CN113420359A - Method for automatically transmitting parameters to well placement based on REVIT (remote visual inspection) electric power engineering general diagram - Google Patents
Method for automatically transmitting parameters to well placement based on REVIT (remote visual inspection) electric power engineering general diagram Download PDFInfo
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- CN113420359A CN113420359A CN202110747953.4A CN202110747953A CN113420359A CN 113420359 A CN113420359 A CN 113420359A CN 202110747953 A CN202110747953 A CN 202110747953A CN 113420359 A CN113420359 A CN 113420359A
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F30/00—Computer-aided design [CAD]
- G06F30/10—Geometric CAD
- G06F30/13—Architectural design, e.g. computer-aided architectural design [CAAD] related to design of buildings, bridges, landscapes, production plants or roads
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F30/00—Computer-aided design [CAD]
- G06F30/20—Design optimisation, verification or simulation
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T17/00—Three dimensional [3D] modelling, e.g. data description of 3D objects
- G06T17/10—Constructive solid geometry [CSG] using solid primitives, e.g. cylinders, cubes
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F2119/00—Details relating to the type or aim of the analysis or the optimisation
- G06F2119/02—Reliability analysis or reliability optimisation; Failure analysis, e.g. worst case scenario performance, failure mode and effects analysis [FMEA]
Abstract
The invention relates to a method for automatically transmitting a parameter and distributing a well based on a power engineering general diagram of REVIT. The method comprises the following steps: (1) generating and creating a site; (3) dividing the field: picking up internal components of the field including roads and enclosing walls, projecting the internal components to the field generated in the step (2), and dividing the field to obtain real field boundary information; (4) generating a field with a slope according to the slope and elevation information; (5) establishing a three-dimensional pipeline model; (6) establishing a related well family, setting parameters related to the generated bottom hole elevation as example parameters, and loading the example parameters into a project; (7) placing a well: selecting a well to be placed in a window of the well, dragging the well to a project, generating an example at the position where the well is to be placed, continuously generating a plurality of wells, and placing the wells by pressing an ESC bond; (8) setting the well height: and in the three-dimensional view, adjusting to the upper view, sequentially arranging the pipelines around each well, generating a bottom elevation by one key, and finishing cutting the pipelines penetrating into the wells.
Description
Technical Field
The invention belongs to the field of three-dimensional digitization, relates to the field of modeling of a digitized three-dimensional design model, is applied to an automatic parameter transmission placement well of a three-dimensional design model of electric power engineering, and particularly relates to a method for automatically parameter transmission and well distribution of an electric power engineering general diagram based on REVIT.
Background
BIM three-dimensional digital modeling, wherein the BIM process utilizes centralized digital three-dimensional modeling as a core resource. The BIM model is a model formed by cooperation of multiple persons, professional resources and teams. Each building participant plans the data model while also allowing other people's rights and data modifications. The BIM model consists of detailed BIM units such as doors, walls, equipment, etc. BIM modeling will greatly improve work efficiency, that is, it can prevent potential conflicts that may occur to a building project during the planning phase. BIM systems allow architects and designers to more quickly and easily understand and implement features of gating, automation, and other products.
Currently, the three-dimensional modeling software of BIM is seven series: revit series software, Bentley series software, ArchicaD series software for drawing soft, Tekla series software for Tianbao, CATIA series software for Dasuo, MagiCAD series software for Guangdong and Rhino series software. The Revit series software supports design and construction drawings of all stages aiming at specific professional building design and document systems. The 3D software is a Building Information Model (BIM) solution oriented to civil engineering design and documentation. The AutoCAD Civil3D can help Civil engineering professionals engaged in transportation, land development and water conservancy projects to keep coordination and consistency, explore design schemes more easily and efficiently, analyze project performance and provide documents which are consistent with each other and have higher quality, all in familiar AutoCAD environments.
However, Revit as general software cannot meet specific specialties, and on the basis, Revit as BIM modeling platform software provides basic functions for users to perform BIM modeling. The general modeling platform provides an API (application Programming interface) for a third party to do Revit secondary development. The result of the development is a Revit plug-in that can create models and read BIM model information. Batch operation and intelligent operation are realized, Revit secondary development with other software can be opened, and some simple and repeated work can be completed by a computer instead of people, so that the workload of engineers is greatly reduced.
The prior art has the following defects:
1. in Revit three-dimensional modeling, hosts of various components such as wells, walls or cable ducts need to be floor slabs, and floor slab attributes are used for building a new site in the three-dimensional modeling. When the field is built according to the outer contour line of the field or the sketch of the CAD, the details inside the field are complex, and in addition, the field is not flat and cannot be built quickly, so that mistakes are easy to occur, redundant plates are additionally added, the appearance is influenced, and multiple times of checking and reciprocating modification are needed.
2. After the field is drawn in the first step, the manual confirmation of the details in the field, particularly the places with slopes, is easy to make mistakes and has low efficiency.
3. When various wells need to be placed in the well-arranged pipelines, the bottom elevation of the well is usually calculated manually according to the diameter of a well cavity, the site elevation and the pipelines penetrating into the well. Especially, the complex slope of site and pipeline has brought the degree of difficulty for the calculation of bottom elevation, and the calculation precision is more unable to guarantee, often through increaseing the buried depth, has improved the cost in a large number, brings the problem of collision even.
Disclosure of Invention
The invention aims to provide a method for automatically transmitting and distributing power engineering general diagrams based on REVIT (remote operated interactive technology) aiming at the characteristics that when various wells are placed in a power engineering pipe network, the bottom elevation is usually calculated manually according to the surrounding environment, the efficiency is low, the calculated amount is large, and the error is high.
In order to achieve the purpose, the technical scheme of the invention is as follows: a method for automatically transmitting a power engineering general diagram to a well layout based on a REVIT comprises the following steps:
(1) importing a CAD two-dimensional field and a road model into Revit or generating a field according to the elevation point data of CIVIL 3D;
(2) a site is created: picking up a closed outer contour line of a field to generate the field, wherein the property of the field is a floor slab;
(3) dividing the field: picking up internal components of the field including roads and enclosing walls, projecting the internal components to the field generated in the step (2), and dividing the field to obtain real field boundary information;
(4) generating a field with a slope according to the slope and elevation information;
(5) establishing a three-dimensional pipeline model;
(6) establishing a related well family, setting parameters related to the generated bottom hole elevation as example parameters, and loading the example parameters into a project;
(7) placing a well: selecting a well to be placed in a window of the well, dragging the well to a project, generating an example at the position where the well is to be placed, continuously generating a plurality of wells, and placing the wells by pressing an ESC bond;
(8) setting the well height: and in the three-dimensional view, adjusting to the upper view, sequentially arranging the pipelines around each well, generating a bottom elevation by one key, and finishing cutting the pipelines penetrating into the wells.
In an embodiment of the present invention, the steps (1) and (2) are specifically implemented as follows: importing two-dimensional boundary information of CAD or a site two-dimensional boundary model of CIVIL3D into Revit, clicking a created site to pick up a closed outer contour line to generate a basic site, and setting the attribute of the generated site as a floor slab; the floor in Revit can be provided with elevation, gradient, starting and mapping, and meets various requirements of the field.
In an embodiment of the present invention, the parameter related to the bottom elevation in step (6) includes: well burial depth, top plate thickness, walling crib height, ground height.
In one embodiment of the present invention, in step (8), the well height, i.e. the bottom hole elevation, is calculated as follows:
the bottom elevation = the top plate elevation (well burial depth-top plate thickness-well curb height + ground height) = the lowest elevation of the pipeline-bottom plate thickness.
Compared with the prior art, the invention has the following beneficial effects: according to the method, a set of plug-in units for automatically placing various wells are independently researched and developed according to the revitAPI, the bottom elevation is automatically calculated according to the surrounding environment, the operation is carried out by clicking two or three steps with a mouse, the field can be generated and the arrangement of the field and the wells can be divided in less than one minute, the plug-in units are convenient to install, high in calculation accuracy and good in interactivity, the working efficiency and the accuracy are greatly improved, and the manufacturing cost is saved.
Drawings
FIG. 1 is a basic flow diagram of the method of the present invention.
Fig. 2 is a schematic view of a divided site with a slope.
Fig. 3 is a schematic view of a pipeline.
FIG. 4 is a schematic diagram of a well family.
FIG. 5 is a parameter diagram of an example of a setup.
FIG. 6 is a schematic drawing of a drag producing well.
FIG. 7 is an example of a well placement pattern of the present invention.
Figure 8 is an example of a tubing run-in well diagram of the present invention.
FIG. 9 is an example of a selected piping pattern around a well according to the present invention.
FIG. 10 is an example of the automatic generation of a bottom hole elevation and cut pipe map of the present invention.
Detailed Description
The technical scheme of the invention is specifically explained below with reference to the accompanying drawings.
The invention discloses a method for automatically transmitting a parameter and distributing a well based on an electrical engineering general diagram of REVIT. The key points of the method comprise: (1) importing a CAD two-dimensional field and a road model into Revit or generating a field according to the elevation point data of CIVIL 3D; (2) a site is created: picking up a closed outer contour line of a field to generate the field, wherein the property of the field is a floor slab; (3) dividing the field: picking up site internal components such as roads and enclosing walls, projecting the components to the site in the step (2), and dividing the site to obtain real site boundary information; (4) generating a field with a slope according to the slope and elevation information; (5) establishing a three-dimensional pipeline model; (6) the relevant well families are established and the parameters related to generating the bottom hole elevation are set as instance parameters and loaded into the project. (7) Placing a well: selecting a well to be placed in a window of the well, dragging the well to the project, generating an example at the position where the well is to be placed, and continuously generating a plurality of wells to be placed in an ESC bond bundle. (8) Setting the well height: and in the three-dimensional view, adjusting to the upper view, sequentially arranging the pipelines around each well, generating a bottom elevation by one key, and finishing cutting the pipelines penetrating into the wells.
The following are specific implementation examples of the present invention.
FIG. 1 shows the basic flow of the method, firstly, the CAD two-dimensional boundary information and the site two-dimensional boundary model of CIVIL3D are imported into Revit, and the site is clicked to create a site to pick up a closed outer contour line to generate a basic site; then clicking a site division button, picking up boundaries such as an outer wall, a road and the like, and automatically projecting the system to a basic site to finish site division; and then inputting elevation and setting gradient directions to the divided field to construct a real field. The entire pipeline is then constructed. And establishing a family file of related wells, setting parameters influencing the elevation of the bottom of the well as example parameters, and loading the example parameters into the project after the example parameters are completed. And clicking the arrangement well, dragging the related well to the model, and clicking a left mouse button at the corresponding position to continuously place the well. And finally, clicking to set the well height, sequentially selecting surrounding pipelines for the well in the last step, and automatically calculating the well bottom elevation and cutting the pipelines by the system to finish the arrangement of the well.
Description of the flow:
step one, generating a producing area outer boundary.
The outer boundary of the site is the approximate range of the model site, and the requirement on the precision of the inner boundary of the site is low. Can be drawn by importing two-dimensional boundaries of CAD or CIVIL3D elevation information, etc. Since the host of the well, cable trench, etc. is the floor, the property of the generated site should be set as the floor. The floor in Revit can be provided with elevation, gradient, starting, mapping and the like, and meets various requirements of the site.
Step two, dividing the field
As shown in fig. 2, the inner boundary of the field is complex, the manual line drawing is complex, the accurate drawing cannot be completed, and errors are easy to occur. Through the production area dividing function of the invention, fool drawing can be realized. Pick up the interior boundary contour line of enclosure, road etc. the system will be automatic with these interior boundary lines projection to floor top surface, look for closed return circuit, accomplish the place and cut apart, improve drawing efficiency and precision greatly.
And step three, inputting gradient and elevation information to complete site construction.
Because the field is not flat, the field with a large number of elevation items is mostly flat except for the landscape function. In order to better enable the floor slab to be attached to the ground, the ground needs to be leveled, and elevation information are input so as to obtain the elevation information of the top surface of the floor slab, which influences the elevation of the bottom of the well.
And step four, constructing a pipeline.
As shown in fig. 3, the pipeline is the surrounding environment of the well, and the system which is closely related to the bottom elevation of the well and the lowest bottom elevation of the pipeline intersected with the well automatically calculates and draws the bottom elevation and the lowest bottom elevation, and displays the bottom elevation in a three-dimensional model in a quasi-tangential mode.
Step five, establishing a well group
As shown in fig. 4 and 5, a family of wells is established in the family module, and a reference elevation is associated with the upper top surface of the plate. And compiling the properties of the family, wherein the properties associated with the bottom elevation calculation formula of the well are as follows: attributes such as well burial depth, top plate thickness, height of a walling crib, height from the ground and the like are set as example parameters.
Step six, placing the well
As shown in fig. 6, clicking the arrangement well, clicking the corresponding well, dragging to the project, continuously clicking the left key at a proper position to generate a plurality of wells, and pressing the ESC key bundle to operate, wherein the generated bottom hole elevations are the default values.
Step seven, setting the well height
The calculation formula of the bottom hole elevation is as follows:
shaft bottom elevation = top plate elevation (well burial depth-top plate thickness-well ring height + ground height) = lowest pipeline elevation-bottom plate thickness
And sequentially selecting wells according to the prompt of the status bar, enabling the pipelines penetrating around the wells to penetrate into the wells, automatically changing the elevation parameters of the bottoms of the wells by the system, and simultaneously cutting off the parts of the pipelines extending into the wells to finally finish the arrangement of the wells.
Fig. 7-10 show typical application examples of the present invention, wherein fig. 7 is an example of a well placement diagram of the present invention, fig. 8 is an example of a pipe penetration diagram of the present invention, fig. 9 is an example of a pipe diagram around a selected well of the present invention, and fig. 10 is an example of an automatic generation of bottom hole elevation and cut pipe diagram of the present invention.
The above are preferred embodiments of the present invention, and all changes made according to the technical scheme of the present invention that produce functional effects do not exceed the scope of the technical scheme of the present invention belong to the protection scope of the present invention.
Claims (4)
1. A method for automatically transmitting and distributing power engineering general diagrams based on REVIT is characterized by comprising the following steps:
(1) importing a CAD two-dimensional field and a road model into Revit or generating a field according to the elevation point data of CIVIL 3D;
(2) a site is created: picking up a closed outer contour line of a field to generate the field, wherein the property of the field is a floor slab;
(3) dividing the field: picking up internal components of the field including roads and enclosing walls, projecting the internal components to the field generated in the step (2), and dividing the field to obtain real field boundary information;
(4) generating a field with a slope according to the slope and elevation information;
(5) establishing a three-dimensional pipeline model;
(6) establishing a related well family, setting parameters related to the generated bottom hole elevation as example parameters, and loading the example parameters into a project;
(7) placing a well: selecting a well to be placed in a window of the well, dragging the well to a project, generating an example at the position where the well is to be placed, continuously generating a plurality of wells, and placing the wells by pressing an ESC bond;
(8) setting the well height: and in the three-dimensional view, adjusting to the upper view, sequentially arranging the pipelines around each well, generating a bottom elevation by one key, and finishing cutting the pipelines penetrating into the wells.
2. The method for automatically transmitting the power engineering general diagram to the well logging based on the REVIT as claimed in claim 1, wherein the steps (1) and (2) are implemented as follows: importing two-dimensional boundary information of CAD or a site two-dimensional boundary model of CIVIL3D into Revit, clicking a created site to pick up a closed outer contour line to generate a basic site, and setting the attribute of the generated site as a floor slab; the floor in Revit can be provided with elevation, gradient, starting and mapping, and meets various requirements of the field.
3. The method for automatically referring to the well distribution based on the REVIT electric power engineering general diagram according to claim 1, wherein the parameters related to the bottom elevation in the step (6) comprise: well burial depth, top plate thickness, walling crib height, ground height.
4. The method for automatically transmitting the electric power engineering general map to the well distribution based on the REVIT as claimed in claim 1, wherein in the step (8), the calculation formula of the well height, namely the bottom hole elevation, is as follows:
the bottom elevation = the top plate elevation (well burial depth-top plate thickness-well curb height + ground height) = the lowest elevation of the pipeline-bottom plate thickness.
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Cited By (2)
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CN115147440B (en) * | 2022-07-12 | 2024-04-19 | 中国建筑西南设计研究院有限公司 | Automatic generation method of basic slope line based on surface area clipping method |
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CN115147440A (en) * | 2022-07-12 | 2022-10-04 | 中国建筑西南设计研究院有限公司 | Automatic basic slope-making line generation method based on surface area cutting method |
CN115147440B (en) * | 2022-07-12 | 2024-04-19 | 中国建筑西南设计研究院有限公司 | Automatic generation method of basic slope line based on surface area clipping method |
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