CN113626904A - Three-dimensional process commander layout method for automobile industry factory building - Google Patents
Three-dimensional process commander layout method for automobile industry factory building Download PDFInfo
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Abstract
The invention discloses a method for arranging three-dimensional process commander drawings of an automobile industrial factory building, which comprises the following steps: step one, drawing a track line of a pre-planned command picture in a view of Bentley Microstation software. And step two, creating a design tool window in Bentley Microstation software. And step three, determining parameters, positions and functions of the assembly workpiece. And step four, calling a shape tool of BentleyMicrostation software, selecting information of the assembled workpiece, and transmitting the information to a design tool. And fifthly, self-defining the placement position of the assembly workpiece. And step six, calling an interface, and combining a software sweeping function to enable the shape to sweep the adult along the path to complete the layout of the command map. The command picture can be automatically generated by one key, the planning and designing efficiency of the command picture is improved, the time distribution accuracy is obviously improved, the operation is simple and convenient, the time cost is saved more than that of the original mode of drawing one by one, and the labor amount of designers is reduced.
Description
Technical Field
The invention relates to the technical field of commander image processing, in particular to a method for arranging three-dimensional process commander images of an automobile industrial factory building.
Background
In the design of the automobile industrial factory building, a process commander has a very important function, and in the initial planning and design stage of the automobile industrial factory building, the arrangement schemes of various production lines and production equipment are designed and optimized by the related professions of the process, and after the various process equipment meet the production requirements, the planning and design of the commander is started, and the commander represents the design result of the trend of the main line shared by all professions and the vertical space requirement in the factory building.
The design mode at the present stage is a process three-dimensional planning design based on Bentley Microstation software, wherein the planning design of the commander is carried out by utilizing an original design tool of the software, pipelines are used for creating 3D models one by using a three-dimensional entity tool, three-dimensional forward design is carried out, such as air pipes, water pipes, pipeline supporting and hanging frames and the like, the entity creating tool is directly utilized for creating and trimming step by step along a path, after the design is carried out one by one and class by class, various pipelines and channels are combined, and the result is the commander.
In the design mode at the present stage, 3D model creation needs to be carried out on each independent object, integration is carried out again, and a result is finally formed, so that time and labor are wasted, and if a scheme is modified, the workload of modification is huge, basic operation is adopted, and the waste of human resources is caused.
Disclosure of Invention
The invention aims to provide a method for arranging three-dimensional process commander drawings of a factory building in the automobile industry so as to solve the problems in the background technology.
In order to achieve the purpose, the invention provides the following technical scheme: a three-dimensional process commander layout method for an automobile industrial factory building comprises the following steps:
step one, drawing a track line of a pre-planned command picture in a view of Bentley Microstation software.
And step two, creating a design tool window in Bentley Microstation software.
And step three, determining parameters, positions and functions of the assembly workpiece.
And step four, calling a shape tool of Bentley Microstation software, selecting information of the assembled workpiece, and transmitting the information to a design tool.
And fifthly, self-defining the placement position of the assembly workpiece.
And step six, calling an interface, and combining a software sweeping function to enable the shape to sweep the adult along the path to complete the layout of the command map.
Preferably, the design tool in the second step is compiled by codes, design parameters are combined with parameters required in a Bentley micro simulation software tool, and self functions of intelligent lines, entities, scanning, copying and the like of the Bentley micro simulation software are utilized to carry out batch processing on the assembly workpieces.
Preferably, the placement position of the assembly workpiece in the fifth step is defined as a side view direction.
Preferably, the assembling of the assembling workpiece in the third step, the fourth step and the fifth step includes assembling of a pipeline and a support hanger.
Preferably, the pipe parameter selection includes shape, cross-sectional size, and the like.
Preferably, a C # table data function in the design tool in the second step is called, the number of layers and the height of the support hanger are controlled, the size of the support hanger is created, and the number of layers and the rack pitch of the support hanger are defined.
Compared with the prior art, the invention has the beneficial effects that: a method for arranging three-dimensional process commander images in factory buildings in the automobile industry is characterized in that a design tool is developed in Bentley Microstation software and codes are compiled by the design tool, so that design parameters are combined with parameters required in the Bentley Microstation software, pipelines are arranged in batches after the information such as pipeline parameter positions and the like is input, and support hangers are arranged in batches after the information such as the size, the layer number, the layer height, the rack spacing and the like of the support hangers is input.
Drawings
FIG. 1 is a flow chart of a three-dimensional process commander layout method according to the present invention;
FIG. 2 is a schematic view of the input parameters of the cradle of the present invention.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-2, the present invention provides the following technical solutions: a three-dimensional process commander layout method for an automobile industrial factory building comprises the following steps:
step one, drawing a track line of a pre-planned command picture in a view of Bentley Microstation software. Used for providing a layout path for the commander.
And step two, creating a design tool window in Bentley Microstation software. And a design tool is created on a development interface of Bentley Microstation software for assembling the batch arrangement of workpieces, so that the planning efficiency of the commander is improved.
And step three, determining parameters, positions and functions of the assembly workpiece. Before the assembly workpieces are arranged, design parameters, arrangement positions and actual functions of the assembly workpieces need to be determined, and subsequent arrangement errors are avoided.
And step four, calling a shape tool of Bentley Microstation software, selecting information of the assembled workpiece, and transmitting the information to a design tool. Inputting parameter information of the assembly workpiece to enable the parameter information to be matched with parameters in the design tool.
And fifthly, self-defining the placement position of the assembly workpiece. And accurately rotating the distribution position of the assembly workpiece.
And step six, calling an interface, and combining a software sweeping function to enable the shape to sweep the adult along the path to complete the layout of the command map. Finally, the assembly workpieces are arranged in batches according to the input requirements, the design efficiency of the commander is improved, the arrangement accuracy is obviously improved, the operation is simple and convenient, the time cost is saved, and the labor amount of designers is reduced.
Specifically, the design tool in the second step is compiled by codes, design parameters are combined with parameters required in a Bentley micro simulation software tool, and self functions of intelligent lines, entities, scanning, copying and the like of the Bentley micro simulation software are utilized to perform batch processing on the assembly workpieces. The design tool is used for matching the input design parameters, executing specified commands, quickly performing a large amount of repeated layout operations and improving the layout efficiency of the commander.
Specifically, the placement position of the assembly workpiece in the fifth step is defined as a side view direction.
Specifically, the assembling of the assembling work in the third step, the fourth step and the fifth step includes assembling of a pipe and a support hanger.
Specifically, the pipe parameter selection includes shape, cross-sectional size, and the like. The shape of the pipe is selected to be round or square
Specifically, a C # table data function in the design tool in the second step is called, the number of layers and the height of the support hanger are controlled, the size of the support hanger is created, and the number of layers and the rack pitch of the support hanger are defined. And (3) creating a single support and hanger, calling the copy function of the software through an interface tool, and inputting various self-defined parameters into the support and hanger according to the path to finally complete the creation of the whole command picture module.
The specific operation process of the commander layout is as follows:
1) preparing a proper track line;
2) clicking a command diagram layout button, and then clicking a prepared trajectory line by a left key;
3) popping up a command picture tool window as shown in the figure, and automatically converting the view into a left view at the moment;
4) inputting relevant parameters: [ Pitch ] units are meters (m), other units are millimeters (mm);
5) setting parameters of bracket length, bracket height and layer height, clicking to add, wherein the right-side list is a layer parameter list, and clicking to clear if parameters need to be modified;
6) after the completion list is set, clicking (placing) can generate a first support at the starting position of the track line, and automatically adjusting the view to the position of the support;
7) setting the radius of a circular pipeline, clicking (adding), and adding a circle at a proper position in the bracket, wherein the same principle is applied to a rectangular pipeline;
8) when modification is needed, clicking a self-contained selection function, deleting the generated rectangle or circle, and then continuing clicking the shape needed (adding);
9) after arranging the command picture interface picture, clicking (determining) to finish the arrangement of the command picture;
the working principle is as follows: writing codes in Bentley Microstation software, developing a design tool, combining the design parameters of an assembly workpiece with the parameters required in the Bentley Microstation software tool, inputting various parameters of a pipeline or a supporting and hanging bracket, combining a software sweeping function to sweep shape along a path into a whole body, the rapid batch arrangement of pipelines can be realized, the parameters of the supporting and hanging frames are input, the size of the supporting and hanging frames, the layer number of the supporting and hanging frames, the spacing between the supporting and hanging frames and the like are controlled, the supporting and hanging frames are automatically arranged in batches, finally, the commander is automatically generated by one key, the arrangement of the commander is very convenient through the development of a design tool, the method is simple to operate, easy to operate, and capable of abandoning the original one-by-one drawing mode, greatly improving the planning and designing efficiency of the commander, remarkably improving the accuracy, saving the time cost, fully exerting the imagination and the execution force of designers, and reducing the cost of human resources.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (6)
1. A three-dimensional process commander graph arrangement method for an automobile industrial factory building is characterized by comprising the following steps: the method comprises the following steps:
step one, drawing a track line of a pre-planned command picture in a view of Bentley Microstation software.
And step two, creating a design tool window in Bentley Microstation software.
And step three, determining parameters, positions and functions of the assembly workpiece.
And step four, calling a shape tool of Bentley Microstation software, selecting information of the assembled workpiece, and transmitting the information to a design tool.
And fifthly, self-defining the placement position of the assembly workpiece.
And step six, calling an interface, and combining a software sweeping function to enable the shape to sweep the adult along the path to complete the layout of the command map.
2. The arrangement method of the three-dimensional process commander map of the factory building in the automobile industry according to claim 1, characterized in that: and the design tool in the second step is prepared by coding, combines the design parameters with the parameters required in the Bentley Microstation software tool, and performs batch processing on the assembled workpieces by using the self functions of intelligent lines, entities, scanning, copying and the like of the Bentley Microstation software.
3. The arrangement method of the three-dimensional process commander map of the factory building in the automobile industry according to claim 2, characterized in that: and the placing position of the assembly workpiece in the fifth step is defined as a side view direction.
4. The arrangement method of the three-dimensional process commander map of the factory building in the automobile industry according to claim 3, characterized in that: the assembling of the assembling workpiece in the third step, the fourth step and the fifth step comprises assembling of a pipeline and a support hanger.
5. The arrangement method of the three-dimensional process commander map of the factory building in the automobile industry according to claim 4, characterized in that: the pipe parameter selection includes shape, cross-sectional dimension, etc.
6. The arrangement method of the three-dimensional process commander map of the factory building in the automobile industry according to claim 3, characterized in that: and calling a C # table data function in the design tool in the step two, controlling the layer number and the layer height of the supporting and hanging frame, creating the size of the supporting and hanging frame, and defining the layer number and the frame interval of the supporting and hanging frame.
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Address after: No. 1958, Chuangye street, Changchun automobile economic and Technological Development Zone, Changchun City, Jilin Province, 130011 Applicant after: The Ninth Design and Research Institute of Machinery Industry Co.,Ltd. Address before: No. 1958, Chuangye street, Changchun automobile economic and Technological Development Zone, Changchun City, Jilin Province, 130011 Applicant before: Machinery Industry Ninth Design and Research Institute Co.,Ltd. |
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