CN109446664B - On-site progress management display equipment system - Google Patents

Abstract

The invention relates to the technical field of engineering management, in particular to a field progress management display equipment system, which comprises a true three-dimensional engineering model building module, a real three-dimensional engineering model generation module and a real three-dimensional engineering model generation module, wherein the true three-dimensional engineering model building module is used for generating a true three-dimensional engineering model; the progress filling module is used for constructors to fill engineering progress data in real time; the three-dimensional engineering model display module is associated with the data of the Cheng Jindu reporting module and updates the construction progress information on the true three-dimensional engineering model in real time; the progress management module is used for making or adjusting the engineering progress of management personnel and acting on the three-dimensional engineering model display module; the construction auxiliary information module is used for acquiring notes of the construction process and information of safety equipment and tools required by construction; and the electronic display screen is used for receiving the data of the three-dimensional engineering model display module and providing information required by construction for site constructors. The invention can provide the information required by the construction process for constructors, and can enable the manager to know the progress of the project in time.

Description

On-site progress management display equipment system

Technical Field

The invention relates to the technical field of engineering management, in particular to a field progress management display device system.

Background

The construction progress management of the engineering project is an important link of engineering project management, and the development of the engineering progress management level is restricted due to the characteristics of lag information, low informatization degree and the like of the traditional progress management method. Because the large-scale engineering has the characteristics of large construction difficulty, long period and more operators, the large-scale engineering can face a plurality of problems in terms of progress and cost during engineering construction. The traditional method is to schedule engineering progress first and then control cost through the progress.

In order to improve the efficiency of site progress management, in the conventional construction progress management method, a display signboard is usually arranged on the site to display some information related to the site progress, such as project construction progress plan, actual site construction progress, progress deviation and the like. However, the conventional display panel is usually handwritten, needs to be modified and written every day, is inconvenient to actually operate, can display limited information, cannot effectively reflect the progress condition of the project, and when the construction progress is managed by the method, a manager needs to know the progress completed by the constructor on site or acquire the progress condition through a multi-layer report, and the manager cannot acquire the progress condition of the project in time.

Disclosure of Invention

In order to solve the problems, the on-site progress management display equipment system can effectively provide information required by a construction process for constructors and enable the manager to know the progress condition of engineering in time.

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

the field progress management display equipment system comprises a true three-dimensional engineering model building module, a BIM three-dimensional model building module, a GIS three-dimensional topographic map building module, a progress reporting module, a three-dimensional engineering model display module, a progress management module, a construction auxiliary information module, an electronic display screen and a data server,

the BIM three-dimensional model building module is used for building a BIM three-dimensional model of engineering through software, dividing the BIM three-dimensional model into a plurality of engineering components, and inputting information of component names, materials, affiliated positions, engineering quantity and manufacturing cost relative to an actual engineering part of the engineering components;

the GIS three-dimensional topographic map building module is used for carrying out space three encryption calculation on site topographic data through Smart3D software to generate point cloud data, and producing an actual topographic map of the engineering site through the point cloud data;

the true three-dimensional engineering model building module is used for combining the data of the BIM three-dimensional model building module with the data of the GIS three-dimensional topographic map building module and generating a true three-dimensional engineering model;

the progress filling module is used for filling engineering progress data in real time by constructors through constructor terminals;

the three-dimensional engineering model display module is used for displaying the true three-dimensional engineering model, and the data of the Cheng Jindu reporting module is associated with the true three-dimensional engineering model building module to update the construction progress information on the true three-dimensional engineering model in real time;

the progress management module is used for making or adjusting the project progress through a manager terminal according to the information of the three-dimensional project model display module and acting the making or adjusting data of the project progress on the three-dimensional project model display module;

the construction auxiliary information module is used for acquiring the positions of the construction members and the construction projects of the construction members according to the progress management module, acquiring notes of the construction process and information of safety equipment and tools required by construction through a machine learning algorithm, and transmitting the information to the three-dimensional engineering model display module;

the electronic display screen is respectively arranged on the construction site of each engineering component and is used for receiving the data of the three-dimensional engineering model display module in real time through the data transmission module, the electronic display screen comprises a progress comparison module, a construction information display module and an engineering component information display module, and the progress comparison module is used for carrying out analysis processing on the data of the progress filling module and the progress management module in the three-dimensional engineering model display module to update the difference between the actual progress and the planned progress of the engineering component and the overall engineering completion percentage in real time; the construction information display module is used for demonstrating the construction method by receiving the data of the progress management module in the three-dimensional engineering model display module, listing the construction tasks and steps and simulating animation; the engineering component information display module is used for establishing module information by receiving the BIM three-dimensional model in the three-dimensional engineering model display module and displaying information of component names, materials, affiliated positions, engineering quantity and manufacturing cost corresponding to the engineering components;

the data server is used for storing or transmitting data of the three-dimensional engineering model display module, the progress management module and the construction auxiliary information module.

Further, the GIS three-dimensional topographic map establishing module obtains site topographic data through an unmanned aerial vehicle aerial photographing technology.

Further, the true three-dimensional engineering model building module is used for generating a true three-dimensional engineering model by leading the terrain information of the GIS three-dimensional terrain map building module into Lumion software to be combined with the three-dimensional model of the BIM three-dimensional model building module.

Further, the construction information display module makes a construction method simulation animation through Naviswork software.

The system comprises a first monitoring module, a second monitoring module and a third monitoring module, wherein the first monitoring module comprises a first video acquisition sub-module and a first identification comparison sub-module, and the first video acquisition sub-module is used for shooting construction personnel safety equipment wearing information and construction tool information before departure; the first recognition comparison submodule is used for extracting the characteristic image of the first video acquisition submodule and comparing the characteristic image of the first video acquisition submodule with the information of the construction auxiliary information module; when the information of the first recognition comparison submodule is not matched, the first recognition comparison submodule prompts constructors to shoot again, and the information which is not matched is sent to the three-dimensional engineering model display module through the data server.

The construction safety reminding system comprises a construction auxiliary information module, a first supervision module, a second supervision module and a construction safety reminding module, wherein the construction auxiliary information module is used for acquiring a construction personnel's safety equipment wearing condition video through a camera arranged on an engineering component, and the second supervision module comprises a second video acquisition sub-module and a second identification comparison sub-module which are used for extracting a characteristic image of the second video acquisition sub-module and comparing the characteristic image of the second video acquisition sub-module with the information of the construction auxiliary information module; when the data of the second recognition comparison sub-module is not matched, the second recognition comparison sub-module sends the unmatched characteristic image and unmatched content of the second video acquisition sub-module to the three-dimensional engineering model display module, and the construction safety reminding module receives the information of the second supervision module in the three-dimensional engineering model display module and displays the situation that the safety equipment of the constructor is not correctly worn.

Further, the construction safety reminding module can be used for receiving information of the construction auxiliary information module in the three-dimensional engineering model display module and displaying notes of a construction process.

Further, a field progress management display device system according to claims 1-7, characterized in that: the management method adopting the system comprises the following steps,

s1, building a BIM three-dimensional model in the BIM three-dimensional model building module according to actual engineering, dividing the BIM three-dimensional model into a plurality of engineering components according to actual engineering parts, and inputting information of component names, materials, affiliated positions, engineering quantities and manufacturing cost of the engineering components;

s2, obtaining site topographic data through an unmanned aerial vehicle aerial photographing technology, in the GIS three-dimensional topographic map building module, performing space three encryption calculation on the site topographic data through Smart3D software to generate point cloud data, and manufacturing an actual topographic map of an engineering site through the point cloud data;

s3, importing the topographic information into Lumion software, combining the topographic information with the three-dimensional model of the BIM three-dimensional model building module, and generating a true three-dimensional engineering model in the three-dimensional engineering model display module;

s4, the manager carries out information of component names, materials, belonged positions, engineering quantities and manufacturing costs according to the engineering components in the three-dimensional engineering model display module and makes a planned engineering progress in the progress management module according to big data;

s5, a constructor clicks the construction auxiliary information module on the three-dimensional engineering model display module to obtain notes in a working process, safety equipment required to be worn by work and information of tools required by work, wears the safety equipment and prepares the tools according to requirements, the constructor shoots the wearing condition of the safety equipment and the preparation condition of the construction tools through the first video acquisition sub-module, the first identification comparison sub-module compares the characteristic images of the first video acquisition sub-module with the information of the construction auxiliary information module, and when the first identification comparison sub-module is not matched, reminds the constructor that the safety equipment is worn by the information which does not meet the requirements, and the information which lacks or is wrong in the construction tools and prompts are shot again, and feeds the comparison result back to the three-dimensional engineering model display module;

s6, the construction information display module lists the construction tasks and steps by receiving the progress management module, and creates a construction method simulation animation by Navisworks software; the constructor acquires the task and steps of construction through the construction information display module and simulates animation to perform construction through watching a construction method;

s7, at a construction site, the second video acquisition submodule shoots the wearing condition of safety equipment of constructors, and the second identification comparison submodule compares the characteristic images of the second video acquisition submodule with the information of the construction auxiliary information module; when the data of the second recognition comparison sub-module is not matched, the second recognition comparison sub-module sends the unmatched characteristic image and unmatched content to the three-dimensional engineering model display module, and the unmatched characteristic image and the unmatched content are displayed on an electronic screen through the construction safety reminding module;

s8, when a constructor finishes a certain work, the progress filling module is used for filling engineering progress data, and the progress comparison module is used for receiving the data of the progress filling module and the progress management module in the three-dimensional engineering model display module to analyze and process so as to update the difference between the actual progress and the planned progress of the engineering component and the overall engineering completion percentage in real time;

s9, after the preset working time, the manager adjusts the project progress through the manager terminal according to the actual progress condition of the three-dimensional project model display module.

The invention has the advantages that,

the BIM three-dimensional model building module divides the BIM three-dimensional model into a plurality of engineering components, the engineering components and the actual engineering parts are opposite to each other and can carry out information input of component names, materials, belonged positions, engineering quantities and manufacturing cost, the engineering components are decomposed according to the modules, each module is provided with a label, and statistics of a 0# account is facilitated; the GIS three-dimensional topographic map building module obtains site topographic data through an unmanned aerial vehicle aerial photographing technology, performs space three encryption calculation on the site topographic data through Smart3D software to generate point cloud data, and makes an actual topographic map of an engineering site through the point cloud data. The true three-dimensional engineering model building module combines the two to provide visual information for the manager, so that the information can be acquired conveniently.

2. The method comprises the steps that a manager obtains information of actual construction progress in a three-dimensional engineering model display module, and makes or adjusts a planning progress in a progress management module according to the information of the actual construction progress through a manager terminal, and the progress management module sends the planning progress information to the three-dimensional engineering model display module; and the constructor acquires the latest plan progress information in the three-dimensional engineering model display module through the electronic display, and executes tasks according to the plan progress information, and the constructor fills the actual progress completion condition in the progress filling module. The WBS and BIM model mutual mapping is achieved, construction information of engineering components can be timely obtained by constructors and management staff, construction flexibility is improved, the constructors can timely execute tasks according to the planned progress information, and the management staff can adjust the construction progress of the engineering components according to the actual progress completion condition of the progress filling module. The construction method can facilitate new people to know project construction technology through simulating animation demonstration, and is also beneficial to the communication popularization of the technology

3. The second frequency vision acquisition submodule acquires a video of wearing conditions of safety equipment of constructors through a camera arranged on the engineering component, and the second identification comparison submodule is used for extracting characteristic images of the second video acquisition submodule and comparing the characteristic images of the second video acquisition submodule with information of the construction auxiliary information module. When the second recognition comparison submodule data are not matched, the second recognition comparison submodule can send the fact that the photos of the constructors and the safety equipment are not correctly worn to the electronic display screen, so that the constructors can wear the safety equipment timely according to requirements, and accidents in the construction process are avoided.

4. The first video acquisition sub-module is used for shooting construction personnel safety equipment wearing information and construction tool information before departure; the first recognition comparison submodule is used for extracting the characteristic image of the first video acquisition submodule and comparing the characteristic image of the first video acquisition submodule with the information of the construction auxiliary information module. The constructor finishes wearing the safety equipment and shoots through the first video acquisition submodule, when the information of the first identification comparison submodule is not matched, the first identification comparison submodule prompts the constructor to shoot again, and the problem that engineering progress is delayed or even a safety accident occurs due to incomplete preparation or irregular wearing of the safety equipment is avoided. The constructor shoots the tools required by construction through the first video acquisition submodule in sequence according to the information provided by the construction auxiliary information module, and when the information of the first identification comparison submodule is not matched, the first identification comparison submodule prompts the missing tools or carries the information of the wrong tools, so that the condition that the construction progress is delayed due to insufficient tool preparation of the constructor is avoided.

Drawings

Fig. 1 is a block diagram of the system architecture of the present invention.

In the figure, a 1-true three-dimensional engineering module building module, a 11-BIM three-dimensional model building module, a 12-GIS three-dimensional model building module, a 2-progress reporting module, a 21-constructor terminal, a 3-three-dimensional engineering model display module, a 4-progress management module, a 41-manager terminal, a 5-construction auxiliary information module, a 51-first supervision module, a 511-first frequency view acquisition submodule, a 512-first identification comparison submodule, a 52-second supervision module, a 521-second frequency view acquisition submodule, a 522-second identification comparison submodule, a 6-electronic display screen, a 61-progress comparison module, a 62-construction information display module, a 63-engineering component information display module, a 64-construction safety reminding module, a 7-data transmission module and an 8-data server.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The on-site progress management display equipment system comprises a true three-dimensional engineering model building module 1, a BIM three-dimensional model building module 11, a GIS three-dimensional topographic map building module 12, a progress filling module 2, a three-dimensional engineering model display module 3, a progress management module 4, a construction auxiliary information module 5, an electronic display screen 6 and a data server 8.

The BIM three-dimensional model building module 11 is used for building a BIM three-dimensional model of engineering through software, dividing the BIM three-dimensional model into a plurality of engineering components, and inputting information of component names, materials, affiliated positions, engineering quantity and manufacturing cost relative to an actual engineering part. In this embodiment, the BIM three-dimensional model building module 11 builds an engineered BIM three-dimensional model through the Revit or CATIA software.

The GIS three-dimensional topographic map creation module 12 is configured to perform space three encryption calculation on the site topographic data through Smart3D software to generate point cloud data, and create an actual topographic map of the engineering site through the point cloud data. In this embodiment, the GIS three-dimensional topography creation module 12 obtains on-site topography data through unmanned aerial vehicle aerial technology.

The true three-dimensional engineering model building module 1 is used for combining the data of the BIM three-dimensional model building module 11 with the data of the GIS three-dimensional topographic map building module 12 and generating a true three-dimensional engineering model. In this embodiment, the true three-dimensional engineering model building module 1 generates a true three-dimensional engineering model by importing the topographic information of the GIS three-dimensional topographic map building module 12 into Lumion software to combine with the three-dimensional model of the BIM three-dimensional model building module 11.

The BIM three-dimensional model building module 11 divides the BIM three-dimensional model into a plurality of engineering components, and the engineering components and the actual engineering parts can input information of component names, materials, belonging positions, engineering quantities and manufacturing cost relative to each other; the GIS three-dimensional topographic map building module 12 obtains site topographic data through an unmanned aerial vehicle aerial photographing technology, performs space three encryption calculation on the site topographic data through Smart3D software to generate point cloud data, and makes an actual topographic map of an engineering site through the point cloud data. The true three-dimensional engineering model building module 1 combines the above two to provide visual information for the manager, so that the information can be conveniently obtained.

The progress filling module 2 is used for a constructor to fill engineering progress data in real time through the constructor terminal 21.

The three-dimensional engineering model display module 3 is used for displaying a true three-dimensional engineering model, and correlates the data of the process progress reporting module 2 with the true three-dimensional engineering model building module 1 to update the construction progress information on the true three-dimensional engineering model in real time;

the progress management module 4 is used for making or adjusting the project progress by a manager through the manager terminal 41 according to the information of the three-dimensional project model display module 3, and applying the making or adjusting data of the project progress to the three-dimensional project model display module 3.

The constructor fills the actual progress completion situation in the progress filling module 2 through the constructor terminal 21. The manager obtains the information of the actual construction progress in the three-dimensional engineering model display module 3, and makes or adjusts the planning progress in the progress management module 4 through the manager terminal 41 according to the information of the actual construction progress, and the progress management module 4 sends the planning progress information to the three-dimensional engineering model display module 3. The management personnel can acquire the construction information of the engineering component in time, so that the construction progress of the engineering component can be adjusted according to the actual progress completion condition of the progress filling module.

The construction auxiliary information module 5 is used for acquiring the positions of the construction members and the construction projects of the construction members according to the progress management module 4, acquiring notes of the construction process and information of safety equipment and tools required by construction through a machine learning algorithm, and transmitting the information to the three-dimensional engineering model display module 3. The constructor can prepare the safety equipment and tools required by construction according to the information provided by the construction auxiliary information module 5, so that the situation that the construction progress is delayed or even a safety accident occurs due to incomplete preparation of the safety equipment or irregular wearing of the safety equipment by the constructor is caused by insufficient preparation of the tools is avoided.

The electronic display screen 6 is respectively arranged at the construction site of each engineering component and is used for receiving the data of the three-dimensional engineering model display module 3 in real time through the data transmission module 7. In this embodiment, the electronic display 6 adopts an LED display, and the data transmission module 7 adopts five twisted pairs as data transmission media.

The electronic display 6 includes a progress comparison module 61, a construction information display module 62, and an engineering component information display module 63.

The progress comparison module 61 performs analysis processing by receiving the data of the progress filling module 2 and the progress management module 4 in the three-dimensional engineering model display module 3 to update the difference between the actual progress and the planned progress of the engineering component and the overall engineering completion percentage in real time. The construction staff obtains the progress information of the engineering components in real time through the progress comparison module 61, so that the production progress of the construction components on the same day and whether the production progress is advanced or normal or delayed compared with the planned progress can be known conveniently. The production progress information of the engineering components is displayed in real time, so that on-site constructors can know the project progress in time, and the urgent sense of work of the constructors is enhanced.

The construction information display module 62 is used for demonstrating the construction method by receiving the data of the progress management module 4 in the three-dimensional engineering model display module 3 and listing the tasks and steps of construction and simulating animation. The constructor obtains the latest planning progress information in the three-dimensional engineering model display module through the construction information display module 62 and executes tasks according to the planning progress information, the constructor fills the actual progress completion situation in the progress filling module 2, the manager obtains the information of the actual construction progress in the three-dimensional engineering model display module 3 and makes or adjusts the planning progress in the progress management module 4 through the manager terminal 41 according to the information of the actual construction progress, and the progress management module 4 sends the planning progress information to the three-dimensional engineering model display module 3. The construction method has the advantages that the constructors can timely execute tasks, the manager can adjust the construction progress of the engineering components, information hysteresis is avoided, and the completion efficiency of engineering is improved.

In this embodiment, the construction information display module 62 creates a construction method simulation animation by using Naviswork software, so that a constructor can quickly grasp the construction method and provide working efficiency.

The engineering component information display module 63 is configured to receive the information of the BIM three-dimensional model building module 11 in the three-dimensional engineering model display module 3 and display the information of the component name, the material, the location, the engineering quantity and the manufacturing cost of the corresponding engineering component. The construction member information display module 63 allows a constructor to understand the construction member at the construction site.

The system further comprises a first supervision module 51, wherein the first supervision module 51 comprises a first video acquisition sub-module 511 and a first identification comparison sub-module 512, and the first video acquisition sub-module 511 is used for shooting construction personnel safety equipment wearing information and construction tool information before departure; the first recognition comparison sub-module 512 is configured to extract a feature image of the first video acquisition sub-module 511, and compare the feature image of the first video acquisition sub-module 511 with information of the construction auxiliary information module 5; when the information of the first recognition comparison sub-module 512 is not matched, the first recognition comparison sub-module 512 prompts constructors to shoot again, and the information of the mismatch is sent to the three-dimensional engineering model display module 3 through the data server 8.

In this embodiment, the constructor finishes wearing the safety equipment and shoots through the first video acquisition sub-module 511, and when the information of the first recognition comparison sub-module 512 is not matched, the first recognition comparison sub-module 512 prompts the constructor to shoot again, so that the problem that the engineering progress is delayed or even a safety accident occurs due to incomplete preparation or irregular wearing of the safety equipment by the constructor is avoided. The constructor shoots the tools required by construction through the first video acquisition sub-module 511 in sequence according to the information provided by the construction auxiliary information module 5, and when the information of the first recognition comparison sub-module 512 is not matched, the first recognition comparison sub-module 512 prompts the missing tools or carries the information of the wrong tools, so that the condition that the construction progress is delayed due to insufficient tool preparation of the constructor is avoided.

A second supervision module 52 and a construction safety reminder module 64 are also included. The second supervision module 52 includes a second video acquisition sub-module 521 and a second recognition comparison sub-module 522, where the second video acquisition sub-module 521 acquires a wearing condition video of safety equipment of a constructor through a camera installed on an engineering component, and the second recognition comparison sub-module 522 is used to extract a feature image of the second video acquisition sub-module 521 and compare the feature image of the second video acquisition sub-module 521 with information of the construction auxiliary information module 5.

When the data of the second recognition comparison sub-module 522 is not matched, the second recognition comparison sub-module 522 sends the unmatched feature image and the unmatched content of the second video acquisition sub-module 521 to the three-dimensional engineering model display module 3, and the construction safety reminding module 64 receives the information of the second supervision module 52 in the three-dimensional engineering model display module 3 and displays that the safety equipment of the constructor is not correctly worn.

The management method adopting the system comprises the following steps,

s1, building a BIM three-dimensional model in a BIM three-dimensional model building module 11 according to actual engineering, dividing the BIM three-dimensional model into a plurality of engineering components according to actual engineering parts, and inputting information of component names, materials, belongings, engineering quantity and manufacturing cost of the engineering components;

s2, obtaining site topographic data through an unmanned aerial vehicle aerial photographing technology, in a GIS three-dimensional topographic map building module 12, performing space three encryption calculation on the site topographic data through Smart3D software to generate point cloud data, and manufacturing an actual topographic map of an engineering site through the point cloud data;

s3, importing the topographic information into Lumion software, combining the topographic information with a three-dimensional model of the BIM three-dimensional model building module 11, and generating a true three-dimensional engineering model in the three-dimensional engineering model display module 4;

s4, the manager carries out information of component names, materials, affiliated positions, engineering quantities and manufacturing costs according to engineering components in the three-dimensional engineering model display module 4 and makes a planned engineering progress in the progress management module 4 according to big data;

s5, a constructor clicks the construction auxiliary information module 5 on the three-dimensional engineering model display module 4 to obtain notes of a working process, safety equipment required to be worn by the work and information of tools required by the work, wears the safety equipment and prepares the tools according to requirements, the constructor shoots the wearing condition of the safety equipment and the preparation condition of the construction tools through the first video acquisition sub-module 511, the first identification comparison sub-module 512 compares the characteristic images of the first video acquisition sub-module 511 with the information of the construction auxiliary information module 5, and when the first identification comparison sub-module 512 is not matched, reminds the constructor that the safety equipment is worn by the information which is not in accordance with the requirements, the information which is lack or wrong in the construction tools and prompts are shot again, and feeds back the comparison results to the three-dimensional engineering model display module 4;

s6, the construction information display module 62 lists the construction tasks and steps through the receiving progress management module 4, and creates a construction method simulation animation through Navisworks software; the constructor performs construction by acquiring the task and steps of construction at the construction information display module 62 and simulating animation by watching the construction method;

s7, at a construction site, a second video acquisition sub-module 521 shoots the wearing condition of safety equipment of constructors, and a second recognition comparison sub-module 522 compares the characteristic images of the second video acquisition sub-module 521 with information of the construction auxiliary information module 5; when the data of the second recognition comparison sub-module 522 is not matched, the second recognition comparison sub-module 522 sends the unmatched characteristic images and unmatched contents to the three-dimensional engineering model display module 3, and the unmatched characteristic images and the unmatched contents are displayed on an electronic screen through the construction safety reminding module 64;

s8, when a constructor finishes a certain work, the project progress data is filled through the progress filling module 2, and the progress comparison module 61 analyzes and processes the data of the progress filling module 2 and the progress management module 4 in the three-dimensional project model display module 3 to update the difference between the actual progress and the planned progress of the project component and the overall project completion percentage in real time;

s9, after the preset working time, the manager adjusts the project progress through the manager terminal 41 according to the actual progress condition of the three-dimensional project model display module 3.

In this embodiment, when the second recognition comparison sub-module 522 data is not matched, the second recognition comparison sub-module 522 can send the condition that the photo and the safety equipment of the constructor are not correctly worn to the electronic display screen 6, so that the constructor can wear the safety equipment timely according to the requirement, and accidents in the construction process are avoided.

The first supervision module 51 and the second supervision module 52 are used for supervising the preparation condition before working and the construction site condition of constructors, so that smooth construction is ensured, and the safety of the constructors is ensured.

When a construction is performed on a construction element somewhere, a manager makes a construction progress through the manager terminal 41. The constructor prepares the safety equipment and the construction tool according to the information of the construction auxiliary information module 5.

In the construction site, a constructor acquires the task and step of construction through the construction information display module 62 and executes the construction task; when a constructor finishes a certain work, the project progress data is filled through the progress filling module 2. Meanwhile, the progress comparison module 61 updates the difference between the actual progress of the engineering component and the planned progress and the overall engineering completion percentage in real time. After a predetermined working time, the manager adjusts the project progress through the manager terminal 41 according to the actual progress situation of the three-dimensional project model display module 3. The constructor again acquires the task and the step of the latest construction in the construction information display module 62, and the information interaction flow of the constructor and the manager is completed.

Claims (4)

1. The field progress management display equipment system is characterized by comprising a true three-dimensional engineering model building module (1), a BIM three-dimensional model building module (11), a GIS three-dimensional topographic map building module (12), a progress filling module (2), a three-dimensional engineering model display module (3), a progress management module (4), a construction auxiliary information module (5), an electronic display screen (6) and a data server (8),

the BIM three-dimensional model building module (11) is used for building a BIM three-dimensional model of engineering through software, dividing the BIM three-dimensional model into a plurality of engineering components, wherein the engineering components correspond to actual engineering parts and can be used for inputting information of component names, materials, affiliated positions, engineering quantity and manufacturing cost;

the GIS three-dimensional topographic map building module (12) is used for performing space three encryption calculation on site topographic data through Smart3D software to generate point cloud data, and manufacturing an actual topographic map of the engineering site through the point cloud data;

the true three-dimensional engineering model building module (1) is used for combining the data of the BIM three-dimensional model building module (11) with the data of the GIS three-dimensional topographic map building module (12) and generating a true three-dimensional engineering model;

the progress filling module (2) is used for a constructor to fill engineering progress data in real time through the constructor terminal (21);

the three-dimensional engineering model display module (3) is used for displaying the true three-dimensional engineering model, and correlates the data of the progress filling module (2) with the true three-dimensional engineering model building module (1) to update the construction progress information on the true three-dimensional engineering model in real time;

the progress management module (4) is used for making or adjusting the project progress through a manager terminal (41) according to the information of the three-dimensional project model display module (3) and acting the making or adjusting data of the project progress on the three-dimensional project model display module (3);

the construction auxiliary information module (5) is used for acquiring the position of a construction member and the construction project of the construction member according to the progress management module (4), acquiring notes of the construction process and the information of safety equipment and tools required by construction through a machine learning algorithm, and transmitting the information to the three-dimensional engineering model display module (3);

the electronic display screen (6) is respectively arranged on the construction site of each engineering component and is used for receiving the data of the three-dimensional engineering model display module (3) in real time through the data transmission module (7), the electronic display screen (6) comprises a progress comparison module (61), a construction information display module (62) and an engineering component information display module (63), and the progress comparison module (61) is used for carrying out analysis processing on the data of the progress filling module (2) and the progress management module (4) in the three-dimensional engineering model display module (3) to update the difference between the actual progress and the planned progress of the engineering components and the overall engineering completion percentage in real time; the construction information display module (62) is used for demonstrating the construction method by receiving the data of the progress management module (4) in the three-dimensional engineering model display module (3) and listing the construction tasks and steps and simulating animation; the engineering component information display module (63) is used for receiving the information of the BIM three-dimensional model building module (11) in the three-dimensional engineering model display module (3) and displaying the information of the component name, the material, the affiliated position, the engineering quantity and the construction cost of the corresponding engineering component;

the data server (8) is used for storing or transmitting data of the three-dimensional engineering model display module (3), the progress management module (4) and the construction auxiliary information module (5);

the system further comprises a first supervision module (51), wherein the first supervision module (51) comprises a first video acquisition sub-module (511) and a first identification comparison sub-module (512), and the first video acquisition sub-module (511) is used for shooting construction personnel safety equipment wearing information and construction tool information before departure; the first recognition comparison sub-module (512) is used for extracting the characteristic image of the first video acquisition sub-module (511) and comparing the characteristic image of the first video acquisition sub-module (511) with the information of the construction auxiliary information module (5); when the information of the first identification comparison sub-module (512) is not matched, the first identification comparison sub-module (512) prompts constructors to shoot again, and the unmatched information is sent to the three-dimensional engineering model display module (3) through the data server (8);

the system further comprises a second supervision module (52) and a construction safety reminding module (64), wherein the second supervision module (52) comprises a second video acquisition sub-module (521) and a second identification comparison sub-module (522), the second video acquisition sub-module (521) acquires a safety equipment wearing condition video of a constructor through a camera arranged on the engineering component, and the second identification comparison sub-module (522) is used for extracting a characteristic image of the second video acquisition sub-module (521) and comparing the characteristic image of the second video acquisition sub-module (521) with information of the construction auxiliary information module (5); when the data of the second recognition comparison sub-module (522) is not matched, the second recognition comparison sub-module (522) sends the unmatched characteristic image and unmatched content of the second video acquisition sub-module (521) to the three-dimensional engineering model display module (3), and the construction safety reminding module (64) receives the information of the second supervision module (52) in the three-dimensional engineering model display module (3) and displays the situation that the safety equipment of constructors is incorrectly worn;

the construction safety reminding module (64) can also be used for receiving the information of the construction auxiliary information module (5) in the three-dimensional engineering model display module (3) and displaying notes of the construction process;

the management method adopting the system comprises the following steps,

s1, building a BIM three-dimensional model in the BIM three-dimensional model building module (11) according to actual engineering, dividing the BIM three-dimensional model into a plurality of engineering components according to actual engineering parts, and inputting information of component names, materials, affiliated positions, engineering quantities and manufacturing cost of the engineering components;

s2, obtaining site topographic data through an unmanned aerial vehicle aerial photographing technology, in the GIS three-dimensional topographic map building module (12), performing space three encryption calculation on the site topographic data through Smart3D software to generate point cloud data, and manufacturing an actual topographic map of an engineering site through the point cloud data;

s3, importing the topographic information into Lumion software, combining the topographic information with the three-dimensional model of the BIM three-dimensional model building module (11), and generating a true three-dimensional engineering model in the three-dimensional engineering model display module (3);

s4, a manager makes a plan project progress in the progress management module (4) according to the component name, the material, the affiliated position, the project quantity and the cost information of the project component in the three-dimensional project model display module (3) and big data;

s5, a constructor clicks the construction auxiliary information module (5) on the three-dimensional engineering model display module (3) to obtain notes of a working process and information of safety equipment required to be worn and tools required to be worn and used for working, wears the safety equipment and prepares the tools according to requirements, the constructor shoots the wearing condition of the safety equipment and the preparation condition of the construction tools through the first video acquisition sub-module (511), the first identification comparison sub-module (512) compares the characteristic images of the first video acquisition sub-module (511) with the information of the construction auxiliary information module (5), and when the first identification comparison sub-module (512) is not matched, reminds the constructor that the wearing of the safety equipment does not meet the requirements, the lack or the error information of the construction tools and prompts to re-shoot, and feeds the comparison result back to the three-dimensional engineering model display module (3);

s6, the construction information display module (62) lists the construction tasks and steps by receiving the progress management module (4), and creates a construction method simulation animation by using Naviswork software; the constructor performs construction by acquiring the task and steps of construction and viewing the simulation animation of the construction method in the construction information display module (62);

s7, at a construction site, the second video acquisition submodule (521) shoots the wearing condition of safety equipment of constructors, and the second identification comparison submodule (522) compares the characteristic image of the second video acquisition submodule (521) with the information of the construction auxiliary information module (5); when the data of the second recognition comparison sub-module (522) is not matched, the second recognition comparison sub-module (522) sends the unmatched characteristic images and unmatched contents to the three-dimensional engineering model display module (3) and displays the unmatched characteristic images and the unmatched contents on an electronic screen through the construction safety reminding module (64);

s8, when a constructor finishes a certain work, project progress data are filled through the progress filling module (2), and the progress comparison module (61) analyzes and processes the data of the progress filling module (2) and the progress management module (4) in the three-dimensional project model display module (3) to update the difference between the actual progress and the planned progress of the project component and the overall project completion percentage in real time;

s9, after the preset working time, the manager adjusts the project progress through the manager terminal (41) according to the actual progress condition of the three-dimensional project model display module (3).

2. The field progress management display system of claim 1, wherein: the GIS three-dimensional topographic map building module (12) obtains site topographic data through unmanned aerial vehicle aerial technology.

3. The field progress management display system of claim 1, wherein: the real three-dimensional engineering model building module (1) is used for generating a real three-dimensional engineering model by leading the topographic information of the GIS three-dimensional topographic map building module (12) into Lumion software to be combined with the three-dimensional model of the BIM three-dimensional model building module (11).

4. The field progress management display system of claim 1, wherein: the construction information display module (62) makes a construction method simulation animation through Naviswork software.

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