CN111539053A

CN111539053A - BIM software-based material identification generation system and use method thereof

Info

Publication number: CN111539053A
Application number: CN202010259225.4A
Authority: CN
Inventors: 李国彬; 李岩
Original assignee: Liaoning Xinxin Construction Technology Co ltd
Current assignee: Liaoning Xinxin Construction Technology Co ltd
Priority date: 2020-04-03
Filing date: 2020-04-03
Publication date: 2020-08-14

Abstract

The invention discloses a BIM software-based material identifier generation system and a use method thereof, wherein the BIM software-based material identifier generation system comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, wherein the design terminal is connected with the central processing unit, the workshop terminal is connected with the design terminal, and the execution mechanism is connected with the workshop terminal; the system has the advantages that the system is simple to operate and convenient to use, on the basis of three-dimensional modeling, the numbering function of a single workpiece in the three-dimensional modeling is respectively numbered in production and position by software, a coordinate system capable of determining the single workpiece is provided for the central processing unit, the central processing unit is used for generating two-dimensional codes for the workpiece in the three-dimensional modeling, the two-dimensional codes are printed on the workpiece after the production of the workpiece is finished, and a detailed mounting position diagram of the workpiece can be obtained by scanning the codes by using mobile terminals such as a mobile phone and the like, so that the system is beneficial to simultaneous construction of multiple persons, and the construction efficiency and precision are accelerated.

Description

BIM software-based material identification generation system and use method thereof

Technical Field

The invention relates to the technical field of engineering management, in particular to a BIM software-based material identification generation system and a use method thereof.

Background

The aluminium template trade is the trade that makes a sound a relatively late among the building trade, and its main construction tool is the template of aluminum alloy material, utilizes multiple aluminium template to splice the effect that can accomplish traditional mould, and the contrast tradition mould has the high corrosion-resistant characteristic of light in weight intensity of structure moreover, consequently more and more has taken up the market of building template, has very good development prospect.

BIM is a new tool in architecture, engineering and civil engineering. The term building information model or building information model was created by Autodesk. It is used to describe the computer aided design mainly based on three-dimensional figure, object guide and building engineering.

The BIM is utilized to carry out three-dimensional modeling design on the aluminum template, design and shaping work can be completed quickly, construction drawing is convenient to build, digital identification codes are usually sprayed in the production process of the aluminum template in the existing construction process, so that the installation positions in three-dimensional modeling can be compared conveniently, however, the method needs the assistance of the drawing, the drawing configuration quantity of common constructors is limited, the reference of the constructors is limited, the construction efficiency is limited, the comparison of the identification codes is not visual enough, installation position errors are easy to occur, the construction quality and progress are influenced, in view of the above, deep research is carried out on the problems, and the scheme is generated.

Disclosure of Invention

The invention aims to solve the problems, designs a BIM software-based material identifier generation system and a using method thereof, and solves the problems that in the existing construction process, digital identification codes are usually sprayed in the production process of an aluminum template so as to be convenient for contrasting the installation position in three-dimensional modeling, but the method needs the assistance of drawings, the configuration quantity of the drawings of a common constructor is limited, so that the constructor has limited reference and construction efficiency is limited, and secondly, the identification codes are not visual enough for contrasting, so that the installation position error is easy to occur, and the construction quality and progress are influenced.

The technical scheme of the invention for realizing the aim is as follows: a BIM software-based material identifier generation system comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, wherein the design terminal is connected with the central processing unit, the workshop terminal is connected with the design terminal, and the execution mechanism is connected with the workshop terminal;

the design terminal is used for three-dimensional modeling and receiving a processing result of the central processing unit, the central processing unit is used for receiving files uploaded by the design terminal and generating identification codes, the workshop terminal is used for receiving instructions of the design terminal, the execution mechanism is used for spraying codes according to the instructions received by the workshop terminal, and the mobile terminals are used for identifying the identification codes sprayed by the execution mechanism.

The system further comprises a data storage cloud end for storing the generated three-dimensional modeling number and the identification code.

The actuating mechanism is an ink-jet printer and the identification code sprayed by the actuating mechanism is a two-dimensional code.

The design terminal is internally provided with a display and carries BIM software for three-dimensional modeling.

And the mobile terminals are all intelligent mobile equipment with a code scanning function.

The use method of the BIM software-based material identification generation system based on claim 5 comprises the following steps: step S1, logging in the system; step S2, three-dimensional modeling; step S3, uploading for the first time; step S4, secondary uploading; step S5, downloading the identification code; step S6, transmitting the code spraying; step S7, code scanning and assembling;

step S1: logging in a system interface, and selecting a client project to be executed;

step S2: carrying out three-dimensional modeling on BIM software, and numbering a single workpiece in the modeling by using the numbering function of the software in the three-dimensional modeling process;

step S3: exporting the three-dimensional modeling into an IFC format, selecting an IFC file and uploading the IFC file to a central processing unit to obtain a URL address;

step S4: selecting the IFC format file in the step S3 from the obtained URL address, uploading the IFC format file to a central processing unit for the second time, and independently coding workpieces in the IFC file by the central processing unit;

step S5: waiting for the generation result of the central processing unit, and selecting a generation file on the URL for downloading after the generation result is generated;

step S6: respectively sending the identification code and the serial number of a single workpiece to a workshop, and directly spraying the identification code on the workpiece according to the serial number after the workshop produces;

step S7: when in assembly, the mobile terminal is used for scanning the identification code on the workpiece, and the assembly is carried out according to the installation position of the workpiece in the three-dimensional modeling on the mobile terminal.

The software of step S2 performs twice identification codes for a single workpiece, one for a production number and the other for a position number.

The generated result of the central processing unit in the step S5 is automatically uploaded to the cloud data storage.

And the identification code sprayed to the workpiece by the code spraying machine in the step S6 is a two-dimensional code.

In step S7, when the mobile terminal scans the workpiece, the complete three-dimensional model is displayed on the mobile terminal and the workpiece is highlighted.

The BIM software-based material identification generation system manufactured by the technical scheme of the invention is simple to operate and convenient to use, on the basis of three-dimensional modeling, the numbering function of a single workpiece in the three-dimensional modeling is respectively carried out production numbering and position numbering by using software, a coordinate system capable of determining the single workpiece is provided for a central processing unit, the workpiece in the three-dimensional modeling is subjected to two-dimensional code generation by using the central processing unit, a two-dimensional code is printed on the workpiece after the production of the workpiece is finished, and a detailed installation position diagram of the workpiece can be obtained by scanning the code by using mobile terminals such as a mobile phone, so that the BIM software-based material identification generation system is beneficial to simultaneous construction of multiple persons.

Drawings

Fig. 1 is a system block diagram of a BIM software-based material identifier generation system and a method for using the same according to the present invention.

Fig. 2 is a schematic workflow diagram of a material identifier generation system based on BIM software and a method for using the same according to the present invention.

Detailed Description

The invention is described in detail with reference to the accompanying drawings, and as shown in fig. 1-2, a material identifier generation system based on BIM software comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, wherein the design terminal is connected with the central processing unit, the workshop terminal is connected with the design terminal, and the execution mechanism is connected with the workshop terminal; the system comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, wherein the design terminal is used for three-dimensional modeling and receiving a processing result of the central processing unit, the central processing unit is used for receiving files uploaded by the design terminal and generating identification codes, the workshop terminal is used for receiving instructions of the design terminal, the execution mechanism is used for spraying codes according to the instructions received by the workshop terminal, and the mobile terminals are used for identifying the identification codes sprayed by the execution mechanism; the system also comprises a data storage cloud end for storing the generated three-dimensional modeling number and the identification code; the executing mechanism is an ink-jet printer and the identification code sprayed by the executing mechanism is a two-dimensional code; the design terminal is internally provided with a display and carries BIM software for three-dimensional modeling; the mobile terminals are all intelligent mobile equipment with a code scanning function; the use method of the BIM software-based material identification generation system based on claim 5 comprises the following steps: step S1, logging in the system; step S2, three-dimensional modeling; step S3, uploading for the first time; step S4, secondary uploading; step S5, downloading the identification code; step S6, transmitting the code spraying; step S7, code scanning and assembling; step S1: logging in a system interface, and selecting a client project to be executed; step S2: carrying out three-dimensional modeling on BIM software, and numbering a single workpiece in the modeling by using the numbering function of the software in the three-dimensional modeling process; step S3: exporting the three-dimensional modeling into an IFC format, selecting an IFC file and uploading the IFC file to a central processing unit to obtain a URL address; step S4: selecting the IFC format file in the step S3 from the obtained URL address, uploading the IFC format file to a central processing unit for the second time, and independently coding workpieces in the IFC file by the central processing unit; step S5: waiting for the generation result of the central processing unit, and selecting a generation file on the URL for downloading after the generation result is generated; step S6: respectively sending the identification code and the serial number of a single workpiece to a workshop, and directly spraying the identification code on the workpiece according to the serial number after the workshop produces; step S7: when in assembly, the mobile terminal is used for scanning the identification code on the workpiece, and the assembly is carried out according to the installation position of the workpiece in the three-dimensional modeling on the mobile terminal; the software of the step S2 identifies the code for a single workpiece twice, wherein one time is a production number, and the other time is a position number; the generated result of the central processing unit in the step S5 is automatically uploaded to the data storage cloud; the identification code sprayed to the workpiece by the code spraying machine in the step S6 is a two-dimensional code; in step S7, when the mobile terminal scans the workpiece, the complete three-dimensional model is displayed on the mobile terminal and the workpiece is highlighted.

The system is characterized by comprising a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, wherein the design terminal is connected with the central processing unit, the workshop terminal is connected with the design terminal, and the execution mechanism is connected with the workshop terminal; the system comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, wherein the design terminal is used for three-dimensional modeling and receiving a processing result of the central processing unit, the central processing unit is used for receiving a file uploaded by the design terminal and generating an identification code, the workshop terminal is used for receiving an instruction of the design terminal, the execution mechanism is used for spraying codes according to the instruction received by the workshop terminal, and the mobile terminals are used for identifying the identification code sprayed by the; the BIM software-based material identification generation system is simple to operate and convenient to use, on the basis of three-dimensional modeling, the numbering function of a single workpiece in the three-dimensional modeling is respectively numbered in production and position by using software, a central processing unit is provided with a coordinate system capable of determining the single workpiece, the workpiece in the three-dimensional modeling is generated by using the central processing unit, a two-dimensional code is printed on the workpiece after the production of the workpiece is finished, and a mounting position detailed diagram of the workpiece can be obtained by scanning the code by using mobile terminals such as a mobile phone, so that the BIM software-based material identification generation system is beneficial to simultaneous construction of multiple persons, and the construction efficiency and precision are accelerated.

All the electrical components in the present application are connected with the power supply adapted to the electrical components through the wires, and an appropriate controller should be selected according to actual conditions to meet the control requirements, and specific connection and control sequences should be obtained.

Example (b): according to the attached drawings 1-2 in the specification, the BIM software-based material identifier generation system is designed, and mainly comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism, a plurality of mobile terminals and a data storage cloud end, wherein the connection relationship is as follows:

the design terminal is connected with the central processing unit, the workshop terminal is connected with the design terminal, the execution mechanism is connected with the workshop terminal, and the data storage cloud is connected with the central processing unit;

in the specific implementation process, a terminal is designed as a working platform mainly operated by a user, a computer is adopted to carry BIM software, the BIM software is used for three-dimensional modeling, and a central processing unit of an access system is used for receiving an identification code result of the central processing unit on a single model in the three-dimensional modeling; the central processing unit is used as a system core for receiving the three-dimensional modeling file uploaded by the design terminal and generating an identification code according to the single piece code of the three-dimensional modeling file; the workshop terminal is used for receiving an instruction of the design terminal and is a transfer machine for connecting the execution mechanism and the design terminal; the executing mechanism is used for spraying codes according to the instruction received by the workshop terminal, the executing mechanism is a code spraying machine, and the identification codes sprayed by the executing mechanism are two-dimensional codes; the mobile terminals are used for identifying the identification codes sprayed by the actuating mechanisms; the data storage cloud end stores the generated three-dimensional modeling serial number and the identification code;

the following describes the material identification generation system in detail in conjunction with a method for using the system based on BIM software.

As can be seen from fig. 2 in the specification, the steps required for the user to operate in the operation flow of the system include: firstly, logging in a system; secondly, three-dimensional modeling; thirdly, uploading at one time; fourthly, uploading for the second time; fifthly, downloading the identification code; sixthly, transmitting and spraying codes; seventhly, code scanning and assembling;

firstly, the method comprises the following steps: the method comprises the steps of logging in a system interface, selecting a client project to be executed, and selecting the client project to be executed after logging in the system, wherein the steps are to facilitate a user to operate aiming at different client projects, avoid management confusion among projects, and enable each client to establish one or more projects;

II, secondly: after a customer project is selected, three-dimensional modeling is carried out on BIM software, in the three-dimensional modeling process, a single workpiece in the modeling is numbered by using the numbering function of the software, in the three-dimensional modeling process, the BIM software automatically numbers the single workpiece twice, wherein one time is a production number and the other time is a position number, so that the single workpiece can be determined by the production number and the position number, and two groups of numbers exist because the production numbers of workpieces with the same type are the same and only the change of the quantity is recorded, thereby being convenient for management;

thirdly, the method comprises the following steps: exporting the three-dimensional modeling into an IFC format, selecting an IFC file and uploading the IFC file to a central processing unit to obtain a URL address, wherein the step is to obtain the available URL address;

fourthly, the method comprises the following steps: selecting the IFC format file in the step S3 from the obtained URL address, uploading the IFC format file to a central processing unit for the second time, independently coding the workpieces in the IFC file by the central processing unit, and determining a workpiece to perform independent identification code grouping on the workpiece by the central processing unit according to the coding result, the production number and the position number of the software;

fifthly: waiting for a generation result of the central processing unit, uniformly transmitting the identification code of each workpiece in an IFC file to a URL (Uniform resource locator) by the central processing unit, simultaneously uploading the identification code to a data storage cloud, and accessing the URL obtained before to download the processed IFC file;

sixthly, the method comprises the following steps: respectively sending the identification code and the serial number of a single workpiece to a workshop terminal, directly spraying a code to the workpiece according to the production serial number after workshop production, and enabling the identification code sprayed to the workpiece by a code spraying machine to be a two-dimensional code;

seventhly, the method comprises the following steps: when in assembly, the mobile terminal is used for scanning the identification code on the workpiece, and the assembly is carried out according to the installation position of the workpiece in the three-dimensional modeling on the mobile terminal; the mobile terminal can preferably adopt a mobile phone, and when the mobile terminal scans codes of the workpiece, the mobile terminal can display a complete three-dimensional modeling and highlight the workpiece;

in summary, the BIM software-based material identification generation system is simple to operate and convenient to use, on the basis of three-dimensional modeling, the numbering function of a single workpiece in the three-dimensional modeling is respectively subjected to production numbering and position numbering by using software, a coordinate system capable of determining the single workpiece is provided for a central processing unit, the workpiece in the three-dimensional modeling is subjected to two-dimensional code generation by using the central processing unit, a two-dimensional code is printed on the workpiece after the production of the workpiece is completed, and a detailed mounting position diagram of the workpiece can be obtained by scanning the code by using mobile terminals such as a mobile phone and the like, so that simultaneous construction by multiple persons is facilitated, and the construction efficiency and precision are improved.

The technical solutions described above only represent the preferred technical solutions of the present invention, and some possible modifications to some parts of the technical solutions by those skilled in the art all represent the principles of the present invention, and fall within the protection scope of the present invention.

Claims

1. A BIM software-based material identifier generation system comprises a design terminal, a central processing unit, a workshop terminal, an execution mechanism and a plurality of mobile terminals, and is characterized in that the design terminal is connected with the central processing unit, the workshop terminal is connected with the design terminal, and the execution mechanism is connected with the workshop terminal;

2. The BIM software-based material identification generation system of claim 1, further comprising a data storage cloud for storing the generated three-dimensional modeling number and the identification code.

3. The BIM software-based material identifier generation system of claim 1, wherein the actuator is an inkjet printer and the identification code sprayed by the actuator is a two-dimensional code.

4. The BIM software-based material identification generation system as claimed in claim 1, wherein the design terminal has a display therein and carries BIM software for three-dimensional modeling.

5. The BIM software-based material identification generation system according to claim 1, wherein the plurality of mobile terminals are all intelligent mobile devices with a code scanning function.

6. The use method of the BIM software-based material identification generation system according to claim 5, comprising the following steps: step S1, logging in the system; step S2, three-dimensional modeling; step S3, uploading for the first time; step S4, secondary uploading; step S5, downloading the identification code; step S6, transmitting the code spraying; step S7, code scanning and assembling;

7. The use method of the BIM software-based material identification generation system according to claim 6, wherein the software of step S2 performs identification coding on a single workpiece twice, one time being a production number and the other time being a position number.

8. The use method of the BIM software-based material identification generation system as claimed in claim 6, wherein the generation result of the central processing unit in the step S5 is automatically uploaded to a cloud data storage device.

9. The use method of the BIM software-based material identifier generation system according to claim 6, wherein the identification code sprayed by the inkjet printer to the workpiece in the step S6 is a two-dimensional code.

10. The use method of the BIM software-based material identification generation system, as claimed in claim 6, wherein in step S7, the mobile terminal displays the complete three-dimensional modeling and highlights the workpiece when scanning the workpiece.