a data analysis method for simulating a simulation model based on a BIM technology, which comprises the following steps:

s1: acquiring and analyzing DELMIA data, and uploading the DELMIA data to a visual platform;

s2: DELMIA data downloading is carried out by utilizing the process framework and the step attribute of the DELMIA platform;

s3: and performing simulation editing by using the downloaded DELMIA data to complete the analysis of the simulation model data.

In the embodiment of the present invention, as shown in fig. 1, step S1 includes the following sub-steps:

s11: accessing the PPR structure tree through a secondary development interface of the DELMIA platform to obtain DELMIA data, wherein the DELMIA data comprises a Product data Product, a Resource data Resource and an Activity data Activity;

s12: identifying the types of Product data Product, Resource data Resource and Activity data Activity through the process container;

s13: accessing Product data Product, Resource data Resource and Activity data Activity through the interface;

s14: writing the accessed and obtained data into a database and extracting triangular patch data and vertex data;

s15: and writing the triangular patch data and the vertex data into an SQLITE file, and uploading to a visualization platform.

In the invention, through analyzing DELMIA data, discretizing the data, extracting the required triangular patch and vertex, generating an SQLITE file by process simulation data, uploading the SQLITE file to a visual platform, managing the data in the visual platform, and realizing the functions of data reuse, data visualization and cross-platform use. The Product is a Product to be simulated, the Resource is a Resource required for simulation, the Activity is a specific simulation Activity, and the Activity describes how the Product performs simulation activities with the help of the Resource.

In the embodiment of the present invention, as shown in fig. 1, in step S13, the method for accessing the Product data Product includes: geometry data Geometries, visibility, and child nodes childProducts of the Product data Product are recursively acquired and all Geometries are acquired.

In this embodiment of the present invention, as shown in fig. 1, in step S13, the method for accessing Resource data Resource includes: acquiring Mechanisms Mechanisms, a joint list JointList, a command list CommandList and an initial command value InitialCmdValue in Resource data.

In the embodiment of the present invention, as shown in fig. 1, in step S13, the method for accessing Activity data Activity includes: acquiring an Item of the simulation Activity of the Activity data Activity and a Resource of the simulation Activity.

In the embodiment of the present invention, as shown in fig. 1, in step S14, for the Product data Product and the Resource data Resource, the method for extracting the triangle patch and the vertex includes: and traversing the structure trees of the Product data Product and the Resource data Resource to obtain the entity body, triangulating the entity body by using a DELMIA (Deltaimid) patch function, and extracting triangular patch data and vertex data.

In the present invention, all the entity Body in the Product data Product and Resource data Resource are required.

In the embodiment of the present invention, as shown in fig. 1, the step S3 includes the following sub-steps:

s31: downloading a process frame and step attributes from a visual platform by a user;

s32: inserting the process framework and the step attributes into the PPR structure tree;

s33: downloading a three-dimensional scene from a visual platform by a user, and carrying out rapid assembly;

s24: and simulating and editing DELMIA data by using the process frame, the step attributes, the PPR structure tree and the three-dimensional scene to complete the analysis of the simulation model data.

In the invention, the process frame and the step attribute are uploaded after the user defines the process frame and the step attribute in DELMIA. The process frame and the step attributes are inserted into the PPR structure tree, so that a user can quickly use the defined frame and attributes, repeated work content is greatly reduced, and efficiency is improved. The three-dimensional scene Product is built in the DELMIA itself. The uploading of the data is for repeated use, the data downloading is editing capable of utilizing the data to carry out rapid simulation, a user can download a defined process frame and step attributes from the platform, directly insert the process frame and the step attributes into the current PPR structure tree, download a required three-dimensional scene Product from the platform to realize rapid assembly of the scene, and finally the user only needs to define a simulation process, so that the process can be completed, and the application requirements of the user and the requirements of later-stage data management are met.

The working principle and the process of the invention are as follows: firstly, DELMIA data is obtained and analyzed, and the DELMIA data is uploaded to a visual platform; then, DELMIA data downloading is carried out by utilizing the process framework and the step attribute of the DELMIA system; and finally, performing simulation editing by using the downloaded DELMIA data to complete the analysis of the simulation model data.

The invention has the beneficial effects that:

(1) the invention provides the function of docking with a visual platform, realizes data intercommunication and efficiently performs DELMIA modeling.

(2) The DELMIA system realizes data interaction with the visual platform by calling the class library of the WebAPI of the visual platform. The data of DELMIA is discretized and uploaded to a platform for management.

(3) In order to realize data intercommunication between a visualization platform and a DELMIA system, eliminate information islands, quickly perform data interaction and improve the working efficiency, secondary development is performed on the DELMIA system, so that a user can access the data of the visualization platform in the DELMIA system and realize uploading and downloading functions.

(4) And data management is carried out in the visualization platform, and the functions of data reuse, data visualization and cross-platform use are realized.

It will be appreciated by those of ordinary skill in the art that the embodiments described herein are intended to assist the reader in understanding the principles of the invention and are to be construed as being without limitation to such specifically recited embodiments and examples. Those skilled in the art can make various other specific changes and combinations based on the teachings of the present invention without departing from the spirit of the invention, and these changes and combinations are within the scope of the invention.

Claims (7)

1. A BIM technology-based simulation model data analysis method is characterized by comprising the following steps:

s1: acquiring and analyzing DELMIA data, and uploading the DELMIA data to a visual platform;

s2: DELMIA data downloading is carried out by utilizing the process framework and the step attribute of the DELMIA system;

s3: and performing simulation editing by using the downloaded DELMIA data to complete the analysis of the simulation model data.

2. The BIM technique based simulation model data parsing method of claim 1, wherein the step S1 comprises the following sub-steps:

s11: accessing the PPR structure tree through a secondary development interface of the DELMIA platform to obtain DELMIA data, wherein the DELMIA data comprises a Product data Product, a Resource data Resource and an Activity data Activity;

s12: identifying the types of Product data Product, Resource data Resource and Activity data Activity through the process container;

s13: accessing Product data Product, Resource data Resource and Activity data Activity through the interface;

s14: writing the accessed and obtained data into a database and extracting triangular patch data and vertex data;

s15: and writing the triangular patch data and the vertex data into an SQLITE file, and uploading to a visualization platform.

3. The BIM technique based simulation model data analysis method of claim 2, wherein in step S13, the method for accessing Product data Product comprises: geometry data Geometries, visibility, and child nodes childProducts of the Product data Product are recursively acquired and all Geometries are acquired.

4. The BIM technology-based analytical method for simulation model data according to claim 2, wherein in step S13, the method for accessing Resource data Resource comprises: acquiring Mechanisms Mechanisms, a joint list JointList, a command list CommandList and an initial command value InitialCmdValue in Resource data.

5. The BIM technique-based analytical method for simulation model data according to claim 2, wherein in step S13, the method for accessing Activity data Activity comprises: acquiring an Item of the simulation Activity of the Activity data Activity and a Resource of the simulation Activity.

6. The BIM technique based analytical method for simulation model data according to claim 2, wherein in step S14, for the Product data Product and Resource data Resource, the method for extracting triangle patches and vertices includes: and traversing the structure trees of the Product data Product and the Resource data Resource to obtain the entity body, triangulating the entity body by using a DELMIA (Deltaimid) patch function, and extracting triangular patch data and vertex data.

7. The BIM technique based simulation model data parsing method of claim 1, wherein the step S3 comprises the following sub-steps:

s31: downloading a process frame and step attributes from a visual platform by a user;

s32: inserting the process framework and the step attributes into the PPR structure tree;

s33: downloading a three-dimensional scene from a visual platform by a user, and carrying out rapid assembly;

s24: and simulating and editing DELMIA data by using the process frame, the step attributes, the PPR structure tree and the three-dimensional scene to complete the analysis of the simulation model data.

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