CN114925435A - Method for manufacturing BIM family of assembly type pipe-well pipe assembly module - Google Patents

Abstract

The invention provides a method for manufacturing a BIM family of an assembly type pipe well pipe group module, which is established based on Autodesk Revit software, meets the precision requirement of the assembly type module, accords with the actual requirement of field installation, has the functions of automatically calculating and arranging the distance between a pipeline and a bracket and replacing a module component family according to the requirement, can effectively improve the modeling precision, the modeling efficiency and the practicability of the assembly type BIM and ensures the floor implementation of the assembly type technology.

Description

Method for manufacturing assembly type pipe well pipe group module BIM family

Technical Field

The invention belongs to the technical field of BIM family manufacturing, and particularly relates to a method for manufacturing a BIM family of an assembly type pipe-well pipe group module.

Background

In recent years, the assembly type technology has become a necessary trend for future development of the construction industry. Meanwhile, with the continuous development of the BIM technology, the tool for engineering construction management datamation is gradually applied deeply in construction engineering, the accuracy requirement for building the BIM model is higher and higher, and the automatic device review software is not internally provided with an assembly module BIM family conforming to the assembly technology. In the practice of building the assembly type BIM model, if an assembly type tube well pipeline module BIM family needs to be used, the assembly can be carried out only on the basis of a component family which is simple, rough and can not meet the field installation requirement in a shaping mode by utilizing the built-in placing and aligning functions of software; the pipe group module BIM family that adopts this kind of mode to make does not satisfy assembled module precision demand, has seriously influenced the accuracy of model, is not conform to the on-the-spot installation demand, has restricted the falling to the ground of assembled tube-well from the source and has implemented, and can not automatic adjustment pipeline and support arrangement interval, is showing and is reducing work efficiency, can not replace module component family as required, has promoted the establishment degree of difficulty of model by a wide margin. Therefore, it is necessary to invent a new method for manufacturing a Building Information Module (BIM) family of assembled tubular well tubular assemblies, which solves the existing problems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a method for manufacturing an assembly type tube well tube group module BIM family, which solves the problems that the existing assembly type tube well tube group module BIM family does not accord with the assembly type technical precision, does not meet the field installation requirement, cannot automatically adjust the arrangement distance of pipelines and supports, and does not replace module components according to the requirement.

The present invention achieves the above-described object by the following technical means.

A method for manufacturing a BIM family of assembled tubular well pipe group modules comprises the following steps:

step 1: in Autodesk Revit software, a new family is created by using a metric conventional family template file based on a surface, a length control reference line of a pipe group pipeline is drawn in a facade view, and a pipe middle distance control reference line of the pipe group pipeline is drawn in a plane view; marking the size of each reference line, and giving all size marking parameters, wherein the parameters comprise the length of the pipe section and the distance between adjacent pipes;

and 2, step: establishing a pipe group pipeline model by using a stretching command, binding the center of a pipeline circle to the intersection point of a central front/rear reference line and a middle distance control reference line of each pipe in a plane view by using an alignment command, carrying out diameter marking, and then adding parameters to all diameter marks, wherein the added parameters comprise the diameters of the pipes;

and 3, step 3: in a vertical view, using an alignment command to bind one end of the pipeline to a datum plane and bind the other end of the pipeline to a length control reference line;

and 4, step 4: performing parameter logical processing on the parameters of the space between the adjacent pipelines, and giving a space parameter formula to the parameters;

and 5: adding the number of group parameter pipe groups, adding visibility parameters to each pipe model, endowing a visibility parameter logic formula with the visibility parameters, and operating the logic formula to control the display number of the pipe groups according to the pipe group pipe number parameters;

and 6: creating a family of face-based pipe-carrier-containing pipe hoops, creating a family of line-based channel steels;

and 7: drawing a distance control reference line of the pipeline support in a plane view, marking the size, and adding group parameters;

and step 8: compiling a logic algorithm for automatically identifying the maximum pipe diameter of the pipe group, giving an algorithm formula to control size marking of the spacing of the pipe supports, and automatically controlling the spacing of the pipe supports through the logic algorithm formula;

and step 9: based on the pipe bracket distance control reference line, creating a pipe hoop model, binding the pipe hoop diameter parameters with the pipe diameter parameters, binding the pipe hoop model with the pipe middle distance control reference line of each pipe, and binding the pipe hoop elevation offset with the corresponding family parameters in the step 7;

step 10: establishing a transverse channel steel model based on the pipeline bracket spacing control reference line, wherein two ends of the transverse channel steel are bound to the pipeline bracket spacing control reference lines on two sides, and the vertical surface offset is respectively bound to the corresponding family parameters in the step 7;

step 11: based on the spacing control reference line of the pipeline supports, a vertical frame channel steel model is established and is bound with a transverse channel steel model;

step 12: sequentially creating pipeline connecting pieces at the upper opening and the lower opening of the pipe group pipeline model, and binding corresponding diameter parameters;

step 13: family files are saved for use.

Further, in step 4, the distance parameter formula is as follows:

in the formula, m is a positive integer and represents a pipeline number; after a distance parameter formula is given, the distance between the adjacent pipelines is automatically controlled through the diameter parameters of the pipelines.

Further, the group parameters in step 7 include an upper channel steel placement height, a middle channel steel placement height, a lower channel steel placement height, an upper pipe clamp placement height, and a lower pipe clamp placement height.

Further, in step 9, there are two sets of pipe clamp models, including an upper pipe clamp and a lower pipe clamp, where the number of each set of pipe clamp models corresponds to the number of pipes, and the offset of the vertical surface of one set of pipe clamp is bound to the placement height of the upper pipe clamp, and the offset of the vertical surface of the other set of pipe clamp is bound to the placement height of the lower pipe clamp.

Further, in the step 10, the number of the transverse channel steel models is three, the transverse channel steel models are respectively an upper transverse channel steel, a middle transverse channel steel and a lower transverse channel steel, and the vertical offset of the upper transverse channel steel, the middle transverse channel steel and the lower transverse channel steel is respectively bound to the upper channel steel placement height, the middle channel steel placement height and the lower channel steel placement height.

Further, in step 11, the number of the pipelines is nine, the number of the vertical frame channel steel models in each group is five, two ends of the first group of vertical channel steel models are bound to the boundaries of the two horizontal channel steel models in the upper part and the middle part respectively, two ends of the second group of vertical channel steel models are bound to the boundaries of the two horizontal channel steel models in the middle part and the lower part respectively, the positions of the first and fifth vertical frame channel steel in each group are bound to the left and right ends of the horizontal channel steel models respectively, and the second, third and fourth vertical frame channel steel in each group are bound to the distance control reference line in the middle of the third pipeline, the fifth pipeline and the seventh pipeline respectively.

The invention has the following beneficial effects:

compared with the existing method for manufacturing the assembly type tube well tube group module BIM family, the invention establishes the assembly type tube well tube group module BIM family which meets the precision requirement of the assembly type module, accords with the actual requirement of field installation, has the functions of automatically calculating and arranging the distance between pipelines and supports and can replace the module component family according to the requirement based on the Autodesk Revit software, can effectively improve the modeling precision, the modeling efficiency and the practicability of the assembly type BIM, and ensures the ground-to-ground implementation of the assembly type technology.

Drawings

FIG. 1 is a three-dimensional schematic diagram of a modular assembly of a tubular well casing of the present invention.

Detailed Description

The invention will be further described with reference to the following figures and specific examples, without limiting the scope of the invention thereto.

The numbers "1", "2", "3" and the like mentioned in the present embodiment are used to indicate the numbers of the pipes.

The invention relates to a method for manufacturing a BIM group of an assembly type pipe-well pipe group module, which comprises the following steps:

step 1: in Autodesk Revit software, a new family is created by using a metric conventional family template file based on a surface, a length control reference line of a pipe group pipeline is drawn in a facade view, and a pipe middle distance control reference line of the pipe group pipeline is drawn in a plane view; the pipeline of the pipe group comprises a pipeline 1, a pipeline 2, a pipeline 3, a pipeline 4, a pipeline 5, a pipeline 6, a pipeline 7, a pipeline 8 and a pipeline 9;

dimensioning each reference line and giving all dimensioning parameters including the length of the pipe section, the distance between the pipeline 1 and the pipeline 2, the distance between the pipeline 2 and the pipeline 3, the distance between the pipeline 3 and the pipeline 4, the distance between the pipeline 4 and the pipeline 5, the distance between the pipeline 5 and the pipeline 6, the distance between the pipeline 6 and the pipeline 7, the distance between the pipeline 7 and the pipeline 8 and the distance between the pipeline 8 and the pipeline 9;

and 2, step: using a stretching command to create a pipe group pipeline model, using an alignment command to bind the center of a pipeline circle to the intersection point of a central front/back reference line and each pipe middle distance control reference line in a plane view, carrying out diameter marking, and then adding parameters to all diameter markings, wherein the parameters comprise the diameters of each pipeline, and are respectively as follows: diameter 1, diameter 2, diameter 3, diameter 4, diameter 5, diameter 6, diameter 7, diameter 8, diameter 9;

and step 3: in a vertical view, using an alignment command to bind one end of the pipeline to a datum plane and bind the other end of the pipeline to a length control reference line;

and 4, step 4: performing parameter logical processing on the pipeline interval related parameters in the step 1, and giving an interval parameter formula to the pipeline interval related parameters, wherein the interval parameter formula is as follows:

in the embodiment, m is a positive integer, and m is less than or equal to 9; the spacing between the pipes can be automatically controlled by the pipe diameter-related parameter given by the spacing parameter formula, for example, the spacing between the pipes 2 and 3 can be calculated by the formula

Namely, the value of the parameter of the distance between the pipeline 2 and the pipeline 3 is determined by the values of the two parameters of the diameter 2 and the diameter 3;

and 5: adding the number of group parameter pipe groups, adding visibility parameters to each pipe model, endowing a visibility parameter logic formula with the visibility parameters, and operating the logic formula to control the display number of the pipe groups according to the pipe group pipe number parameters;

and 6: querying national standard HG/T21629 and 1999 pipe support standard diagram (1) to create a face-based channel steel family containing a pipe support hoop, querying national standard GB/T706 and 2016 (Hot rolled section steel) to create a line-based channel steel family;

and 7: drawing a pipeline bracket spacing control reference line in a plan view, carrying out size marking, and adding group parameters, wherein the group parameters comprise an upper channel steel placement height, a middle channel steel placement height, a lower channel steel placement height, an upper pipe hoop placement height and a lower pipe hoop placement height;

and step 8: compiling a logic algorithm for automatically identifying the maximum pipe diameter of the pipe group, giving an algorithm formula to control size labels for the spacing of the pipe supports, and automatically controlling the spacing of the pipe supports through the logic algorithm formula;

and step 9: based on the spacing control reference line of the pipeline support, two groups of pipe hoop models are created, namely an upper pipe hoop and a lower pipe hoop, and the number of each group of pipe hoop models corresponds to the number of pipelines; binding the pipe hoop diameter parameters with the pipe diameter parameters in sequence, binding the pipe hoop model with the pipe middle distance control reference line of each pipe, binding the offset of the vertical surface of one group of pipe hoops with the placing height of the upper pipe hoop, and binding the offset of the vertical surface of the other group of pipe hoops with the placing height of the lower pipe hoop;

step 10: establishing transverse channel steel models based on the spacing control reference line of the pipeline support, wherein in the embodiment, the number of the transverse channel steel models is three, and the transverse channel steel models are respectively an upper transverse channel steel, a middle transverse channel steel and a lower transverse channel steel; two ends of the transverse channel steel are bound on space control reference lines of pipeline supports on two sides, and the vertical offset is respectively bound on three parameters of the placement height of the upper channel steel, the placement height of the middle channel steel and the placement height of the lower channel steel;

step 11: two groups of vertical frame channel steel models are established based on the distance control reference line of the pipeline support, and in the embodiment, the number of each group of vertical frame channel steel models is five; two ends of a first group of vertical channel steel models are respectively bound on the boundaries of two transverse channel steel models on the upper part and the middle part, two ends of a second group of vertical channel steel models are respectively bound on the boundaries of two transverse channel steel models on the middle part and the lower part, the positions of a first vertical frame channel steel and a fifth vertical frame channel steel of each group are respectively bound on the left end and the right end of each transverse channel steel model, and a second vertical frame channel steel, a third vertical frame channel steel and a fourth vertical frame channel steel of each group are respectively bound on the pipe middle distance control reference lines of a pipeline 3, a pipeline 5 and a pipeline 7;

step 12: sequentially creating pipeline connecting pieces at the upper opening and the lower opening of the pipe group pipeline model, and binding corresponding diameter parameters;

step 13: family files are saved for use and a completed building of a well-tubing string is shown in fig. 1.

The present invention is not limited to the above-described embodiments, and any obvious improvements, substitutions or modifications can be made by those skilled in the art without departing from the spirit of the present invention.

Claims (6)

1. A method for manufacturing a BIM group of assembled tubular well pipe group modules is characterized by comprising the following steps:

step 1: in Autodesk Revit software, creating a new family by using a metric conventional family template file based on a surface, drawing a length control reference line of a pipe group pipeline in a facade view, and drawing a pipe intermediate distance control reference line of the pipe group pipeline in a plane view; marking the dimension of each reference line, and giving all dimension marking parameters, wherein the parameters comprise the length of the pipe section and the distance between adjacent pipes;

and 2, step: establishing a pipe group pipeline model by using a stretching command, binding the center of a pipeline circle to the intersection point of a central front/rear reference line and a middle distance control reference line of each pipe in a plane view by using an alignment command, carrying out diameter marking, and then adding parameters to all diameter marks, wherein the added parameters comprise the diameters of the pipes;

and step 3: in a vertical view, using an alignment command to bind one end of the pipeline to a datum plane and bind the other end of the pipeline to a length control reference line;

and 4, step 4: performing parameter logical processing on the parameters of the space between the adjacent pipelines, and giving a space parameter formula to the parameters;

and 5: adding the number of group parameter pipe groups, adding visibility parameters to each pipe model, endowing a visibility parameter logic formula with the visibility parameters, and operating the logic formula to control the display number of the pipe groups according to the pipe group pipe number parameters;

and 6: creating a family of face-based pipe-carrier-containing pipe hoops, creating a family of line-based channel steels;

and 7: drawing a distance control reference line of the pipeline support in a plane view, marking the size, and adding group parameters;

and 8: compiling a logic algorithm for automatically identifying the maximum pipe diameter of the pipe group, giving an algorithm formula to control size marking of the spacing of the pipe supports, and automatically controlling the spacing of the pipe supports through the logic algorithm formula;

and step 9: based on the pipe support distance control reference line, creating a pipe hoop model, binding the pipe hoop diameter parameters with the pipe diameter parameters, binding the pipe hoop model with the pipe middle distance control reference line of each pipe, and binding the pipe hoop elevation offset with the corresponding group parameters in the step 7;

step 10: establishing a transverse channel steel model based on the pipeline bracket spacing control reference line, wherein two ends of the transverse channel steel are bound to the pipeline bracket spacing control reference lines on two sides, and the vertical surface offset is respectively bound to the corresponding family parameters in the step 7;

step 11: based on the spacing control reference line of the pipeline supports, a vertical frame channel steel model is established and is bound with a transverse channel steel model;

step 12: sequentially creating pipeline connecting pieces at the upper opening and the lower opening of the pipe group pipeline model, and binding corresponding diameter parameters;

step 13: the family file is saved for use.

2. The method for manufacturing the BIM family of the fabricated tubular well tubular assembly module according to claim 1, wherein in the step 4, the spacing parameter formula is as follows:

in the formula, m is a positive integer and represents a pipeline number; after a distance parameter formula is given, the distance between the adjacent pipelines is automatically controlled through the diameter parameters of the pipelines.

3. The fabricated tubular-well-tubular-stack module BIM family fabrication method of claim 1, wherein the family parameters in step 7 include an upper channel placement height, a middle channel placement height, a lower channel placement height, an upper pipe collar placement height, and a lower pipe collar placement height.

4. The method for manufacturing the BIM family of the prefabricated pipe-well-pipe assembly module according to claim 3, wherein in the step 9, there are two sets of pipe hoop models, including an upper pipe hoop and a lower pipe hoop, the number of each set of pipe hoop models corresponds to the number of pipes, and one set of pipe hoop elevation offset is bound to the upper pipe hoop placing height, and the other set of pipe hoop elevation offset is bound to the lower pipe hoop placing height.

5. The BIM manufacturing method of the assembly type pipe-well pipe assembly module according to claim 3, wherein in the step 10, the number of the transverse channel steel models is three, and the transverse channel steel models are respectively an upper transverse channel steel, a middle transverse channel steel and a lower transverse channel steel, and vertical offsets of the upper transverse channel steel, the middle transverse channel steel and the lower transverse channel steel are respectively bound to an upper channel steel placement height, a middle channel steel placement height and a lower channel steel placement height.

6. The method for manufacturing the BIM family of the assembled pipe-well pipe assembly modules according to claim 5, wherein in the step 11, nine pipes are provided, the number of the channel steel models of each group is five, two ends of the first group of vertical channel steel models are respectively bound to the boundaries of the two transverse channel steel models at the upper part and the middle part, two ends of the second group of vertical channel steel models are respectively bound to the boundaries of the two transverse channel steel models at the middle part and the lower part, the positions of the first vertical frame channel steel and the fifth vertical frame channel steel of each group are respectively bound to the left end and the right end of the transverse channel steel models, and the middle pipe distance control reference lines of the second vertical frame channel steel, the third vertical frame channel steel and the fourth vertical frame channel steel of each group are respectively bound to the middle pipe distance control reference lines of the third pipe, the fifth pipe and the seventh pipe.

Images