CN113569306A - BIM modeling implementation and application method of waste incineration power plant based on BIM technology - Google Patents

Abstract

The invention discloses a BIM modeling implementation and application method of a waste incineration power plant based on a BIM technology, relates to the field of engineering design of the waste incineration power plant, and solves the technical problems that the prior art is lack of utilization of BIM model information and the like. The method comprises the following steps: s1, item start: s2, decomposing intelligent work of the platform: s3, selecting platform preset project environment S4, and completing each professional model: establishing a positioning reference point of each monomer of the project through a general drawing; each professional model refers to a design drawing according to the single positioning points to establish the model; s5, automatic streaming of model verification: after the model is established by each professional design unit, the circulation of checking is started; s6, collision check of each professional model; s7, limited space headroom analysis; s8, a hole-reserving picture and a section view of the wall; and S9, delivering the result. The method achieves the effects of realizing the BIM modeling implementation application with one module for multiple purposes, outputting BIM engineering quantity lists, auxiliary construction section drawings and the like, and bringing a plurality of benefits to projects.

Description

BIM modeling implementation and application method of waste incineration power plant based on BIM technology

Technical Field

The invention relates to the field of engineering design of a waste incineration power plant, in particular to a BIM modeling implementation application method of a waste incineration power plant based on a BIM technology.

Background

Along with the development of the application of the domestic BIM technology, the application of the BIM technology of the domestic waste incineration power plant is gradually increased year by year, and the application of the BIM technology in the whole waste incineration power generation field is actively developed.

The invention patent with the publication number of CN111597666A is disclosed by the intellectual property office of China at 28.8.2020, entitled "a method for applying BIM to the construction process of a transformer substation", and provides a method for applying BIM to the construction process of the transformer substation, which comprises the following steps: in the power grid design stage, BIM modeling is carried out on a transformer substation, and BIM three-dimensional modeling, collision inspection and pipeline optimization are utilized; in the power grid construction stage, geographic information of a GIS (geographic information System) is combined, geographic terrain data are acquired according to unmanned aerial vehicle photography, and are compared with BIM (building information modeling) data of a transformer substation, so that a construction scheme is corrected; in the operation and maintenance stage, the BIM data of the transformer substation is combined with the intelligent sensor data of the intelligent construction site, so that the BIM visual intelligent transformer substation is realized, the BIM information is not utilized, and the method belongs to a simple three-dimensional model building method; the BIM application in the operation and maintenance stage is lacked, and the operability is not good.

Therefore, in the BIM modeling implementation application method in the field of waste incineration power generation at present, the advantages of BIM technology application are not effectively combined to generate greater benefit, the BIM not only has three-dimensional shape and can carry out collision inspection and other work, but also can provide assistance for projects by the information of the BIM model. Therefore, a BIM modeling implementation application method which has a wide coverage area and is feasible and can bring many benefits to projects is urgently needed.

Disclosure of Invention

The invention aims to provide a BIM modeling implementation application method of a waste incineration power plant based on a BIM technology, which can realize the BIM modeling implementation application with multiple purposes, can output BIM engineering quantity lists, auxiliary construction section drawings and the like, and can bring various benefits to projects.

The technical purpose of the invention is realized by the following technical scheme:

a BIM modeling implementation and application method of a waste incineration power plant based on a BIM technology comprises the following steps:

s1, item start: at the beginning of BIM modeling of a waste incineration power generation project, determining BIM modeling implementation application requirements of the project;

s2, decomposing intelligent work of the platform: decomposing the BIM modeling work of the whole project so as to carry out BIM design;

s3, selecting the platform preset project environment: the BIM modeling of the waste incineration power generation project respectively creates project template files and working environments corresponding to the professions according to the different characteristics of different professions and using different software;

s4, completing each professional model: drawing files of all specialties of a waste incineration power generation project are collected, before building of BIM models of all specialties is started, positioning datum points of all monomers of the project are built through general drawing, and integration and summarization after building of all the specialties are completed are facilitated;

after the establishment of each monomer positioning datum point is completed, each professional model refers to a design drawing according to the monomer positioning points to establish the model;

s5, automatic streaming of model verification: after the model is established by each professional design unit, the circulation of checking is started;

s6, collision check of each professional model: opening the integrated whole plant model, performing BIM collision check according to the specialty, the specialty and the specialty, sending BIM collision check reports of the project to each professional unit, feeding back BIM engineers to modify the model by each professional unit, and sending the modified drawings to the BIM engineers as the basis of model adjustment;

s7, restricted space headroom analysis: performing model clearance analysis on a region with limited partial space in a plant-wide integration model, and visually knowing that the limited space can meet the clearance requirement by measuring or inserting a clearance inspection model; if the clearance is insufficient, a feedback designer modifies the related elevation to ensure the clearance requirement of the limited space;

s8, wall hole reserving picture and section view: after the project BIM model is checked and modified, outputting a wall hole-reserving picture and a pipeline installation section and sending to a site construction site;

s9, result delivery: after all applications of BIM modeling of the project are finished, the designed BIM model is submitted to the project field application and project construction links.

Further, in step S1, a proper BIM model is selected to establish the fineness, and the fineness of the BIM model meets the requirement of the national standard on the fineness of the model.

Further, in step S2, the decomposed BIM modeling implementation application work includes model catalog, project BIM design schedule, and model delivery criteria.

Further, in step S3, all the software working environments and project templates are preset in advance in the collaborative design management platform and selected as required.

Furthermore, if the REVIT software is used, various family components required to be used by the project are customized after the project template is used, and meanwhile, list codes are added to the family components according to the requirement of the BIM pilot quantity list, so that the statistics of the subsequent BIM project quantity is facilitated;

if the BENTLEY series software is used, the working environment is required to be customized in the series software, and the list code is added into the component.

Further, in step S4, the created models include a building model, a structural model, a process model, a heating and ventilation model, a water supply and drainage model, an electrical model, a steel structure model, an equipment model, and a site model.

Furthermore, in step S5, the flow of the verification includes submitting to the model quality unit for model checking, and if the model is found to be established with errors, feeding back the BIM engineer for modification.

Furthermore, in step S5, the drawing design problems and unreasonable design parts found in the process of modeling by each professional design unit BIM are collected and registered, and submitted to be fed back to the feedback designer for checking; and after checking by the designer, feeding back a professional design unit for model modification.

Furthermore, after the model checking and the graph model checking are completed, all the completed professional models are integrated, and the factory-wide integrated model is lightened through lightening tool software.

Further, in step S8, a BIM engineering volume list and a BIM display animation of the model are also output.

In conclusion, the invention has the following beneficial effects:

(1) the defect that the existing model building implementation collision check is single is overcome, and the BIM modeling implementation application method with multiple purposes is realized;

(2) the defect that the model does not have extended application is overcome, and besides conventional visualization and collision inspection, the BIM model can also output a BIM engineering quantity list, a profile drawing for auxiliary construction, display animation and the like;

(3) the model can be extended to the construction and operation and maintenance stage, and the problem of repeated modeling is avoided;

(4) the model is sent to a professional designer for interaction in real time in the process of establishing the model, so that the accuracy of establishing the model is ensured;

(5) and building BIM models with different fineness according to different design stages, such as schemes, initial setting, construction and the like.

Drawings

FIG. 1 is a schematic flow chart of the implementation and application of the present invention.

Detailed Description

The following further describes the embodiments of the present invention with reference to the drawings, and the present embodiment is not to be construed as limiting the invention.

As shown in fig. 1, the BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology provided by this embodiment is used for the BIM modeling implementation and application of a project in the field of waste incineration power generation, and has been actually applied to a plurality of projects and has good effects at present. Meanwhile, the method is different from a conventional BIM modeling implementation application method, supports multi-professional collaborative design, has the characteristic of multiple purposes, and fully shows the application advantages of the BIM technology in the field of waste incineration power generation. Which comprises the following steps:

s1, item start:

at the beginning of BIM modeling of a waste incineration power generation project, determining BIM modeling implementation application requirements of the project and various design data related to the project, such as an exploitable document and the like; meanwhile, the depth and the property of the project design are determined, and a proper BIM model is selected to establish the fineness, wherein the fineness of the BIM model meets the requirement of national standard on the fineness of the model;

s2, decomposing intelligent work of the platform:

according to a collaborative design management platform Projectwise erected on a public cloud, automatically decomposing the BIM modeling work of the whole project so that the whole BIM working system or working process can better carry out BIM design;

the decomposed BIM modeling implementation application work comprises a model catalog, a project BIM design schedule and a model delivery standard, the whole project BIM modeling implementation is carried out under a standardized frame from the source, and the project environment building S3 link is carried out after the whole project BIM modeling implementation is finished;

s3, selecting the platform preset project environment:

the BIM modeling of the waste incineration power generation project respectively creates project template files and working environments corresponding to the professions according to the different characteristics of different professions and using different software;

REVIT software is commonly used in civil engineering major, various family members needed to be used by projects are customized after project templates of REVIT software, such as wall beam plate columns, doors and windows, and meanwhile, list codes are added to the family members according to the requirement of a BIM guide quantity list, so that the statistics of the subsequent BIM project quantity is facilitated;

BENTLEY series software is widely used in the electromechanical profession, a working environment needs to be customized in the series software, and the list codes are added into the components;

software used by other specialties such as steel structures also needs to customize templates in advance;

all software working environments and project templates are preset in advance on a collaborative design management platform Projectwise, are selected as required, and then enter each professional model to complete (S4);

s4, completing each professional model:

drawing files of all specialties of a waste incineration power generation project are collected, before building of BIM models of all specialties is started, positioning datum points of all monomers of the project are built through general drawing, and integration and summarization after building of all the specialties are completed are facilitated;

after the establishment of each monomer positioning datum point is completed, each professional model refers to a design drawing according to the monomer positioning points to establish the model;

the totally created models include a building model, a structural model, a process model, a heating and ventilation model, a water supply and drainage model, an electrical model, a steel structural model, an equipment model and a site model. After all models are built, entering links of model self-checking and graph model checking (S5);

s5, automatic streaming of model verification:

after each professional design unit or BIM engineer completes the model creation, automatically starting to transfer the verification according to the workflow customized by the project wise of the collaborative design management platform;

submitting the model quality unit to a BIM model quality engineer of a project professional for model checking, and feeding back the BIM engineer for modification if errors exist in model establishment;

meanwhile, summarizing and registering drawing design problems and unreasonable design parts found in the BIM modeling process of each professional design unit or professional BIM engineer, and feeding back the drawing design problems and unreasonable design parts to a designer for checking; after checking by a designer, feeding back a BIM engineer to modify the model;

after the model checking and the graph model checking are finished, a BIM design coordinator of a refuse incineration power generation project integrates all finished professional models, and the factory-wide integrated model is lightened through a lightweight tool software Navisvarks, so that the phenomenon that a computer browses the model to be stuck after all models are integrated is avoided. Entering a collision check (S6) link of each professional model after the lightweight integration of the model is completed;

s6, crash check of professional models

Opening the integrated whole plant model by Navisvarks lightweight model software, and starting BIM collision inspection according to the specialty and the specialty;

after the software collision check work, compiling a BIM collision check report of a project and sending the BIM collision check report to each specialty, and simultaneously carrying out discussion on collision point problems together with each specialty in a BIM collision check conference; after the collision check meeting, each professional designer replies a relevant collision check problem to a BIM engineer to modify the model, and sends the modified drawing to the BIM engineer as a basis for model adjustment;

and performing secondary collision check work again after the BIM model is adjusted so as to ensure that new collision is not generated after the collision point is adjusted. Entering a restricted space headroom analysis (S7) step after the completion;

s7, constrained space headroom analysis

Performing model clearance analysis on a region with limited partial space in a plant-wide integration model, and visually knowing that the limited space can meet the clearance requirement by measuring or inserting a clearance inspection model; and if the clearance is not enough, the feedback designer modifies the relevant elevation to ensure the clearance requirement of the limited space. After the completion, entering links of wall hole reserving drawing, section drawing, engineering quantity and animation display (S8);

s8, wall hole-reserving picture, section picture, engineering quantity, display cartoon

After the project BIM model is checked and modified, outputting a wall hole reserving diagram and a pipeline installation section to send a site construction site for matching construction, and feeding back the hole reserving diagram output by the BIM to the construction major to modify the hole opening positions of each major to avoid the inconsistency of actual installation and the reserved hole opening positions; the output pipeline installation section is matched with field construction installation, so that field construction change caused by disordered pipeline installation elevation is avoided;

outputting a BIM project amount list of the model to control the cost of the whole project;

since the source of the BIM engineering quantity list is the material list derived from the BIM model, and the list codes of the components are preset in the software in step S3, after the material list is derived, the BIM engineering quantity list is classified and summarized according to the list codes in the material list;

adding a material loss coefficient in the finished BIM project amount list to avoid insufficient material purchasing for use in a construction site caused by the quantity of the model substance;

and outputting the BIM display animation to be used as the propaganda display of the project. After the completion, the process goes to a result delivery (S9) link;

s9, result delivery

And after the BIM modeling of the project is finished, the designed BIM model is submitted to the project field application and project construction links, meanwhile, the BIM model in the design stage is filed, and the project completion model is completed according to a completion drawing after the project is completed.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the spirit and scope of the invention.

Claims (10)

1. A BIM modeling implementation and application method of a waste incineration power plant based on a BIM technology is characterized by comprising the following steps:

s1, item start: at the beginning of BIM modeling of a waste incineration power generation project, determining BIM modeling implementation application requirements of the project;

s2, decomposing intelligent work of the platform: decomposing the BIM modeling work of the whole project so as to carry out BIM design;

s3, selecting the platform preset project environment: the BIM modeling of the waste incineration power generation project respectively creates project template files and working environments corresponding to the professions according to the different characteristics of different professions and using different software;

s4, completing each professional model: drawing files of all specialties of a waste incineration power generation project are collected, before building of BIM models of all specialties is started, positioning datum points of all monomers of the project are built through general drawing, and integration and summarization after building of all the specialties are completed are facilitated;

after the establishment of each monomer positioning datum point is completed, each professional model refers to a design drawing according to the monomer positioning points to establish the model;

s5, automatic streaming of model verification: after the model is established by each professional design unit, the circulation of checking is started;

s6, collision check of each professional model: opening the integrated whole plant model, performing BIM collision check according to the specialty, the specialty and the specialty, sending BIM collision check reports of the project to each professional unit, feeding back BIM engineers to modify the model by each professional unit, and sending the modified drawings to the BIM engineers as the basis of model adjustment;

s7, restricted space headroom analysis: performing model clearance analysis on a region with limited partial space in a plant-wide integration model, and visually knowing that the limited space can meet the clearance requirement by measuring or inserting a clearance inspection model; if the clearance is insufficient, a feedback designer modifies the related elevation to ensure the clearance requirement of the limited space;

s8, wall hole reserving picture and section view: after the project BIM model is checked and modified, outputting a wall hole-reserving picture and a pipeline installation section and sending to a site construction site;

s9, result delivery: after all applications of BIM modeling of the project are finished, the designed BIM model is submitted to the project field application and project construction links.

2. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1, wherein: in step S1, a proper BIM model is selected to establish the fineness, and the fineness of the BIM model meets the requirement of the national standard on the fineness of the model.

3. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1 or 2, wherein: in step S2, the decomposed BIM modeling implementation application work includes a model catalog, a project BIM design schedule, and model delivery criteria.

4. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1, wherein: in step S3, all software working environments and project templates are preset in advance on the collaborative design management platform and selected as needed.

5. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 4, wherein: if REVIT software is used, various family members needed to be used by the project are customized after the project template is used, and meanwhile, list codes are added to the family members according to the requirement of the BIM pilot list so as to facilitate the statistics of the subsequent BIM engineering quantity;

if the BENTLEY series software is used, the working environment is required to be customized in the series software, and the list code is added into the component.

6. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1, wherein: in step S4, the created models include a building model, a structural model, a process model, a heating and ventilation model, a water supply and drainage model, an electrical model, a steel structure model, an equipment model, and a site model.

7. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1, wherein: in step S5, the flow of the verification includes submitting the flow to a model quality unit for model checking, and if the model is found to be established with errors, feeding back BIM engineers for modification.

8. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1 or 7, wherein: in step S5, summarizing and registering drawing design problems and unreasonable design parts discovered in the process of BIM modeling of each professional design unit, and submitting the drawing design problems and unreasonable design parts to a feedback designer for checking; and after checking by the designer, feeding back a professional design unit for model modification.

9. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 8, wherein: and integrating all the finished professional models after the model checking and the graph model checking are finished, and lightening the factory-wide integrated model through lightening tool software.

10. The BIM modeling implementation and application method of the waste incineration power plant based on the BIM technology as claimed in claim 1, wherein: in step S8, a BIM engineering quantity list and a BIM display animation of the model are also output.

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