CN112257160B - BIM-based standardized forward design method for garbage incineration power plant - Google Patents

Abstract

The invention discloses a BIM-based standardized forward design method for a garbage incineration power plant, which comprises the following steps: s1, building a working environment, S2, creating a total image field model, S3, creating an equipment model, S4, creating a building model, S5, creating a structural model, S6, creating a water heating electric model, S7, creating a process model, S8, analyzing and examining the model, and outputting the model. The invention has the advantages of realizing the full-specialized BIM forward design of the garbage incineration power plant, avoiding the current situation that the traditional BIM design depends on the turnover mould, providing a mature, reliable and efficient method for the BIM forward design transformation of the design institute, solving the problem that the BIM is difficult to land in the forward direction and greatly improving the BIM forward application coverage rate.

Description

BIM-based standardized forward design method for garbage incineration power plant

Technical Field

The invention relates to the field of engineering design of garbage incineration power plants, in particular to a BIM-based standardized forward design method of a garbage incineration power plant.

Background

With the development of the application of the domestic BIM technology, the application of the BIM technology of the domestic garbage incineration power plant is gradually increased year by year, and BIM forward design is a development trend of the application of the BIM technology, and with the continuous innovation of the BIM technology, the existing design mode of two-dimensional CAD drawing is replaced. Whether forward design is employed in BIM technology applications in waste incineration power plants is an important criterion for evaluating BIM application level. At present, the design of the domestic garbage incineration power plant generally adopts two-dimensional CAD drawing design, and even if BIM technology is adopted, the BIM technology is limited on the basis of collision inspection by turnover of a die, and has a larger rising space in application value.

Therefore, BIM forward is still in a starting stage in China, a set of mature, reliable, standardized and practical method is not formed yet for how to successfully transform BIM three-dimensional forward design from CAD two-dimensional design, BIM technology in the engineering design field of the garbage incineration power plant starts later, BIM forward design is futile, a garbage incineration power plant standardized forward design method based on BIM technology is urgently required to be developed, BIM forward design is concentrated on a certain specialty and cannot be covered comprehensively, existing BIM forward design is mainly used for establishing a model and collision check, a link from the model to a construction drawing is not opened, meanwhile, multi-specialty BIM forward collaborative design cooperation is lacked, mutual investment among the specialty is ignored, BIM forward application is single, and BIM forward achievement expression is limited.

Disclosure of Invention

The invention aims to provide a BIM-based standardized forward design method for a garbage incineration power plant.

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

the standardized forward design method for the garbage incineration power plant based on BIM is characterized by comprising the following steps of:

s1, building a working environment: configuring a layer, a system, a drawing and a preset component library of an item through BENTLEY software, designing a civil engineering specialty by adopting REVIT software, pre-configuring sample files required by an item level, and configuring a family library, an engineering quantity list code, drawing template setting and the like;

s2, creating a total image field model: analyzing a topographic map, a red line map, a wind direction and external access conditions obtained by the place where the project is located, completing the design work of the total map of the project by utilizing a topographic surface tool in REVIT software, and sending the total map to each specialty in a three-dimensional model form;

s3, creating an equipment model: modeling equipment in advance by using BENTLEY software according to the information of each electromechanical professional equipment provided by a manufacturer, and importing all equipment models into the working environment of the BENTLEY software on a server after equipment model creation is completed;

s4, building a building model: after the basic size and the height of the factory building are determined, building design is perfected by building professions, building BIM forward design is started by applying building design commands in REVIT software according to the received house conditions for professional building, and building model design is perfected;

s5, creating a structural model: according to the equipment model provided in the step S3, the building model provided by the building specialty in the step S4 and the equipment load received later are used for lifting materials, and the BIM forward design model of the concrete structure and the steel structure is completed by the structural specialty;

s6, creating a water heating electric model: the BENTLEY software of the water heating electric professional refers to the building model in the cited S4 for building a water heating electric BIM forward design model, and comprises forward model designs of water supply and drainage, fire-fighting pipelines, heating ventilation pipes, electric lighting, bridge cables, lightning protection and grounding and the like;

s7, creating a process model: the technical specialty receives the technical design information, applies BENTLEY OPENPLANT piping software to develop the three-dimensional design of the technical pipeline, and utilizes a classical pipe element grade library configured in the working environment in advance to finish the forward design of the technical BIM pipeline, and then introduces CAESAR II software to calculate and analyze the stress analysis;

s8, model analysis and examination: integrating and summarizing all model files by utilizing light browsing software NAVISWORKS to finish collision check and clearance analysis of the model, and subsequently performing checking work;

s9, outputting a model: and outputting a two-dimensional construction diagram to each professional model through software, leading out an enterprise or national standard engineering quantity list by each professional BIM model component with engineering quantity list information, completing the project display animation production work, and finally performing the design bottoming work.

Preferably, in the step S1, the working environment of the bertley software is set up on the server, and each professional can be designed under the same working environment.

Preferably, the sample file in S1 includes a family library, an engineering quantity list code, and a drawing template.

Preferably, in the step S3, naming, two-dimensional view projection, layer information and device information are added for each device while the device model is established.

Preferably, in the step S4, the shaft network is arranged, the wall body, the room layout and other design works are drawn by using REVIT software with reference to the professional three-dimensional house investment of the cited process, and the building model design is perfected by combining with other professional three-dimensional house investment.

Preferably, in the S5, the structural profession respectively completes BIM forward design models of the concrete structure and the steel structure in PKPM and 3D3S software, the structural concrete model completed by PKPM is directly fed back to the building profession, the building profession directly introduces the PKPM model through the plug-in unit by adopting REVIT software, the building profession completes updating of the civil engineering model and feeds back to the relevant profession, and the steel structure model completed by 3D3S directly exports 3D DWG file and feeds back to each profession for pipeline design and collision checking work.

Preferably, in the step S9, the two-dimensional construction drawings are output to the professional models in REVIT, BENTLEY, PKPM and 3D3S software respectively, the output two-dimensional construction drawings have basic drawing marking information, and the unsatisfied requirements are subjected to secondary deepening processing by CAD, so as to meet the construction drawing requirements.

In summary, the invention has the following beneficial effects:

(1) Providing a set of standardized BIM forward design method for designing the garbage incineration power plant for guidance;

(2) The engineering design of the garbage incineration power plant realizes full-specialty collaborative BIM forward design, is not limited to BIM forward design by a certain specialty any more, and has good practical value.

(3) And the output two-dimensional construction diagram is used as a final target for transmitting a construction site, so that the BIM forward design is truly landed in actual work.

(4) The cooperation design cooperation among multiple professions is realized, the BIM model is used for replacing two-dimensional investment, and the BIM forward design concept is more attached.

(5) Besides the application of collision detection as the most basic of BIM design, BIM engineering quantity is increased, animation application is displayed, and BIM forward design results are enriched.

Drawings

Fig. 1 is a flow chart of a standardized forward design method of a garbage incineration power plant based on a BIM technology.

Detailed Description

The following description of the embodiments of the invention is further illustrated in the accompanying drawings, and the examples are not meant to limit the invention.

As shown in fig. 1, the standardized forward design method of the garbage incineration power plant based on the BIM technology is used for establishing a set of mature and reliable BIM forward design flow of the garbage incineration power plant based on the BIM technology, so that the BIM forward design can truly fall to the ground and be practical. Which comprises the following steps:

s1, building a working environment: each specialty of garbage incineration power plant design needs to configure the work of BIM software before BIM forward design is performed, so that the practical requirements of each specialty can be met in the BIM forward design process, and the practical requirements comprise design templates, family libraries, component libraries, drawing templates, drawing linearity, engineering quantity list model component numbers and the like are preset. The electromechanical professional software adopts BENTLEY series software, the working environment of the software is set up on a server, all designers using the series software find msdir.cfg in a C disk catalog of the installed software to carry out directional configuration of the working environment of the software, and thus all designers using the software to carry out design are in the same working environment. And then, the layers, the systems, the graphs and the preset component library of the project are configured in the Projects folder under the working environment, so that a professional designer can conveniently call the design content required by the professional designer. The civil engineering profession adopts REVIT to design, and sample files required by project level are pre-configured, so that the configuration of a family base, engineering quantity list codes, drawing template setting and the like is finished, and a professional designer can conveniently call. The method comprises the steps of carrying out a first treatment on the surface of the

S2, creating a total image field model: according to the topographic map, red line map, wind direction and external access condition obtained by analyzing the project, the design of the total site is completed in REVIT software, the REVIT software is opened to find the topographic surface tool in the body quantity and site command in menu bar, the total design work of the project is completed, and the total design work is sent to each professional in the form of three-dimensional model, wherein the electromechanical profession receives the im odel format file so as to make reference design in BENTLEY software center

S3, creating an equipment model: the method is characterized in that equipment in the electromechanical profession needs to be arranged in the design process, so that equipment specifications are put forward according to actual requirements of projects, equipment is modeled in advance by using BENTLEY software after equipment materials meeting requirements are fed back by factories, a MICROSTATION platform adopting BENTLEY software is built by using the equipment model, a DGN format file is saved as the file, the file is called by each electromechanical profession by adopting different BENTLEY software, and naming, two-dimensional view projection, layer information and equipment information addition are carried out on each piece of equipment while the equipment model is built. After the device models are completed, all the device models are imported into the working environment of the BENTLEY software on the server.

S4, building model creation: the building profession is required to complete the building design, each profession provides respective room condition and provides the room condition to the building profession in advance by the process profession so that the building profession can determine the basic size and the height of the factory building, and then other related professions provide the room condition to the building profession to perfect the building design. The three-dimensional arrangement is applied to BENTLEY software by each related specialty, three-dimensional investment-providing conditions are provided for the building specialty in the form of a 3D DWG file, building design commands are applied to REVIT software according to the received house conditions for each specialty, building BIM forward design is started, the shaft network is arranged, wall bodies are drawn, room layout and other design works are used by referring to the three-dimensional house investment-providing of the related art specialty, and then the three-dimensional house investment-providing of other related specialty is combined, so that building model design is perfected, doors and windows are arranged, and the like, and finally the building BIM forward design is completed.

S5, creating a structural model: the construction profession receives a construction BIM model, a process profession equipment arrangement model and equipment load investment provided by the construction profession, a BIM forward design model of a concrete structure and a BIM forward design model of a steel structure are respectively completed in PKPM and 3D3S software, the structural concrete model completed by the PKPM is directly fed back to the construction profession, the construction profession adopts REVIT software to directly guide the construction profession into the PKPM model through an insert, and the construction profession completes updating of the civil engineering model and feeds back to the relevant profession. And directly exporting a 3D DWG file from the steel structure model completed by the 3D3S, and feeding back the 3D DWG file to each professional for pipeline design and collision check work.

S6, creating a water heating electric model: each specialty begins to carry out mutual fund raising to respective contents such as water consumption, electricity consumption and the like by utilizing three-dimensional design software according to own design requirements, and the water heating electric specialty receives and completes the fund raising of each specialty, begins to carry out BIM forward design work of the specialty, builds a BIM forward design model of each specialty by utilizing BENTLEY software reference to refer to a building structure model, and comprises forward model designs such as water supply and drainage, fire pipelines, heating ventilation pipes, electric lighting, bridge cables, lightning protection grounding and the like.

S7, creating a process model: the process major is to complete the design, the main and auxiliary machine equipment diagram data, the material flow diagram and the system diagram are required to be used as the basis for the process design, after receiving the conditions, BENTLEY software is used for carrying out the three-dimensional design of the process pipeline after receiving various process design input conditions, BENTLEY OPENPLANT piping software is used for carrying out the forward design of the process BIM pipeline of the project by utilizing a classical pipe element grade library configured in the working environment in advance, and a process BIM pipeline model after the design is imported into CAESAR II software for calculation and analysis.

S8, model analysis and examination: after all professions of the project complete BIM forward design models, integrating and summarizing all model files by utilizing light browsing software NAVISWORKS, completing collision checking and clearance analysis of the models, after various collision and clearance problems are solved, starting checking work, and after all checking flows are completed, meeting the drawing conditions.

S9, model output: and (3) respectively outputting two-dimensional construction drawings of the professional models in REVIT, BENTLEY, PKPM and 3D3S software, wherein the output two-dimensional construction drawings have basic drawing marking information, and the unsatisfied requirements are subjected to secondary deepening processing by CAD so as to meet the construction drawing requirements. Meanwhile, each professional BIM model component carries engineering quantity list information to derive an enterprise or national standard engineering quantity list. And the BIM forward model is imported into rendering animation software to complete the project display animation production work, and a designer can carry out final design bottoming work according to the BIM forward design model and the two-dimensional construction diagram after the project design is completed.

The invention provides a standardized forward design method for a garbage incineration power plant based on a BIM technology, which can realize full-specialized BIM forward design of the garbage incineration power plant, avoid the current situation that the traditional BIM design depends on turnover of a mold, provide a mature, reliable and efficient method for BIM forward design transformation of a design institute, solve the problem that the BIM is difficult to land in the forward direction, and greatly improve the forward application coverage rate of the BIM.

The foregoing description of the preferred embodiments of the present invention is not intended to limit the invention, and those skilled in the art may make various modifications and equivalents within the spirit and scope of the invention, and such modifications and equivalents should also be considered as falling within the scope of the technical solution of the present invention.

Claims (7)

1. The standardized forward design method for the garbage incineration power plant based on BIM is characterized by comprising the following steps of:

s1, building a working environment: configuring a layer, a system, a drawing and a preset component library of an item through BENTLEY software, designing a civil engineering specialty by adopting REVIT software, pre-configuring sample files required by an item level, and configuring a family library, an engineering quantity list code, drawing template setting and the like;

s2, creating a total image field model: analyzing a topographic map, a red line map, a wind direction and external access conditions obtained by the place where the project is located, completing the design work of the total map of the project by utilizing a topographic surface tool in REVIT software, and sending the total map to each specialty in a three-dimensional model form;

s3, creating an equipment model: modeling equipment in advance by using BENTLEY software according to the information of each electromechanical professional equipment provided by a manufacturer, and importing all equipment models into the working environment of the BENTLEY software on a server after equipment model creation is completed;

s4, building a building model: after the basic size and the height of the factory building are determined, building design is perfected by building professions, building BIM forward design is started by applying building design commands in REVIT software according to the received house conditions for professional building, and building model design is perfected;

s5, creating a structural model: according to the equipment model provided in the step S3, the building model provided by the building specialty in the step S4 and the equipment load received later are used for lifting materials, and the BIM forward design model of the concrete structure and the steel structure is completed by the structural specialty;

s6, creating a water heating electric model: the BENTLEY software of the water heating electric professional refers to the building model in the cited S4 for building a water heating electric BIM forward design model, and comprises forward model designs of water supply and drainage, fire-fighting pipelines, heating ventilation pipes, electric lighting, bridge cables, lightning protection and grounding and the like;

s7, creating a process model: the technical specialty receives the technical design information, applies BENTLEY OPENPLANT piping software to develop the three-dimensional design of the technical pipeline, and utilizes a classical pipe element grade library configured in the working environment in advance to finish the forward design of the technical BIM pipeline, and then introduces CAESAR II software to calculate and analyze the stress analysis;

s8, model analysis and examination: integrating and summarizing all model files by utilizing light browsing software NAVISWORKS to finish collision check and clearance analysis of the model, and subsequently performing checking work;

s9, outputting a model: and outputting a two-dimensional construction diagram to each professional model through software, leading out an enterprise or national standard engineering quantity list by each professional BIM model component with engineering quantity list information, completing the project display animation production work, and finally performing the design bottoming work.

2. The method for standardized forward design of a BIM-based waste incineration power plant according to claim 1, which is characterized in that: in the step S1, the BENTLEY software working environment is built on the server, and all professions can design under the same working environment.

3. The method for standardized forward design of a BIM-based waste incineration power plant according to claim 1, which is characterized in that: and the sample file in the S1 comprises a family library, an engineering quantity list code and a drawing template.

4. The method for standardized forward design of a BIM-based waste incineration power plant according to claim 1, which is characterized in that: and in the step S3, naming, two-dimensional view projection, layer information and device information are added for each device while the device model is established.

5. The method for standardized forward design of a BIM-based waste incineration power plant according to claim 1, which is characterized in that: in the step S4, the design works of shaft network arrangement, wall body drawing, room layout and the like are required to be arranged by REVIT software with reference to the special three-dimensional house investment of the reference process, and the design of the building model is perfected by combining with the other special three-dimensional house investment.

6. The method for standardized forward design of a BIM-based waste incineration power plant according to claim 1, which is characterized in that: in S5, the structural profession respectively completes BIM forward design models of concrete structures and steel structures in PKPM and 3D3S software, the structural concrete models completed by PKPM are directly fed back to the building profession, the building profession directly imports the PKPM models through plug-ins by adopting REVIT software, the building profession completes updating of the civil model and feeds back to related professions, and the 3D3S completed steel structure model directly exports 3D DWG files and feeds back to each profession for pipeline design and collision check work.

7. The method for standardized forward design of a BIM-based waste incineration power plant according to claim 1, which is characterized in that: in the step S9, REVIT, BENTLEY, PKPM and 3D3S software are adopted to output two-dimensional construction drawings of the professional models respectively, the output two-dimensional construction drawings are provided with basic drawing marking information, and CAD is used for carrying out secondary deepening processing on unsatisfied requirements, so that the requirements of construction drawings are met.