CN109948241B - Assembly type building design device and method - Google Patents

Abstract

An assembled building design device and method comprises a drawing path acquisition module, wherein the input of the drawing path acquisition module is connected with the output of a painting brush path acquisition module and the output of an eraser path acquisition module, the output of the drawing path acquisition module is connected with the first input of a central processing unit, the first output of the central processing unit is connected with the input of a three-dimensional model generation module, the second output of the central processing unit is connected with the input of a hard point file reading module, the output of the hard point file reading module is connected with the second input of the central processing unit, the third output of the central processing unit is connected with the input of a hard point building structure model construction module, the fourth output of the central processing unit is connected with the input of a hard point release module, and the fifth output of the central processing unit is connected with the input of a building component point line model construction module; the invention has the characteristics of convenience and quickness; the simulation analysis and detection of the performance of the building are realized while the design is carried out, and the integration of the building design and the performance design is realized.

Description

Assembly type building design device and method

Technical Field

The invention relates to the technical field of building design, in particular to an assembly type building design device and method.

Background

The fabricated building is a building assembled by prefabricated parts at a construction site, and is called as a fabricated building. The building block is divided into five types, namely a block building, a plate building, a box building, a framework plate building, a rising-rise building and the like according to the form and the construction method of the prefabricated part. With the development of modern industrial technology, building houses can be made in batches as machines are produced. The prefabricated house components are transported to a construction site to be assembled. Fabricated buildings have become interesting since the beginning of the 20 th century and have been realized through the sixties. The first attempts were made in English, french, soviet Union, and other countries. The assembly type building is fast in construction speed and low in production cost, and is rapidly popularized and developed all over the world. However, the existing building design process takes a long time, and a large amount of time is required for model generation, which affects the progress of the building.

Disclosure of Invention

In order to solve the problems, the invention provides an assembly type building design device and method, which are convenient and quick and realize the integration of building design and performance design.

In order to achieve the purpose, the invention adopts the technical scheme that:

an input of the drawing path acquisition module is connected with an output of the painting brush path acquisition module and an output of the eraser path acquisition module, an output of the drawing path acquisition module is connected with a first input of a central processing unit, a first output of the central processing unit is connected with an input of the three-dimensional model generation module, a second output of the central processing unit is connected with an input of the hard point file reading module, an output of the hard point file reading module is connected with a second input of the central processing unit after being associated with the hard point table driving module, a third output of the central processing unit is connected with an input of the hard point building structure model construction module, a fourth output of the central processing unit is connected with an input of the hard point publishing module, and a fifth output of the central processing unit is connected with an input of the building component dotted line model construction module; the sixth output of the central processing unit is connected with the control input of the image acquisition module, the signal output of the image acquisition module is connected with the input of the three-dimensional reconstruction module, the output of the three-dimensional reconstruction module is connected with the fourth input of the central processing unit, and the seventh output of the central processing unit is connected with the input of the three-dimensional image format conversion module; the third input of the central processing unit is connected with the output of the transfer node module, the transfer node module is connected with each element in the three-dimensional model generation module, and the three-dimensional model in the three-dimensional model generation module generates corresponding movement by changing the position and direction setting of the transfer node.

And the painting brush path acquisition module is used for acquiring painting brush paths based on a three-dimensional attitude sensor and a geomagnetic sensor which are arranged in a painting brush.

The eraser path acquisition module is used for acquiring eraser paths based on a three-dimensional attitude sensor and a geomagnetic sensor loaded in the eraser sleeve.

And the drawing path acquisition module generates a final drawing path based on the painting brush path and the eraser path.

And the three-dimensional model generation module is used for realizing the construction of the target assembly type building three-dimensional model based on the drawing path.

And the hard point file reading module is used for acquiring the hard point file of the three-dimensional model to form a modifiable hard point table.

And the hard point building structure model building module is used for building a hard point building structure model based on the hard point table, and the hard point building structure model comprises all hard point coordinates.

And the building element point-line model building module is used for building point-line models of all building elements in the building according to the hard point building construction model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association relationship.

And the hard point table driving module is used for changing the coordinates of the corresponding hard point table according to the input design requirements so as to change the structural parameters of each building component and the structural parameters of the hard point building structure model.

The three-dimensional attitude sensor and the geomagnetic sensor in the painting brush path acquisition module are started when the film pressure sensor detects a pressure value, and the three-dimensional attitude sensor and the geomagnetic sensor are closed when the pressure value is not detected.

The three-dimensional model generation module is realized based on Automatic Mechanical system dynamics Analysis of Mechanical Systems (ADAMS software).

The output of the three-dimensional model generation module is sequentially connected with the virtual actuation module, the virtual sensor and the simulation analysis module;

and the transfer node module is connected with each element in the three-dimensional model generation module, and enables the three-dimensional model to generate corresponding motion by changing the position and direction setting of the transfer node.

The virtual actuation module is used for driving parameter change, and after the virtual actuation module establishes a relationship with each element in the three-dimensional model generation module, the virtual actuation module can change the parameters within a specified range, so that the simulation analysis method is driven to calculate and solve different parameters;

the virtual sensor is a logic unit which is inserted into the three-dimensional model and can directly acquire a corresponding result or information target;

the simulation analysis module is used for decomposing parameters of design variables, design targets and design constraints;

the simulation analysis module drives the virtual actuation module to circularly execute the simulation analysis method, the virtual actuation module feeds back the structure to the simulation analysis module through circular execution analysis, the simulation analysis module automatically extracts data to the virtual sensor, and the virtual sensor automatically displays an analysis result.

The outer wall of the rubber sleeve in the rubber path acquisition module is provided with a film pressure sensor in an adhering mode, when the film pressure sensor detects a pressure value, the three-dimensional attitude sensor and the geomagnetic sensor in the rubber path acquisition module are started, and when the pressure value is not detected, the three-dimensional attitude sensor and the geomagnetic sensor are closed.

And the image acquisition module is used for acquiring the drawing/model/target building image.

The three-dimensional reconstruction module is used for acquiring the acquired image data depth image through a kinect depth sensor, triangulating the acquired depth image, fusing all the triangulated depth images in a scale space to construct a layered directional distance field, applying an integral triangulation algorithm to all voxels in the distance field to generate a convex hull covering all the voxels, and constructing an isosurface by using a Marching Tetrahedra algorithm to complete the reconstruction of the three-dimensional image.

And the three-dimensional image format conversion module is used for converting the three-dimensional image obtained by reconstruction into a format which can be identified by ADAMS software.

The design method based on the assembly type building design device comprises the following steps:

1. the method comprises the steps that collection of a painting brush path and an eraser path is achieved through a three-dimensional attitude sensor and a geomagnetic sensor, and a final painting path is generated on the basis of the painting brush path and the eraser path;

2. according to the requirement of the stability parameters of the prefabricated building, establishing a three-dimensional model of the target prefabricated building by using ADAMS, and obtaining an ADAMS hard point file, wherein the ADAMS hard point file at least comprises position information of each hard point of the prefabricated building;

3. reading the coordinate value of each hard point in the hard point file to form a modifiable hard point table;

4. establishing a hard point building construction model according to the hard point table, wherein the hard point building construction model comprises all hard point coordinates;

5. carrying out parameterization processing on the hard point building structure model, establishing association between the hard point building structure model and a hard point table, and issuing each associated hard point in the hard point building structure model;

6. constructing a point-line model of each building element in the building according to the hard point building construction model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association relation;

7. acquiring target design parameters based on a simulation analysis module, a virtual actuation module and a virtual sensor, and converting the design parameters into corresponding hard point driving parameters;

8. and changing the coordinates of the corresponding hard point table based on the hard point driving parameters so as to change the structural parameters of each building component and the structural parameters of the hard point building construction model until the design meets all requirements.

The assembly type building design method based on the design device comprises the following steps:

1. acquiring a drawing/model/target building image through an image acquisition module;

2. acquiring a depth image of acquired image data based on a kinect depth sensor through a three-dimensional reconstruction module, triangulating the acquired depth image, fusing all triangulated depth images in a scale space to construct a layered directed distance field, applying an integral triangulation algorithm to all voxels in the distance field to generate a convex hull covering all the voxels, constructing an isosurface by using a Marching Tetrahedra algorithm, and completing the reconstruction of the three-dimensional image;

3. converting the three-dimensional image obtained by reconstruction into a format which can be identified by ADAMS software based on a three-dimensional image format conversion module, and importing the three-dimensional image into ADAMS to obtain an ADAMS hard point file, wherein the ADAMS hard point file at least comprises position information of each hard point of the assembly building;

4. reading the coordinate value of each hard point in the hard point file to form a modifiable hard point table;

5. establishing a hard point building construction model according to the hard point table, wherein the hard point building construction model comprises all hard point coordinates;

6. carrying out parameterization processing on the hard point building structure model, establishing association between the hard point building structure model and a hard point table, and issuing each associated hard point in the hard point building structure model;

7. constructing a point-line model of each building element in the building according to the hard point building construction model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association;

8. acquiring target design parameters based on a simulation analysis module, a virtual parameter actuation module and a virtual sensor, and converting the design parameters into corresponding hard point driving parameters;

9. and changing the coordinates of the corresponding hard point table based on the hard point driving parameters, so that the structural parameters of each building component and the structural parameters of the hard point building construction model are changed until the design meets all requirements.

According to the invention, through the acquisition of the drawing path, the hand-drawing paper can be directly converted into the three-dimensional model, so that the method is convenient and fast; through the establishment of the modifiable hard point table, the workload required when the design is changed in the design process of the fabricated building structure can be reduced; through the design of self-defined virtual sensor, virtual actuation module and simulation analysis module, the simulation analysis and detection of the performance of building have been realized when carrying out the design, have realized the integration of architectural design and performance design to can carry out the optimization of assembled building according to the demand of difference, realize according to local conditions.

Drawings

Fig. 1 is a system block diagram of a prefabricated building design device according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

An assembled building design device and method comprises a drawing path acquisition module, wherein the input of the drawing path acquisition module is connected with the output of a painting brush path acquisition module and the output of an eraser path acquisition module, the output of the drawing path acquisition module is connected with the first input of a central processing unit, the first output of the central processing unit is connected with the input of a three-dimensional model generation module, the second output of the central processing unit is connected with the input of a hard point file reading module, the output of the hard point file reading module is connected with the second input of the central processing unit after being associated with a hard point table driving module, the third output of the central processing unit is connected with the input of a hard point building structure model construction module, the fourth output of the central processing unit is connected with the input of a hard point publishing module, and the fifth output of the central processing unit is connected with the input of a building component point line model construction module; the sixth output of the central processing unit is connected with the control input of the image acquisition module, the signal output of the image acquisition module is connected with the input of the three-dimensional reconstruction module, the output of the three-dimensional reconstruction module is connected with the fourth input of the central processing unit, and the seventh output of the central processing unit is connected with the input of the three-dimensional image format conversion module; the third input of the central processing unit is connected with the output of the transfer node module, the transfer node module is connected with each element in the three-dimensional model generation module, and the three-dimensional model in the three-dimensional model generation module generates corresponding movement by changing the position and direction setting of the transfer node.

And the painting brush path acquisition module is used for acquiring painting brush paths based on a three-dimensional attitude sensor and a geomagnetic sensor which are arranged in the painting brush.

And the eraser path acquisition module is used for acquiring eraser paths based on a three-dimensional attitude sensor and a geomagnetic sensor loaded in the eraser sleeve.

And the drawing path acquisition module generates a final drawing path based on the painting brush path and the eraser path.

And the three-dimensional model generation module is used for realizing the construction of the target assembly type building three-dimensional model based on the drawing path.

And the hard point file reading module is used for acquiring the hard point file of the three-dimensional model to form a modifiable hard point table.

And the hard point building structure model building module is used for building a hard point building structure model based on the hard point table, and the hard point building structure model comprises all hard point coordinates.

And the building element point-line model building module is used for building point-line models of all building elements in the building according to the hard point building structure models, wherein the point-line model of each building element comprises corresponding parts of the issued hard points and maintains corresponding association relation.

And the hard point table driving module is used for changing the coordinates of the corresponding hard point table according to the input design requirements so as to change the structural parameters of each building component and the structural parameters of the hard point building structure model.

The three-dimensional attitude sensor and the geomagnetic sensor in the painting brush path acquisition module are started when the film pressure sensor detects a pressure value, and the three-dimensional attitude sensor and the geomagnetic sensor are closed when the pressure value is not detected.

The three-dimensional model generation module is realized based on Automatic Mechanical system dynamics Analysis of Mechanical Systems (ADAMS software).

The output of the three-dimensional model generation module is sequentially connected with the virtual actuation module, the virtual sensor and the simulation analysis module;

and the transfer node module is connected with each element in the three-dimensional model generation module and enables the three-dimensional model to generate corresponding motion by changing the position and direction setting of the transfer node.

The virtual actuation module is used for driving parameter change, and after the relation is established between the virtual actuation module and each element in the three-dimensional model generation module, the virtual actuation module can change the parameters within a specified range, so that the simulation analysis method is driven to calculate and solve different parameters;

the virtual sensor is a logic unit which is inserted into the three-dimensional model and can directly acquire a corresponding result or an information target;

the simulation analysis module is used for decomposing the parameters into design variables, design targets and design constraints;

the simulation analysis module drives the virtual actuation module to circularly execute the simulation analysis method, the virtual actuation module feeds back the structure to the simulation analysis module through circular execution analysis, the simulation analysis module automatically extracts data to the virtual sensor, and the virtual sensor automatically displays an analysis result.

The rubber path acquisition module is characterized in that a film pressure sensor is pasted on the outer wall of a rubber sleeve, when the film pressure sensor detects a pressure value, a three-dimensional attitude sensor and a geomagnetic sensor in the rubber path acquisition module are started, and when the pressure value is not detected, the three-dimensional attitude sensor and the geomagnetic sensor are closed.

And the image acquisition module is used for acquiring the drawing/model/target building image.

The three-dimensional reconstruction module is used for acquiring the acquired image data depth image through a kinect depth sensor, triangulating the acquired depth image, then fusing all the triangulated depth images in a scale space to construct a layered directional distance field, applying an integral triangulation algorithm to all voxels in the distance field to generate a convex hull covering all the voxels, constructing an isosurface by using a Marchanedra algorithm, and completing the reconstruction of the three-dimensional image.

And the three-dimensional image format conversion module is used for converting the three-dimensional image obtained by reconstruction into a format which can be identified by ADAMS software.

Example 1

An assembly type building design device and method are realized based on the design device, and the method comprises the following steps:

1. the method comprises the steps that collection of a painting brush path and an eraser path is achieved through a three-dimensional attitude sensor and a geomagnetic sensor, and a final painting path is generated on the basis of the painting brush path and the eraser path;

2. establishing a three-dimensional model of a target assembly building by using ADAMS according to the stability parameter requirement of the assembly building to obtain an ADAMS hard point file, wherein the ADAMS hard point file at least comprises position information of each hard point of the assembly building;

3. reading the coordinate value of each hard point in the hard point file to form a modifiable hard point table;

4. establishing a hard point building construction model according to the hard point table, wherein the hard point building construction model comprises all hard point coordinates;

5. carrying out parameterization processing on the hard point building structure model, establishing association between the hard point building structure model and a hard point table, and issuing each associated hard point in the hard point building structure model;

6. constructing a point-line model of each building element in the building according to the hard point building construction model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association;

7. acquiring target design parameters based on a simulation analysis module, a virtual parameter actuation module and a virtual sensor, and converting the design parameters into corresponding hard point driving parameters;

8. and changing the coordinates of the corresponding hard point table based on the hard point driving parameters, so that the structural parameters of each building component and the structural parameters of the hard point building construction model are changed until the design meets all requirements.

Example 2

The method for designing the fabricated building based on the design device comprises the following steps:

1. acquiring a drawing/model/target building image through an image acquisition module;

2. acquiring a depth image of acquired image data by a three-dimensional reconstruction module based on a kinect depth sensor, triangulating the acquired depth image, fusing all triangulated depth images in a scale space to construct a layered directional distance field, applying an integral triangulation algorithm to all voxels in the distance field to generate a convex hull covering all the voxels, constructing an isosurface by using a Marchanedra algorithm, and completing the reconstruction of the three-dimensional image;

3. converting the three-dimensional image obtained by reconstruction into a format which can be identified by ADAMS software based on a three-dimensional image format conversion module, and importing the three-dimensional image into ADAMS to obtain an ADAMS hard point file, wherein the ADAMS hard point file at least comprises position information of each hard point of the assembly building;

4. reading the coordinate value of each hard point in the hard point file to form a modifiable hard point table;

5. establishing a hard point building construction model according to the hard point table, wherein the hard point building construction model comprises all hard point coordinates;

6. carrying out parameterization processing on the hard point building structure model, establishing association between the hard point building structure model and a hard point table, and publishing each hard point associated in the hard point building structure model;

7. constructing a point-line model of each building element in the building according to the hard point building construction model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association;

8. acquiring target design parameters based on a simulation analysis module, a virtual parameter actuation module and a virtual sensor, and converting the design parameters into corresponding hard point driving parameters;

9. and changing the coordinates of the corresponding hard point table based on the hard point driving parameters, so that the structural parameters of each building component and the structural parameters of the hard point building construction model are changed until the design meets all requirements.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and amendments can be made without departing from the principle of the present invention, and these modifications and amendments should also be considered as the protection scope of the present invention.

Claims (9)

1. An assembly type architectural design device, characterized in that: the drawing path acquisition module is connected with the input of the drawing path acquisition module and the output of the painting brush path acquisition module and the output of the eraser path acquisition module, the output of the drawing path acquisition module is connected with the first input of the central processing unit, the first output of the central processing unit is connected with the input of the three-dimensional model generation module, the second output of the central processing unit is connected with the input of the hard point file reading module, the output of the hard point file reading module is connected with the second input of the central processing unit after being associated with the hard point table driving module, the third output of the central processing unit is connected with the input of the hard point building structure model construction module, the fourth output of the central processing unit is connected with the input of the hard point publishing module, and the fifth output of the central processing unit is connected with the input of the building component point line model construction module; the sixth output of the central processing unit is connected with the control input of the image acquisition module, the signal output of the image acquisition module is connected with the input of the three-dimensional reconstruction module, the output of the three-dimensional reconstruction module is connected with the fourth input of the central processing unit, and the seventh output of the central processing unit is connected with the input of the three-dimensional image format conversion module; the third input of the central processing unit is connected with the output of the transfer node module, the transfer node module is connected with each element in the three-dimensional model generation module, and the three-dimensional model in the three-dimensional model generation module generates corresponding motion by changing the position and direction setting of the transfer node.

2. The assembly building design device and method of claim 1, wherein: the painting brush path acquisition module is used for acquiring painting brush paths based on a three-dimensional attitude sensor and a geomagnetic sensor which are arranged in the painting brush; the eraser path acquisition module is used for acquiring eraser paths based on a three-dimensional attitude sensor and a geomagnetic sensor loaded in an eraser sleeve; the drawing path acquisition module generates a final drawing path based on the painting brush path and the eraser path; a film pressure sensor is pasted at a pen holding position of a painting brush in the painting brush path acquisition module, when the film pressure sensor detects a pressure value, a three-dimensional attitude sensor and a geomagnetic sensor in the painting brush path acquisition module are started, and when the pressure value is not detected, the three-dimensional attitude sensor and the geomagnetic sensor are closed.

3. A fabricated building design device according to claim 1, characterized in that: the three-dimensional model generation module is realized based on Automatic Mechanical system dynamics Analysis of Mechanical Systems (ADAMS software); and constructing a target assembly type building three-dimensional model based on the drawing path.

4. A fabricated building design device according to claim 1, wherein: the hard point file reading module is used for acquiring a hard point file of the three-dimensional model to form a modifiable hard point table; the hard point table driving module is used for changing the coordinates of the corresponding hard point table according to the input design requirements so as to change the structural parameters of each building component and the structural parameters of the hard point building structure model; the hard point building structure model construction module is used for constructing a hard point building structure model based on the hard point table, and the hard point building structure model comprises all hard point coordinates; and the hard point publishing module is used for carrying out parameterization on the hard point building structure model, establishing association between the hard point building structure model and the hard point table, and publishing each associated hard point in the hard point building structure model.

5. A fabricated building design device according to claim 1, wherein: and the building element point-line model building module is used for building point-line models of all building elements in the building according to the hard point building structure models, wherein the point-line model of each building element comprises corresponding parts of the issued hard points and maintains corresponding association relation.

6. A fabricated building design device according to claim 1, characterized in that: the output of the three-dimensional model generation module is sequentially connected with the virtual actuation module, the virtual sensor and the simulation analysis module;

the virtual actuation module is used for driving parameter change, and after the relation is established between the virtual actuation module and each element in the three-dimensional model generation module, the virtual actuation module can change the parameters within a specified range, so that the simulation analysis method is driven to calculate and solve different parameters;

the virtual sensor is a logic unit which is inserted into the three-dimensional model and can directly acquire a corresponding result or an information target;

the simulation analysis module is used for decomposing the parameters into design variables, design targets and design constraints;

the simulation analysis module drives the virtual actuation module to circularly execute the simulation analysis method, the virtual actuation module feeds a structure back to the simulation analysis module through circular execution analysis, the simulation analysis module automatically extracts data to the virtual sensor, and the virtual sensor automatically displays an analysis result.

7. A fabricated building design device according to claim 1, characterized in that: the three-dimensional reconstruction module is used for acquiring the acquired image data depth image through a kinect depth sensor, triangulating the acquired depth image, fusing all the triangulated depth images in a scale space to construct a layered directional distance field, applying an integral triangulation algorithm to all voxels in the distance field to generate a convex hull covering all the voxels, and constructing an isosurface by using a Marching Tetrahedra algorithm to complete the reconstruction of the three-dimensional image.

8. The design method of the prefabricated building design device according to claim 1, wherein: the method comprises the following steps:

1. the method comprises the steps that collection of a painting brush path and an eraser path is achieved through a three-dimensional attitude sensor and a geomagnetic sensor, and a final painting path is generated on the basis of the painting brush path and the eraser path;

2. establishing a three-dimensional model of a target assembly building by using ADAMS according to the stability parameter requirement of the assembly building to obtain an ADAMS hard point file, wherein the ADAMS hard point file at least comprises position information of each hard point of the assembly building;

3. reading the coordinate value of each hard point in the hard point file to form a modifiable hard point table;

4. establishing a hard point building structure model according to the hard point table, wherein the hard point building structure model comprises all hard point coordinates;

5. carrying out parameterization processing on the hard point building structure model, establishing association between the hard point building structure model and a hard point table, and publishing each hard point associated in the hard point building structure model;

6. constructing a point-line model of each building element in the building according to the hard point building structure model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association relation;

7. acquiring target design parameters based on a simulation analysis module, a virtual parameter actuation module and a virtual sensor, and converting the design parameters into corresponding hard point driving parameters;

8. and changing the coordinates of the corresponding hard point table based on the hard point driving parameters, so that the structural parameters of each building component and the structural parameters of the hard point building construction model are changed until the design meets all requirements.

9. A design method of an assembly type building design device based on claim 1, characterized in that: the method comprises the following steps:

1. acquiring a drawing/model/target building image through an image acquisition module;

2. acquiring a depth image of acquired image data based on a kinect depth sensor through a three-dimensional reconstruction module, triangulating the acquired depth image, fusing all triangulated depth images in a scale space to construct a layered directed distance field, applying an integral triangulation algorithm to all voxels in the distance field to generate a convex hull covering all the voxels, constructing an isosurface by using a Marching Tetrahedra algorithm, and completing the reconstruction of the three-dimensional image;

3. converting the three-dimensional image obtained by reconstruction into a format which can be identified by ADAMS software based on a three-dimensional image format conversion module, and importing the format into ADAMS to obtain an ADAMS hard point file, wherein the ADAMS hard point file at least comprises position information of each hard point of the assembly building;

4. reading the coordinate value of each hard point in the hard point file to form a modifiable hard point table;

5. establishing a hard point building construction model according to the hard point table, wherein the hard point building construction model comprises all hard point coordinates;

6. carrying out parameterization processing on the hard point building structure model, establishing association between the hard point building structure model and a hard point table, and issuing each associated hard point in the hard point building structure model;

7. constructing a point-line model of each building element in the building according to the hard point building construction model, wherein the point-line model of each building element comprises corresponding partial hard points in the issued hard points and maintains corresponding association;

8. acquiring target design parameters based on a simulation analysis module, a virtual parameter actuation module and a virtual sensor, and converting the design parameters into corresponding hard point driving parameters;

9. and changing the coordinates of the corresponding hard point table based on the hard point driving parameters, so that the structural parameters of each building component and the structural parameters of the hard point building construction model are changed until the design meets all requirements.

Images