CN111210199B

CN111210199B - Bridge prefab BIM information management system

Info

Publication number: CN111210199B
Application number: CN202010006335.XA
Authority: CN
Inventors: 孙辉; 王建军; 马文安; 林广泰; 陈孝强; 杜海龙; 郑健; 吴刚刚; 唐雁云; 李雍友; 李彩霞; 蒋严波; 陆进; 程振庭; 王伟宁; 欧晨丰
Original assignee: Guangxi Road and Bridge Engineering Group Co Ltd
Current assignee: Guangxi Road and Bridge Engineering Group Co Ltd
Priority date: 2020-01-03
Filing date: 2020-01-03
Publication date: 2022-06-07
Anticipated expiration: 2040-01-03
Also published as: CN111210199A

Abstract

The invention discloses a BIM (building information modeling) informatization management system for bridge prefabricated parts, and belongs to an information management system. The system comprises a cloud platform and a mobile login end; the cloud platform comprises a basic data setting module, a design data management module, a BIM model management module, a project progress management module, a raw material information management module, a quality acceptance management module, a warehousing management module and a factory transportation management module; the cloud platform is combined with a BIM model to display the engineering information of the steel structure processing and installation project, wherein the engineering information comprises project overview, finished output value, processing progress, installation progress and quality acceptance qualification rate; and the mobile login end identifies the two-dimensional code of the prefabricated member leaving the factory through the WeChat code scanning, and inquires a part model, quality control data, raw materials, information of each process and a photo of the prefabricated member bound by the related two-dimensional code. The invention combines BIM technology to visually display the engineering information of the bridge processing and installation project and assist managers to know and track the whole project.

Description

Bridge prefab BIM information management system

Technical Field

The invention relates to an information management system, in particular to a BIM (building information modeling) informatization management system for a bridge prefabricated part.

Background

At present, in the engineering design and construction process of highway bridges in China, prefabricated parts, in particular steel members and prefabricated beams, are used in most cases. The member factory prefabrication production has the characteristics of shortening the construction period, reducing the manufacturing cost and having little influence on the environment, is popularized and applied on a large scale in bridge engineering construction in China, and the operation and maintenance management level of a prefabrication station directly influences the delivery speed and quality of bridge members.

Because the traditional building industry is low in informatization degree, an informatization management system is not standard, and a full life cycle data link failure causes that an information data isolated island is difficult to exert the real value of informatization; moreover, because the prefabricated part processing plant has complex processing procedures in the plant and the plant site is far away from the project site, the accurate and efficient transmission and integrated information management of the multidimensional information are difficult to realize in the traditional management mode. With the rapid development of hardware and software industries in recent years, a set of informatization, standardization, refinement and efficient service management and data analysis system is established by combining the technology of accurate and efficient information acquisition and transmission of the Internet of things and the application of information visualization display technology of BIM and GIS, and the system is the inevitable direction of management of prefabricated part processing plants.

At present, bridge prefabricated parts are mainly processed to have some problems:

1. after receiving the processing project, the prefabricated part processing factory can deepen the design of the project again so as to meet the processing requirement of the processing factory. Therefore, the work contents of the process plant are marked during the process planning, and the project engineering parts related to the work contents are not clear; the planned work load proportion is not clear; the influence of the completion time of the planning work on the project construction period is not clear due to the fact that the project position is not clear; the supervision and feedback mechanism of the progress planning process is relatively backward and cannot accurately and timely transmit progress information to a remote project site.

2. The quality management of the prefabricated member in the processing plant adopts original field record, the construction log is manually written, then a specially-assigned person is needed to arrange the record in an electronic form, the record is time-consuming, difficult to make and easy to make mistakes, the record cannot be kept to be filled in time, and the automatic analysis and processing of data are not provided. The quality acceptance data of paper and the production information stored by a single machine can only be read by a single person, and the project site and a technical team can not be shared in real time, so that the information communication is difficult.

3. The traditional management mode of individual process can not accurately meet the quality requirement, and the identification is carried out by distinguishing if the model steel member has no unique number, so that the source information can not be accurately traced. The traditional precast beam maintenance work can not be accurately carried out according to factors such as site temperature, humidity and the like.

4. The optimization of the production plan of the prefabricated part processing plant and the optimal utilization rate of the field improve the production capacity and the economic benefit.

5. In the face of storage of thousands of parts in a factory, often one or two parts cannot find their storage points.

6. The project department cannot know the information of the factory transportation of the prefabricated parts: the geographical position and the arrival time are frequently arranged in advance by on-site hoisting personnel and machines due to inaccurate information, and resources are wasted.

7. Because the plant site of the prefabricated member processing plant is far away from the project site, personnel at the project department cannot know the condition of the project site and cannot remotely monitor the progress condition of the project.

Disclosure of Invention

The invention aims to solve the problems and provide a BIM (building information modeling) informatization management system for bridge prefabricated parts, which can be combined with BIM technology to visually display the engineering information of a bridge engineering steel structure processing and installing project and assist managers in knowing and tracking the whole project.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows:

a bridge prefabricated part BIM informatization management system comprises a cloud platform and a mobile login end; the cloud platform comprises a basic data setting module, a design data management module, a BIM model management module, a project progress management module, a raw material information management module, a quality acceptance management module, a warehousing management module and an ex-factory transportation management module; the cloud platform is combined with the BIM model to inquire and display the engineering information of the steel structure processing and installation project, wherein the engineering information comprises project outline, finished output value, processing progress, installation progress and quality acceptance qualification rate;

the mobile login terminal identifies the two-dimensional code of the prefabricated member leaving the factory through WeChat code scanning, and inquires a part model, quality control data, raw materials, process information and a real object photo of the prefabricated member bound by the relevant two-dimensional code; the mobile login end binds the prefabricated part which is processed with the BIM model;

the cloud platform and the mobile login terminal correspond to each other in information and are synchronously arranged;

wherein,

the basic data setting module comprises project information setting, material library setting, process setting, mechanical setting, personnel setting, table management, quality control setting, transport ship setting and warehouse setting; the basic data setting module is used for improving the service data logic of the system by a manager;

the design data management module comprises construction drawing management and prefabrication processing management; the construction drawing management leads in digital nesting drawing data, nesting drawing part lists and excess materials; generating a unique number and a two-dimensional code for each part and excess materials by prefabrication management;

the BIM management module comprises BIM management and BIM engine management; the BIM model management is used for managing a BIM model source file and a lightweight file thereof, managing a BIM model version and managing an oblique photography file;

the project schedule management module comprises engineering structure division, schedule registration, processing nesting recording and welding seam position registration; the engineering structure division decomposes a project engineering structure through a built-in engineering structure tree template, and comprises the steps of division of the engineering structure in parts and items, numbering of systems and rules of all process nodes, catalog setting of quality acceptance data of all nodes, association of engineering nodes and on-site part or unit part numbers, association of the engineering nodes and a nesting diagram, association of the engineering nodes and a construction diagram, and association of the engineering nodes and a BIM model component; the progress data of each process on site is registered and visually displayed through the progress registration; the processing nesting records the drawing information of the registered processing blanking, the used raw material basic information and the blanking part site number information; the welding seam position registration is combined with a BIM model to carry out number registration on the welding seam of each part;

the raw material information management module comprises raw material purchasing management, raw material entering registration, raw material storage management, raw material detection management and raw material quality acceptance; the raw material purchasing management generates a raw material purchasing list through the raw material list of the associated set material diagram; the raw material entering registration imports the delivery number, the furnace batch number, the quality guarantee book number and the accessories of the entering raw materials into a system, and checks whether the entering quantity of the raw materials is accurate or not by combining with a purchase list; the raw material storage management is used for checking the data of the storage quantity, the stacking position, the warehouse entry and the warehouse exit of each raw material and providing early warning of low storage quantity; the raw material detection management is used for uploading raw material spot check detection data; the quality acceptance of the raw material is used for uploading and checking the raw material review data;

the quality acceptance management module comprises welding line detection management and raw material quality acceptance, wherein the welding line detection management is used for uploading welding line flaw detection report data, and the quality acceptance data management is used for uploading each quality acceptance data;

the warehouse management module is used for checking stored articles of each warehouse, checking in and out warehouse information and registering in and out warehouses;

the factory transportation management comprises transportation task creation, prefabricated part factory confirmation and transportation process information inquiry.

Preferably, the design data management module manages each precast beam, and reflects the quality acceptance information of the construction unit, the site responsible person, the supervision unit, the site supervision, the bridge name, the precast beam number, the pouring date, the tension and grouting date and the concrete strength of the precast beam in the two-dimensional code.

Preferably, the step of managing the prefabrication of the beam comprises,

the method comprises the steps that precast beam sites are arranged, a basic data setting module is used for setting the average precast period of each precast beam and the turnover frequency of templates in the basic data setting module, and when the number of precast beams, the construction period and the number of input template sets are input, the number of precast site tires to be built is automatically calculated; the basic data setting module calculates the reasonable number of the beam storage ground tires according to the number of the prefabricated ground tires, the average prefabrication progress, the prefabrication and hoisting time difference and the average hoisting progress; the method comprises the following steps that the requirements of a standardized prefabricated yard are arranged in a basic data setting module, and when the length and the width of the prefabricated yard are input, the basic data setting module can automatically manufacture a ground layout plane according to the standardized requirements and the calculated ground number;

according to the examination and approval flow of the precast beam yard construction scheme, relevant construction schemes and examination and approval flows are examined and approved in the basic data setting module according to the group company temporary construction implementation scheme;

the method comprises the following steps of performing information management on a precast beam yard, wherein management personnel input information of items, name positions, field responsible persons, field management personnel, the number of persons and responsible persons of each professional team and each professional team, names of bridges responsible for prefabrication, beam types and quantity, prefabrication starting time and hoisting starting time of the precast beam yard through a basic data setting module;

the method comprises the following steps of performing precast beam yard progress management, wherein a project progress management module makes prefabrication plans and hoisting plans respectively, the prefabrication plans are worked out according to the hoisting plans of each bridge, and a logical relationship is established;

the mobile login end inputs actual progress every day and imports a project progress management module;

and the project progress management module reflects the planned progress and the corresponding actual progress in the same table, visually displays the completion proportion and the progress index, judges the progress speed according to the progress index, and performs early warning supervision and reason analysis on the task with delayed progress.

Preferably, the mobile login end further comprises a raw material incoming acceptance module, and the raw material incoming acceptance module is used for inputting raw material incoming time, material types, model specifications, furnace batch numbers, quantity, finished product names and field photos and synchronizing the raw material incoming time, the material types, the model specifications, the furnace batch numbers, the quantity, the finished product names and the field photos to the cloud platform.

Preferably, the mobile login end further comprises a model and part binding module, the model and part binding module can load a part BIM (building information modeling) model divided into multiple segments, a manager selects a part in the part BIM model and scans a two-dimensional code of a prefabricated part on site, and the model and part binding module acquires information in the two-dimensional code and judges whether the number types of the prefabricated part are consistent and the actual number is repeated so as to determine whether binding can be performed; the model and part binding module can judge the in-place condition of the processed part through the binding condition of the BIM model and the part.

Preferably, the cloud platform and/or the mobile login end are/is provided with a visual display main interface, the main interface comprises a bridge prefabricated part BIM integral model located in the middle of the main interface, a part state progress frame and a toolbar, and the toolbar is arranged on the upper side of the visual display interface; the component state progress frame is arranged on the lower side of the visual display interface and comprises a plurality of condition table frames which are sequentially connected in a pointing mode through arrows, the condition table frames are sequentially named as the condition table frames which are not processed, stored, transported and installed, the condition table frames are different in color and display the number of corresponding prefabricated components in the state, and the display color of the prefabricated components in the bridge prefabricated component BIM integral model corresponds to the color of the table frames.

Due to the adoption of the technical scheme, the invention has the following beneficial effects:

the quality management in the system of the invention manages the model, construction condition and transportation condition of the component in the form of electronic document for the processing plant, which is convenient for storage and filling, and the system can automatically analyze, process and share the data.

The invention can accurately trace the source by uniquely numbering and distinguishing each component.

The invention tracks the factory transportation information of the prefabricated part, accurately arranges the construction time and saves the resources;

the cloud platform and the mobile login terminal are connected in data and synchronous in information, and the mobile terminal is used on site to facilitate the timely input and check of data information.

The invention can intuitively know the processing and construction progress of each component at the project part through the system, and is convenient for the overall management and control of the project.

Drawings

FIG. 1 is a functional flow diagram of the implementation of the present invention.

Detailed Description

The following further describes the embodiments of the present invention with reference to the drawings.

The invention discloses a BIM (building information modeling) informatization management system for bridge prefabricated parts, which comprises a cloud platform and a mobile login end; the cloud platform and the mobile login terminal correspond to each other in information and are synchronously set.

The cloud platform comprises a basic data setting module, a design data management module, a BIM model management module, a project progress management module, a raw material information management module, a quality acceptance management module, a warehousing management module and a factory transportation management module. The cloud platform combines the BIM model to inquire and show the engineering information of steel construction processing installation project, and the engineering information includes the project general overview, accomplishes output, processing progress, installation progress and quality acceptance qualification rate.

here, the design data management module includes construction drawing management and prefabrication processing management; the construction drawing management leads in digital nesting drawing data, nesting drawing part lists and excess materials; and performing machining management to generate a unique number and a two-dimensional code for each part and each excess material. The design data management module manages each precast beam, and reflects the quality acceptance information of the construction unit and the site responsible person, the supervision unit and the site supervision, the bridge name, the number of the precast beam, the pouring date, the tension grouting date and the concrete strength of the precast beam in the two-dimensional code.

the project schedule management module comprises engineering structure division, schedule registration, processing nesting recording and welding seam position registration; the project structure division decomposes a project engineering structure through a built-in project structure tree template, and comprises division of the project structure in different parts and items, serial numbers of systems and rules of all process nodes, directory setting of quality acceptance data of all nodes, association of the project nodes and on-site part or unit part serial numbers, association of the project nodes and a nesting diagram, association of the project nodes and a construction diagram, and association of the project nodes and a BIM model component; the progress data of each process on site is registered and visually displayed through the progress registration; the processing jacking records, registers drawing information of processing blanking, used raw material basic information and blanked part field number information; the welding seam position registration is combined with a BIM model to carry out number registration on the welding seam of each part;

the raw material information management module comprises raw material purchasing management, raw material entering registration, raw material warehousing management, raw material detection management and raw material quality acceptance; the raw material purchasing management generates a raw material purchasing list through the raw material list of the associated set material diagram; the raw material entering registration imports the delivery number, the furnace batch number, the quality guarantee book number and the accessories of the entering raw materials into a system, and checks whether the entering quantity of the raw materials is accurate or not by combining with a purchase list; the raw material storage management is used for checking the data of the storage quantity, the stacking position, the warehouse entry and the warehouse exit of each raw material and providing early warning of low storage quantity; the raw material detection management is used for uploading raw material spot check detection data; the quality acceptance of the raw material is used for uploading and checking the raw material review data;

here, the factory transportation management includes transportation task creation, prefabricated part factory confirmation, and transportation process information inquiry.

The mobile login end identifies the two-dimensional code of the factory prefabricated part through the WeChat code scanning, and inquires a part model, quality control data, raw materials, process information and a real object photo of the prefabricated part bound by the related two-dimensional code; and binding the machined prefabricated part with the BIM by the mobile login end. The mobile login end further comprises a raw material incoming acceptance module, and the raw material incoming acceptance module is used for inputting raw material incoming time, material types, model specifications, furnace batch numbers, quantity, finished product names and field photos and synchronizing the raw material incoming time, the material types, the model specifications, the furnace batch numbers, the quantity, the finished product names and the field photos to the cloud platform.

The mobile login end further comprises a model and part binding module, the model and part binding module can load a part BIM (building information modeling) model divided into multiple sections, managers select parts in the part BIM model and then perform on-site two-dimensional codes of prefabricated parts through code scanning, and the model and part binding module acquires information in the two-dimensional codes and judges whether the number types of the prefabricated parts are consistent or not and whether actual numbers are repeated or not so as to determine whether binding can be performed or not; the model and part binding module can judge the in-place condition of the processed part through the binding condition of the BIM model and the part.

Cloud platform or removal login end all are equipped with visual display main interface, and main interface is including the whole model of bridge prefabricated component BIM, component state progress frame and the toolbar that is located the main interface intermediate position, the toolbar sets up at visual display interface upside. The component state progress frame is arranged on the lower side of the visual display interface and comprises condition table frames which are sequentially pointed by arrows, the condition table frames are sequentially named as non-processed, finished in storage, finished in transportation, finished on-site and mounted, the different condition table frames adopt different colors and display the number of the corresponding prefabricated components in the state, and the display color of the prefabricated components in the BIM integral model of the bridge prefabricated component corresponds to the color of the table frames.

The step of managing the prefabrication of the beam comprises,

the method comprises the steps that precast beam sites are arranged, a basic data setting module is used for setting the average precast period of each precast beam and the turnover frequency of templates in the basic data setting module, and when the number of precast beams, the construction period and the number of input template sets are input, the number of precast site tires to be built is automatically calculated; the basic data setting module calculates the reasonable number of the beam storage ground tires according to the number of the prefabricated ground tires, the average prefabrication progress, the prefabrication and hoisting time difference and the average hoisting progress; the requirement of the standardized prefabricated yard is arranged in the basic data setting module, and when the length and the width of the prefabricated yard are input, the basic data setting module can automatically manufacture a ground layout plane according to the standardized requirement and the calculated ground number.

And in the basic data setting module, the construction scheme and the approval flow are determined according to the approval of the temporary construction scheme of the group company.

And (3) managing the information of the precast beam yard, wherein managers input the information of the project, name and position, field responsible person, field manager, the number of people and responsible persons of each professional team and group, the name, type and number of the beam, the prefabrication starting time and the hoisting starting time of the precast beam yard through a basic data setting module.

And (4) carrying out precast beam yard progress management, wherein a project progress management module makes prefabrication and hoisting plans respectively, and compiles the prefabrication plan according to the hoisting plan of each bridge to establish a logical relationship.

And the mobile login end inputs the actual progress every day and imports the project progress management module.

As shown in fig. 1, the present invention takes the implementation process of the steel structure processing information management engineering of the plannan three-bridge steel structure as an example, and the operation implementation of the present invention can be further understood through the block diagram, and the specific engineering management steps include:

(1) starting and planning production plan, the manager establishes the engineering service data logic through the basic data setting module, and fills corresponding engineering information in the project information setting, material library setting, process setting, mechanical setting, personnel setting, form management, quality control setting, transport ship setting and warehouse setting in sequence; and finishing production planning and dividing production progress nodes.

(2) Leading in digital nesting diagram data, a nesting diagram part list and excess materials by a manager through a design data management module; and generating a unique number and a two-dimensional code for each part and each residual material. And finishing the associated construction drawing.

(3) Raw material purchasing and entering, namely generating a raw material purchasing list by using a raw material information management module through a raw material list of an associated set material diagram; importing the delivery serial number, the furnace batch number, the quality insurance book number and the accessories of the incoming raw materials into a system, and checking whether the incoming quantity of the raw materials is accurate or not by combining with a purchase list.

(4) Preprocessing, namely decomposing a project engineering structure through an engineering structure tree template built in a project progress management module, wherein the method comprises the steps of dividing the project of the project structure in parts and items, numbering systems and rules of all process nodes, setting catalogs of quality acceptance data of all nodes, associating the project nodes with on-site part or unit part numbers, associating the project nodes with a nesting diagram, associating the project nodes with a construction diagram, and associating the project nodes with a BIM model component; registering and visually displaying progress data of each process on site; registering drawing information of processing and blanking, basic information of used raw materials and field number information of blanked parts; the weld of each part was numbered in combination with the BIM model.

(5) And pre-assembling, namely managing the pre-assembling progress through a project progress management module.

(6) Transportation, namely creating a transportation task, confirming that the prefabricated part leaves a factory, and inquiring transportation process information; and combined with map visualization.

(7) And (4) field installation, scanning the two-dimensional code of the prefabricated part by the mobile login end, associating the prefabricated part with the BIM model, inputting the actual progress every day, and importing the actual progress into the project progress management module.

(8) The management personnel manage the project progress through the visual display main interface, and for the prefabricated parts which are not processed, are stored, are transported, are finished to reach the site and are installed, different colors are adopted to represent different states and display the number of the prefabricated parts in the state.

The above description is intended to describe in detail the preferred embodiments of the present invention, but the embodiments are not intended to limit the scope of the claims of the present invention, and all equivalent changes and modifications made within the technical spirit of the present invention should fall within the scope of the claims of the present invention.

Claims

1. A BIM information management system for bridge prefabricated parts comprises a cloud platform and a mobile login end; the method is characterized in that: the cloud platform comprises a basic data setting module, a design data management module, a BIM model management module, a project progress management module, a raw material information management module, a quality acceptance management module, a warehousing management module and an ex-factory transportation management module; the cloud platform is combined with the BIM model to inquire and display the engineering information of the steel structure processing and installation project, wherein the engineering information comprises project outline, finished output value, processing progress, installation progress and quality acceptance qualification rate;

wherein,

the design data management module comprises construction drawing management and prefabrication processing management; the construction drawing management leads in digital nesting drawing data, nesting drawing part lists and excess materials; the method comprises the steps that prefabricating, processing and managing generate unique numbers and two-dimensional codes for each part and excess materials;

the project progress management module comprises engineering structure division, progress registration, processing jacking recording and welding seam position registration; the project structure division decomposes a project engineering structure through a built-in project structure tree template, and comprises division of the project structure in different parts and items, serial numbers of systems and rules of all process nodes, directory setting of quality acceptance data of all nodes, association of the project nodes and on-site part or unit part serial numbers, association of the project nodes and a nesting diagram, association of the project nodes and a construction diagram, and association of the project nodes and a BIM model component; the progress data of each process on site is registered and visually displayed through the progress registration; the processing nesting records the drawing information of the registered processing blanking, the used raw material basic information and the blanking part site number information; the welding seam position registration is combined with a BIM model to carry out number registration on the welding seam of each part;

the raw material information management module comprises raw material purchasing management, raw material entering registration, raw material storage management, raw material detection management and raw material quality acceptance; the raw material purchasing management generates a raw material purchasing list through the raw material list of the associated set material diagram; the raw material entering registration imports the delivery number, the furnace batch number, the quality guarantee book number and the accessories of the entering raw materials into a system, and checks whether the entering quantity of the raw materials is accurate or not by combining with a purchase list; the raw material storage management is used for checking the storage quantity, stacking position and warehouse-in and warehouse-out data of each raw material and providing early warning of low storage quantity; the raw material detection management is used for uploading raw material spot check detection data; the quality acceptance of the raw material is used for uploading and checking the raw material review data;

the factory transportation management comprises transportation task creation, prefabricated part factory confirmation and transportation process information inquiry;

the step of managing the prefabrication of the beam comprises,

according to the method, a precast beam yard construction scheme approval flow is carried out, and a construction scheme and an approval flow are approved and approved according to a group company temporary construction implementation scheme in a basic data setting module;

the method comprises the following steps of managing the progress of a precast beam field, respectively making a prefabrication plan and a hoisting plan by a project progress management module, compiling the prefabrication plan according to the hoisting plan of each bridge, and establishing a logical relationship;

2. The bridge prefabricated member BIM informatization management system according to claim 1, characterized in that: the design data management module manages each precast beam, and reflects the quality acceptance information of the construction unit, the site responsible person, the supervision unit, the site supervision, the bridge name, the number of the precast beam, the pouring date, the tensioning and grouting date and the concrete strength of the precast beam in the two-dimensional code.

3. The bridge prefabricated member BIM informatization management system according to claim 1, characterized in that: the mobile login end further comprises a raw material incoming acceptance module, and the raw material incoming acceptance module is used for inputting raw material incoming time, material types, model specifications, furnace batch numbers, quantity, finished product names and field photos and synchronizing the raw material incoming time, the material types, the model specifications, the furnace batch numbers, the quantity, the finished product names and the field photos to the cloud platform.

4. The bridge prefabricated member BIM informatization management system according to claim 1, characterized in that: the mobile login end further comprises a model and part binding module, the model and part binding module can load a part BIM (building information modeling) model divided into multiple sections, managers select parts in the part BIM model and then perform on-site prefabrication on of the two-dimensional codes of the components through code scanning, and the model and part binding module acquires information in the two-dimensional codes and judges whether the number types of the prefabricated components are consistent and the actual numbers are repeated so as to determine whether the prefabricated components can be bound; the model and part binding module can judge the in-place condition of the processed part through the binding condition of the BIM model and the part.

5. The bridge prefabricated member BIM informatization management system according to claim 1, characterized in that: the cloud platform and/or the mobile login end are/is provided with a visual display main interface, the main interface comprises a bridge prefabricated part BIM integral model, a part state progress frame and a toolbar, the bridge prefabricated part BIM integral model is located in the middle of the main interface, and the toolbar is arranged on the upper side of the visual display interface; the component state progress frame is arranged on the lower side of the visual display interface and comprises a plurality of condition table frames which are sequentially connected in a pointing mode through arrows, the condition table frames are sequentially named as non-machined, stored, transported, finished and on-site and installed, the table frames in different conditions adopt different colors and display the number of corresponding prefabricated components in the state, and the display colors of the prefabricated components in the BIM integral model of the bridge prefabricated component correspond to the colors of the table frames.