CN114841662A

CN114841662A - Infrastructure construction project management and control method and device, computer equipment and storage medium

Info

Publication number: CN114841662A
Application number: CN202210408990.7A
Authority: CN
Inventors: 郭晓斌; 刘天虎; 杨荣霞; 曹熙; 姚泽林; 何妍; 张继
Original assignee: China Southern Power Grid Big Data Service Co ltd
Current assignee: China Southern Power Grid Big Data Service Co ltd
Priority date: 2022-04-19
Filing date: 2022-04-19
Publication date: 2022-08-02

Abstract

The application relates to a infrastructure construction management and control method, a device, computer equipment, a storage medium and a computer program product. The method comprises the following steps: acquiring basic data and business data, wherein the basic data comprises construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the business data comprises progress planning data and construction actual progress data; determining a plurality of control units, wherein the control units at least comprise a safety control unit, a progress control unit and a quality control unit; analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result; determining corresponding early warning information based on the analysis result; and generating a platform cockpit of the capital construction project based on the basic data, the service data and the analysis result. By adopting the method, the control efficiency of the infrastructure construction project can be improved.

Description

Infrastructure construction project management and control method and device, computer equipment and storage medium

Technical Field

The present application relates to the field of infrastructure engineering technologies, and in particular, to a method and an apparatus for infrastructure engineering management and control, a computer device, a storage medium, and a computer program product.

Background

With the deep integration of artificial intelligence and infrastructure engineering, the realization of the online, the intelligent engineering management and control and the engineering data platformization of the infrastructure business process becomes the future development trend of the infrastructure engineering by using advanced information and communication technologies such as the internet of things and the artificial intelligence.

However, in the current infrastructure construction management and control system, each service module does not form data linkage according to the dimensions of the safety, quality and the like of the project, and still needs to adopt a manual mode to perform data summarization and data analysis, so that the current infrastructure construction management and control system has the problem of low working efficiency.

Disclosure of Invention

In view of the foregoing, it is necessary to provide a infrastructure project management and control method, an apparatus, a computer device, a computer readable storage medium, and a computer program product, which can improve management and control efficiency of infrastructure projects.

In a first aspect, the application provides a method for controlling infrastructure construction projects. The method comprises the following steps:

acquiring basic data and business data, wherein the basic data comprises construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the business data comprises progress planning data and construction actual progress data;

determining a plurality of control units, wherein the control units at least comprise a safety control unit, a progress control unit and a quality control unit;

analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result;

determining corresponding early warning information based on the analysis result;

and generating a platform cockpit of the capital construction project based on the basic data, the service data and the analysis result, and displaying the early warning information in the platform cockpit according to the account number authority and the region authority corresponding to the current login account number.

In one embodiment, the method further comprises: determining each object account, and configuring account authority of each object account based on a department and a post corresponding to each object account, wherein the object accounts comprise accounts belonging to a construction party and accounts belonging to a participating party; for the accounts belonging to the construction party, the region authority of each account belonging to the construction party is configured to belong to a network level, a provincial level, a local city level or a prefecture level based on the geographic position of the project construction site and the region administration authority corresponding to the account belonging to the construction party.

In one embodiment, the progress plan data comprises construction progress plan data and material progress plan data, the safety analysis result comprises an object post-arrival and post-job result, an equipment safety monitoring result and a vehicle in-and-out monitoring result, the progress analysis result comprises a construction progress analysis result and a material progress analysis result, and the quality analysis result comprises a weather monitoring result, a dust monitoring result, a construction site water monitoring result and a construction site electricity utilization monitoring result;

based on a plurality of management and control units, basic data and service data are analyzed to obtain an analysis result, and the method comprises the following steps: analyzing the construction site photos and the object position data according to the risk point distribution condition through a safety control unit to obtain the job-on-post job-performing result of the object; analyzing the equipment monitoring data according to the equipment monitoring parameter template to obtain an equipment safety monitoring result; analyzing the vehicle monitoring data according to the vehicle record information to obtain a vehicle access monitoring result;

comparing the construction progress planning data with the construction actual progress data through a progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a construction progress analysis result; comparing the material progress planning data with the material monitoring data to obtain a material progress analysis result;

and analyzing the environment monitoring data through the quality control unit to obtain a quality analysis result.

In one embodiment, the construction progress plan data comprises a first-level progress plan, a second-level progress plan and a third-level progress plan, the second-level progress plan is obtained by carrying out refinement and division on nodes of the first-level progress plan, the third-level progress plan is obtained by carrying out refinement and division on nodes of the second-level progress plan, and the construction progress analysis result comprises a first-level construction progress analysis result, a second-level construction progress analysis result and a third-level construction progress analysis result;

through progress management and control unit, compare construction progress plan data and construction actual progress data, judge that the engineering progress is in advance, normal or lags behind, obtain construction progress analysis result, include: comparing the primary progress plan with the actual construction progress data through a progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a primary construction progress analysis result; comparing the second-stage progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a second-stage construction progress analysis result; and comparing the three-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a three-level construction progress analysis result.

In one embodiment, the construction progress plan data further includes a key path progress plan, the construction progress analysis result further includes a key path progress analysis result, the construction progress plan data and the construction actual progress data are compared through the progress control unit, the project progress is judged to be in advance, normal or delayed, and a construction progress analysis result is obtained, further including: extracting key nodes from the nodes of the three-level progress plan through a key node library to obtain a key path; the key path supports the operations of adding, modifying and deleting; and comparing the key path progress plan with the actual construction progress data, and judging whether the project progress is advanced, normal or delayed to obtain a key path progress analysis result.

In one embodiment, the actual construction progress data is obtained by reporting by the construction party according to the completion condition of the construction progress, and the method further includes: inquiring the construction site photo according to at least one of the target mark segment and the target process to obtain a target construction site photo, and inquiring the actual construction progress data to obtain the actual construction progress data of the target; interpreting the target construction site picture, and extracting the engineering construction progress to obtain an interpretation result; and comparing the interpretation result with the actual progress data of the target construction, and verifying the accuracy of the actual progress data of the target construction.

In a second aspect, the application further provides a capital construction project management and control device. The device comprises:

the system comprises an acquisition module, a data processing module and a data processing module, wherein the acquisition module is used for acquiring basic data and business data, the basic data comprises construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the business data comprises progress planning data and construction actual progress data;

the analysis module is used for determining a plurality of control units, and the control units at least comprise a safety control unit, a progress control unit and a quality control unit;

the analysis module is also used for analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result;

the analysis module is also used for determining corresponding early warning information based on the analysis result;

and the early warning module is used for generating a platform cockpit of the infrastructure project based on the basic data, the service data and the analysis result, and displaying early warning information in the platform cockpit according to the account number authority and the region authority corresponding to the current login account number.

In a third aspect, the application also provides a computer device. The computer device comprises a memory storing a computer program and a processor implementing the following steps when executing the computer program:

In a fourth aspect, the present application further provides a computer-readable storage medium. The computer-readable storage medium having stored thereon a computer program which, when executed by a processor, performs the steps of:

In a fifth aspect, the present application further provides a computer program product. The computer program product comprising a computer program which when executed by a processor performs the steps of:

According to the infrastructure project management and control method, device, computer equipment, storage medium and computer program product, by collecting basic data and service data, a plurality of management and control units are determined from multiple dimensions such as safety, progress and quality, the basic data and the service data are analyzed through the plurality of management and control units to obtain an analysis result, corresponding early warning information is determined based on the analysis result, the early warning information is displayed in a platform cockpit through generating the infrastructure project, early warning is carried out on abnormal conditions, the purpose of forming data linkage aiming at different dimensions of the project is achieved, the working process is fully automated, data summarization and data analysis are carried out in a manual mode, and therefore management and control efficiency of the infrastructure project is improved. Moreover, the effect of data visualization is achieved by generating the platform cockpit, and the effect of displaying the project distribution condition, the project safety condition, the project progress condition and the project quality condition of the infrastructure project according to different user roles is achieved by configuring the account number authority and the region authority of the login account number of the platform cockpit, so that the management and control efficiency of the infrastructure project is further improved.

Drawings

FIG. 1 is an application environment diagram of a method for infrastructure engineering management and control in one embodiment;

FIG. 2 is a flow diagram illustrating a method for managing and controlling infrastructure construction in one embodiment;

FIG. 3 is a flow chart illustrating a data analysis step performed by the policing unit according to an embodiment;

FIG. 4 is a block diagram of a infrastructure management and control system in one embodiment;

FIG. 5 is a block diagram of a infrastructure management and control apparatus in one embodiment;

FIG. 6 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The infrastructure engineering management and control method provided by the embodiment of the application can be applied to the application environment shown in fig. 1. Wherein the terminal 102 communicates with the server 104 via a network. The data storage system may store data that the server 104 needs to process. The data storage system may be integrated on the server 104, or may be located on the cloud or other network server. The terminal 102 may independently execute the infrastructure project management and control method provided by the embodiment of the present application, and the terminal 102 and the server 104 may also cooperatively execute the infrastructure project management and control method provided by the embodiment of the present application.

When the terminal 102 independently executes the infrastructure project management and control method, the terminal 102 collects basic data and service data, wherein the basic data comprises construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the service data comprises progress planning data and construction actual progress data; determining a plurality of control units, wherein the control units at least comprise a safety control unit, a progress control unit and a quality control unit; analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result; determining corresponding early warning information based on the analysis result; and generating a platform cockpit of the capital construction project based on the basic data, the service data and the analysis result, and displaying the early warning information in the platform cockpit according to the account number authority and the region authority corresponding to the current login account number.

When the terminal 102 and the server 104 cooperatively execute the infrastructure project management and control method, the terminal 102 collects basic data and service data, the basic data includes construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, the service data includes progress planning data and construction actual progress data, and the basic data and the service data are sent to the server 104. The server 104 determines a plurality of control units, wherein the control units at least comprise a safety control unit, a progress control unit and a quality control unit; analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result; determining corresponding early warning information based on the analysis result; and generating a platform cockpit of the capital construction project based on the basic data, the service data and the analysis result, and displaying the early warning information in the platform cockpit according to the account number authority and the region authority corresponding to the current login account number.

The terminal 102 may be, but not limited to, various personal computers, notebook computers, smart phones, tablet computers, internet of things devices and portable wearable devices, and the internet of things devices may be smart speakers, smart televisions, smart air conditioners, smart car-mounted devices, and the like. The portable wearable device can be a smart watch, a smart bracelet, a head-mounted device, and the like. The server 104 may be implemented as a stand-alone server or as a server cluster comprised of multiple servers.

In one embodiment, as shown in fig. 2, a method for infrastructure engineering management and control is provided, where the method may be executed by a terminal or a server alone, or may be executed by a terminal and a server in cooperation. The embodiment of the present application is described by taking as an example that the method is applied to a terminal (the terminal may also be referred to as an engineering management and control platform) in fig. 1, and includes the following steps:

step 202, basic data and business data are collected, wherein the basic data comprise construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the business data comprise progress planning data and construction actual progress data.

The basic data are audio and video, attendance identification, safety monitoring, positioning and environment perception data of a project construction site acquired by various field device terminals (such as an unmanned aerial vehicle, a camera, an attendance machine, a shield machine and a weather all-in-one machine), and are collected in a unified mode through technologies such as a cloud platform, an Internet of things platform and big data.

The construction site picture is a picture of a construction site of a capital construction project, the content of the picture can comprise a construction site, personnel, equipment, vehicles, materials, sky and the like, and the construction site picture also comprises information such as project names, picture description, shooting time and the like.

The object position data is position information of the personnel on the construction site, and comprises in-place time, in-place personnel, in-place risk point positions, risk point types, risk grades and the like.

The equipment monitoring data is obtained by monitoring points of special operation for professional equipment and can comprise deep foundation pit monitoring data, high formwork monitoring data, shield tunneling machine monitoring data, scaffold monitoring data, pipe jacking operation monitoring data, elevator monitoring data and the like. Before monitoring a monitoring point of a special operation by professional equipment, professional equipment account information needs to be combined, the professional equipment and a terminal are bound, so that the terminal can obtain equipment monitoring data monitored by the bound professional equipment, and the professional equipment account information comprises an equipment ID, an equipment name, an equipment manufacturer and an equipment model.

The vehicle monitoring data is vehicle access information including a license plate number, a time when the vehicle enters a project construction site, a time when the vehicle leaves the project construction site, a vehicle access number, a vehicle positioning track and the like.

The material monitoring data is material supply information, including warehouse name of material storage, material code, material arrival amount, actual arrival time of material and the like.

The environmental monitoring data is the environmental information of project construction site, including weather monitoring data, dust monitoring data, building site water use monitoring data, building site electricity consumption monitoring data etc..

The business data is data related to construction progress of a project construction site, including progress plan data and actual progress data of construction. The schedule data is compiled by related construction parties and comprises project names, project codes, node names, node details, schedule starting time, schedule ending time and the like. The nodes are tasks in the infrastructure project, and project progress can be reflected through task completion progress. The actual construction progress data is obtained by reporting by a construction party according to the completion condition of the construction progress.

Specifically, a terminal collects basic data and business data of a project construction site, wherein the basic data comprises construction site pictures, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data; the business data comprises progress plan data and construction actual progress data.

Step 204, determining a plurality of control units, wherein the control units at least comprise a safety control unit, a progress control unit and a quality control unit.

The management and control unit is a functional module integrating a plurality of service modules, wherein the management and control unit is used for combing the work flow of the infrastructure project management and control system from the dimensions of safety, progress, quality and the like of the infrastructure project.

The safety control unit is used for controlling the capital construction project from the safety dimension and comprises a safety management subunit, a professional equipment monitoring subunit and a video monitoring subunit.

And the safety management subunit is used for managing the risk points and managing the post and job-carrying conditions of the personnel at the risk points. The risk points are operation behaviors that potential safety hazards exist in the workflow of the capital construction project and safety measures need to be taken for management and control, for example, one risk point of a construction site is an earth and rockfill, and the consequence of the risk corresponding to the risk point possibly caused by collapse is collapse, so that the risk point needs to be managed and controlled, and the corresponding safety measures can be the work of strictly constructing according to the standard requirement, well performing slope protection drainage and the like. As a basis of security control, the risk points are usually issued in the form of a risk point list, and when abnormal information is monitored, security check can be performed according to the risk point list.

The professional equipment monitoring subunit is used for managing and controlling special operations from the safety dimension, and the special operations comprise deep foundation pit operations, high formwork supporting operations, shield machine operations, scaffold operation, pipe jacking operations, elevator operations and the like.

The video monitoring subunit is used for managing and controlling personnel and vehicles on the construction site from the safety dimension, and comprises the steps of respectively managing and controlling vehicle access, personnel safety wearing behaviors and the like.

The progress control unit is used for controlling the infrastructure project from the progress dimension, and comprises a progress plan and an actual progress which are respectively controlled.

The quality management and control unit is used for managing and controlling capital construction projects according to quality dimensions, and comprises the steps of respectively managing and controlling weather, dust, construction site water consumption, construction site electricity consumption and the like.

Specifically, the terminal determines that the infrastructure project management and control system at least comprises a safety management and control unit, a progress management and control unit and a quality management and control unit based on the safety, progress and quality dimensions of the infrastructure project.

And step 206, analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result.

Specifically, the terminal analyzes the basic data based on the safety control unit to obtain a safety analysis result; analyzing the basic data and the service data based on the progress control unit to obtain a progress analysis result; and analyzing the basic data based on the quality control unit to obtain a quality analysis result.

And step 208, determining corresponding early warning information based on the analysis result.

The analysis result comprises normal and abnormal situations. For example, when the result of the object going to post shows that the post status of the risk point is not post, the result of the object going to post is abnormal; when the video monitoring subunit does not recognize the license plate number of the vehicle or monitors that the visitor vehicle is not reported in advance, the vehicle access monitoring result is abnormal.

And when the analysis result is in an abnormal condition, the early warning information is information which corresponds to the analysis result in the abnormal condition and is used for early warning and reminding. The warning information may be in different forms, for example, the warning information may be that a red light, a green light, or a yellow light is turned on, or may be a pop-up dialog box in which characters representing the warning meaning are displayed, or may be a pop-up image in which information representing that the result is abnormal is displayed. The early warning information comprises safety control early warning information, progress control early warning information and quality control early warning information.

Specifically, the terminal determines corresponding safety control early warning information based on a safety analysis result; determining corresponding progress control early warning information based on the progress analysis result; and determining corresponding quality control early warning information based on the quality analysis result.

And 210, generating a platform cockpit of the infrastructure project based on the basic data, the service data and the analysis result, and displaying early warning information in the platform cockpit according to the account authority and the region authority corresponding to the current login account.

The platform cockpit is a management information center system obtained according to input data (namely basic data and service data) and output data (namely analysis results) of the plurality of control units, and is used for displaying project maps, engineering overview and progress, field work and material machine display, field video monitoring, field environment monitoring and abnormal alarm display through a user interface of the platform cockpit.

The project map display is integrated with a power grid resource center, and based on a GIS (Geographic Information Science, abbreviation of Geographic Information Science), the capital construction project Information is displayed on the GIS map. The project overview and progress display is linked with the project map, and displays selected capital construction project information in a list form, wherein the selected capital construction project information comprises project names, located areas, project responsible persons, start time, end time and the like; and clicking on the project name may drill down the relevant project details. The on-site work material machine display is linked with the project map, and displays the conditions of the selected capital construction project on-site working personnel, the vehicle in-out conditions, the on-site material placement conditions and the like. The field video monitoring is linked with a project map, and displays the field video of the selected capital construction project, including construction field video, key monitoring area conditions, personnel access conditions, vehicle access conditions, personnel safety wearing, identification and monitoring and the like. The site environment monitoring is linked with an engineering map, is in butt joint with an Internet of things platform, and shows weather monitoring data, dust monitoring data, construction site water monitoring data and construction site electricity utilization monitoring data of a selected capital construction project construction site. The abnormal alarm display is characterized in that project construction sites, counties, cities, provinces and network levels are used as dimensions, illegal alarms of different types and different regions and abnormal alarms of professional equipment are inquired, high-risk projects or regions are statistically displayed, and a report basis is provided.

The current login account is the current account of the landing cockpit, the account authority is the data access authority determined according to the user type, the user type comprises users with general level authority, users with high level authority and users with administrator level authority, and the range of data access of the users with different levels of account authority is different. The region authority is a data access authority determined according to the region administration authority level of the work unit where the user is located, and the range in which the users with the region authority of different levels can access data is different.

Specifically, the terminal generates a platform cockpit of the infrastructure project based on the GIS map, the basic data, the service data and the analysis result, and displays the basic data, the service data, the analysis result and the early warning information in the platform cockpit according to the account number authority and the region authority corresponding to the current login account number of the platform cockpit.

According to the infrastructure project management and control method, the basic data and the service data are collected, the management and control units are determined from multiple dimensions such as safety, progress and quality, the basic data and the service data are analyzed through the management and control units to obtain the analysis result, the corresponding early warning information is determined based on the analysis result, the early warning information is displayed in the platform cockpit by generating the platform cockpit of the infrastructure project to early warn abnormal conditions, the purpose of forming data linkage aiming at different dimensions of the project is achieved, the work flow is full-automatic, data summarization and data analysis are carried out in a manual mode, and therefore management and control efficiency of the infrastructure project is improved. Moreover, the effect of data visualization is achieved by generating the platform cockpit, and the effect of displaying the project distribution condition, the project safety condition, the project progress condition and the project quality condition of the infrastructure project according to different user roles is achieved by configuring the account number authority and the region authority of the login account number of the platform cockpit, so that the management and control efficiency of the infrastructure project is further improved.

In one embodiment, the infrastructure engineering management and control method further includes: determining each object account, and configuring the account authority of each object account based on the corresponding department and post of each object account, wherein the object accounts comprise accounts belonging to a construction party and accounts belonging to a participating party; for the account numbers belonging to the construction party, the region authority of each account number belonging to the construction party is configured to belong to a network level, a provincial level, a prefecture level or a district and county level based on the geographic position of the project construction site and the region jurisdiction authority corresponding to the account number belonging to the construction party.

The target account is an account for logging in a cockpit of the platform, the target comprises a constructor and a participant, and correspondingly, the target account comprises an account belonging to the constructor and an account belonging to the participant. The construction party is divided into construction parties with different levels of regional authorities according to the network level, the provincial level, the prefecture level and the prefecture level, and the participating construction parties comprise a construction party, a supervision party and a design party. The account number authority comprises project data, personnel data, terminal equipment data, project maps, start-up review submission, construction progress submission, alarm information processing, defect problem correction scheme execution, alarm information processing and the like.

The different departments refer to the departments to which the object belongs, the departments comprise a main manager, a capital construction department, a safety supervision department and the like, and the different posts refer to the positions of the object in the departments to which the object belongs, and comprise a main manager, a subsidiary main manager, a main master, a subsidiary main master, a supervisor, a main supervisor, a project manager, a construction team leader, a constructor and the like. For example, the construction party comprises departments such as a management part and a construction project part, wherein the management part comprises stations such as a subordination and above, and the corresponding account number authority is as follows: checking engineering data, personnel data, terminal equipment data, project maps and processing alarm information; the construction project department comprises a project manager, and the corresponding account number authority is as follows: checking engineering data, submitting a work-starting review, submitting construction progress, processing alarm information and executing a defect problem rectification scheme; the account number authority corresponding to the construction team leader is as follows: checking engineering data and processing alarm information; the constructor, its corresponding account number authority is: and checking the engineering data.

The region jurisdiction authority corresponding to the account belonging to the construction party refers to the region jurisdiction authority corresponding to the administrative region level, which is possessed by the construction party and comprises a network level (nationwide), a provincial level, a prefecture level and a district and county level. For example, when the construction party is a company headquarter, the construction party has a jurisdiction national project authority, and a region jurisdiction authority corresponding to an account belonging to the construction party is a network level; when the constructor is a type A company belonging to the headquarters of the company, the constructor has the jurisdiction provincial project authority, and the region jurisdiction authority corresponding to the account number belonging to the constructor is provincial; when the builder is a first-level branch company subordinate to the type A company, the builder has a jurisdiction local and city level project authority, and a region jurisdiction authority corresponding to an account number belonging to the builder is a local and city level; when the construction party is a secondary branch company subordinate to the primary branch company, the construction party has a jurisdiction and county level project authority, and the region jurisdiction authority corresponding to the account number belonging to the construction party is at the district and county level.

When the regional authority of the account belonging to the construction party belongs to a network level, the platform cockpit displays a project map in the whole network (national) range, and the project map can be drilled to a lower provincial level, a local city level and a prefecture level until a project construction site; when the regional authority of the account belonging to the construction party belongs to provincial level, the platform cockpit displays a project map of the provincial scope, and the project map can be drilled to the lower local city level and the district level until the project construction site; when the regional authority of the account belonging to the construction party belongs to the local city level, the platform cockpit displays a project map of a local city range, and the project map can be drilled from the lower layer region county level to a project construction site; when the regional authority of the account number belonging to the construction party belongs to the district level, the platform cockpit displays the project map of the district level, and the project map can be drilled into a lower-layer project construction site.

Specifically, the terminal determines that each object account of a landing platform cockpit is an account belonging to a construction party or an account belonging to a participating party, and configures account permission of each object account based on a department and a post to which an object corresponding to each object account belongs; for the account belonging to the construction party, determining provinces, cities and counties where the construction site of the project is located based on the geographical position of the construction site of the project; for a constructor with a jurisdiction national project authority, configuring the region authority of each account belonging to the constructor as belonging to a network level; for a constructor with jurisdiction provincial project authority, configuring the region authority of each account belonging to the constructor as belonging to provincial; for a constructor with a jurisdiction local city level project authority, configuring the regional authority of each account belonging to the constructor as belonging to the local city level; and for the construction party with the jurisdiction and county level project authority, configuring the region authority of each account belonging to the construction party as belonging to the county level.

In the embodiment, the account number authority and the region authority of each object account number of the platform cockpit are configured from two dimensions of user role and region administration authority by determining that each object account number of the login platform cockpit is an account number belonging to a construction party or an account number belonging to a participating party, so that the purpose of configuring the data access authority of the object account number for the platform cockpit according to different user roles and region administration authorities can be achieved, the platform cockpit can display project distribution conditions, project safety conditions, project progress conditions and project quality conditions of the capital construction project by using net level, provincial level, prefecture level, district level and county level and project construction site as dimensions, and the effect of further improving the management and control efficiency of the capital construction project is achieved.

In one embodiment, as shown in fig. 3, the progress plan data includes construction progress plan data and material progress plan data, the safety analysis result includes an object on duty result, an equipment safety monitoring result and a vehicle in-and-out monitoring result, the progress analysis result includes a construction progress analysis result and a material progress analysis result, and the quality analysis result includes a weather monitoring result, a dust monitoring result, a construction site water usage monitoring result and a construction site electricity usage monitoring result; based on a plurality of management and control units, basic data and service data are analyzed to obtain an analysis result, and the method comprises the following steps:

step 302, analyzing the construction site photos and the object position data according to the risk point distribution condition through a safety control unit to obtain the job-on-duty result of the object; analyzing the equipment monitoring data according to the equipment monitoring parameter template to obtain an equipment safety monitoring result; and analyzing the vehicle monitoring data according to the vehicle record information to obtain a vehicle access monitoring result.

The risk point distribution condition includes risk point types, risk point quantity, inherent risk levels, possible risk consequences, pre-control measures, operation positions, operation contents, geographic positions and the like which are obtained through statistics according to engineering types. The object post arrival and position information result comprises the position information of the risk points and the position information of the risk points. The performing state of the risk points is no performing or performed, and the performing state of the risk points is performed by a person assigned to a job performing staff within the assigned time; the person who arrives at the post for performing does not designate the person who arrives at the post for performing or designates the person who arrives at the post for performing does not arrive at the post at the designated time, and the performing states of the risk points are all non-performing. The risk point arrival rate is the ratio of the number of persons who have performed the job to the number of persons who need to perform the job.

The equipment monitoring parameter template is designed for professional equipment such as a shield machine and the like and is used for configuring various equipment monitoring parameters, and the equipment monitoring parameters can comprise deep foundation pit monitoring parameters, high formwork supporting monitoring parameters, shield machine monitoring parameters, scaffold monitoring parameters, pipe jacking operation monitoring parameters and elevator monitoring parameters. The equipment safety monitoring result is a parameter value corresponding to the equipment monitoring parameter of each monitoring point monitored by the professional equipment and equipment monitoring parameter value statistical information, and the equipment monitoring parameter value statistical information can comprise daily variation, accumulated variation, the number of the monitoring points and the like of the parameter value corresponding to the equipment monitoring parameter. The equipment safety monitoring result can comprise a deep foundation pit safety monitoring result, a high formwork safety monitoring result, a shield machine safety monitoring result, a scaffold safety monitoring result, a pipe jacking operation safety monitoring result and a lifter safety monitoring result.

The vehicle record information includes a license plate number, a vehicle owner, a vehicle type, a vehicle brand, and the like. The vehicle access monitoring result is information obtained by counting vehicle access information according to the record vehicle and the visitor vehicle.

Specifically, the terminal obtains post job-to-post job conditions of risk point objects of each risk point through a safety management subunit of the safety management and control unit based on risk point distribution conditions, construction site pictures and object position data, wherein the post job-to-post job conditions of the risk point objects at least comprise job performing states, in-place time, in-place personnel, in-place risk point positions, in-place risk point types and risk levels of the risk points; and calculating the arrival rate of the risk points of each risk point based on the arrival job and the job-carrying condition of the risk point object of each risk point.

The terminal configures the equipment monitoring parameters according to the equipment monitoring parameter template through a professional equipment monitoring subunit of the safety control unit, and acquires the equipment monitoring data of each monitoring point for each monitoring point; obtaining a parameter value corresponding to the equipment monitoring parameter of each monitoring point based on the equipment monitoring parameter and the equipment monitoring data of each monitoring point; and counting the parameter values corresponding to the equipment monitoring parameters to obtain the equipment monitoring parameter value statistical information of each monitoring point.

The terminal acquires the license plate number in the vehicle monitoring data through a video monitoring subunit of the safety control unit, matches the license plate number with the vehicle recording information, judges whether the license plate number is contained in the vehicle recording information, determines the vehicle with the license plate number in the vehicle recording information as a recorded vehicle, and determines the vehicle without the license plate number or with the license plate number outside the vehicle recording information as a visitor vehicle; and counting the vehicle monitoring data of the recorded vehicles and the visitor vehicles to obtain vehicle access monitoring results.

Step 304, comparing the construction progress planning data with the construction actual progress data through a progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a construction progress analysis result; and comparing the material progress planning data with the material monitoring data to obtain a material progress analysis result.

The construction progress plan data is a plan about construction progress of the infrastructure project, and the actual construction progress data is the actual project progress of a construction site. The construction progress analysis result comprises the number of days of advance of the project progress, the number of days of normal project progress or the number of days of delay of the project progress. The material progress plan data is a material supply progress plan, namely, a plan for purchasing various materials required by the capital construction project from the market, and the plan can comprise material suppliers, material purchase amount, material plan arrival time and the like. The material progress analysis result comprises normal or delayed material supply progress, satisfaction degree of material supply quantity and satisfaction degree of material arrival time.

Specifically, the terminal compares construction progress planning data with construction actual progress data through a progress control unit, judges whether the engineering progress is advanced, normal or delayed, and obtains a construction progress analysis result; and comparing the material progress planning data with the material monitoring data, and judging whether the material supply quantity and the material arrival time meet the requirements of a construction site or not to obtain a material progress analysis result.

And step 306, analyzing the environmental monitoring data through the quality control unit to obtain a quality analysis result.

The weather monitoring result is suitable for outdoor operation of personnel, suitable for indoor operation of personnel or unsuitable for operation of personnel, for example, when the weather monitoring result is typhoon, the weather monitoring result is unsuitable for operation of personnel. The dust monitoring result is qualified or unqualified, for example, when the dust pollution index corresponding to the dust monitoring data exceeds the limit, the dust monitoring result is unqualified. The site water monitoring result is information obtained by counting the site water condition, such as the water consumption in a specific time period. The monitoring result of the electricity consumption of the construction site is information obtained by counting the electricity consumption conditions of the construction site, such as the electricity consumption in a specific time period.

Specifically, the terminal monitors the weather of a construction site through a quality control unit according to weather monitoring data to obtain a weather monitoring result; monitoring dust pollution indexes such as PM 2.5 and the like of a construction site according to dust monitoring data to obtain a dust monitoring result; performing statistical analysis on the construction site water consumption condition according to the construction site water consumption monitoring data to obtain a construction site water consumption monitoring result; and carrying out statistical analysis on the power utilization condition of the construction site according to the power utilization monitoring data of the construction site to obtain a power utilization monitoring result of the construction site.

In this embodiment, through combining the risk point distribution, equipment monitoring parameter template and vehicle record information, to the job site photo, object position data, equipment monitoring data and vehicle detection data carry out the analysis, obtain respectively including object to post and job function result, the safety analysis result of equipment safety monitoring result and vehicle discrepancy monitoring result, the progress analysis result including construction progress analysis result and material progress analysis result, and including weather monitoring result, dust monitoring result, the quality analysis result of building site water monitoring result and building site electricity consumption testing result, can reach from safety, the mesh of managing and controlling is carried out to the capital construction to multidimension such as progress and quality.

In one embodiment, the construction progress plan data includes a first-level progress plan, a second-level progress plan and a third-level progress plan, the second-level progress plan is obtained by performing refinement and division on nodes of the first-level progress plan, the third-level progress plan is obtained by performing refinement and division on nodes of the second-level progress plan, and the construction progress analysis result includes a first-level construction progress analysis result, a second-level construction progress analysis result and a third-level construction progress analysis result. Through progress management and control unit, compare construction progress plan data and construction actual progress data, judge that the engineering progress is in advance, normal or lags behind, obtain construction progress analysis result, include: comparing the primary progress plan with the actual construction progress data through a progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a primary construction progress analysis result; comparing the second-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a second-level construction progress analysis result; and comparing the three-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a three-level construction progress analysis result.

The primary progress plan is an overall progress plan of the infrastructure project, and the service range covered by the primary progress plan is the largest; the secondary progress plan is a subordinate plan obtained by thinning and dividing the nodes of the primary progress plan, the covered service range is inferior to that of the primary progress plan, and the task node time of the secondary progress plan cannot exceed the task node time of the corresponding primary progress plan; the third-level schedule is a subordinate schedule obtained by refining and dividing nodes of the second-level schedule, the covered service range is minimum, and the task node time of the third-level schedule cannot exceed the task node time of the corresponding second-level schedule. The first-level construction progress analysis result, the second-level construction progress analysis result and the third-level construction progress analysis result are construction progress analysis results respectively corresponding to the first-level progress plan, the second-level progress plan and the third-level progress plan.

Specifically, the terminal compares the first-level progress plan with actual construction progress data through a progress control unit, judges whether the engineering progress is advanced, normal or delayed, and obtains a first-level construction progress analysis result; comparing the second-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a second-level construction progress analysis result; and comparing the three-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a three-level construction progress analysis result.

In the embodiment, the nodes of the first-level progress plan are firstly refined, the second-level progress plan with a master-slave relation is divided, the analogy is repeated, the third-level progress plan is obtained, then the construction progress analysis is carried out according to the business ranges corresponding to the first-level progress plan, the second-level progress plan and the third-level progress plan, a more detailed construction progress analysis result can be obtained, and the purpose of improving the infrastructure construction management and control efficiency is achieved.

In one embodiment, the construction progress plan data further includes a key path progress plan, the construction progress analysis result further includes a key path progress analysis result, the construction progress plan data and the construction actual progress data are compared through the progress control unit, the project progress is judged to be in advance, normal or delayed, and the construction progress analysis result is obtained, further including: extracting key nodes from the nodes of the three-level progress plan through a key node library to obtain a key path; the key path supports the operations of adding, modifying and deleting; and comparing the key path progress plan with the actual construction progress data, and judging whether the project progress is advanced, normal or delayed to obtain a key path progress analysis result.

The critical path progress plan is a construction progress plan comprising a critical path, and the critical path progress analysis result is a construction progress analysis result corresponding to the critical path progress plan. The critical path comprises a plurality of critical nodes, and the critical nodes are critical tasks in the infrastructure project. The key node library is a pre-established database for storing key node information.

Specifically, the terminal determines key nodes from the nodes of the three-level progress plan through the assistance of a key node library, and determines a key path based on the key nodes, wherein the key path supports the operations of adding, modifying and deleting the key nodes; and determining a key path progress plan based on the three-level progress plan, comparing the key path progress plan with the actual construction progress data, and judging whether the project progress is advanced, normal or delayed to obtain a key path progress analysis result.

In the embodiment, the key paths containing the key nodes are determined from the nodes of the three-level progress plan through the assistance of the key node library, the construction progress is analyzed based on the key path progress plan, the key path progress analysis result is obtained, the purpose of performing the construction progress analysis on the key tasks in the infrastructure construction project can be achieved, and the purpose of improving the infrastructure construction management and control efficiency is further achieved.

In one embodiment, the actual construction progress data is obtained by reporting by the construction party according to the completion condition of the construction progress, and the infrastructure construction management and control method further includes: inquiring the construction site photo according to at least one of the target mark segment and the target process to obtain a target construction site photo, and inquiring the actual construction progress data to obtain the actual construction progress data of the target; interpreting the target construction site picture, and extracting the engineering construction progress to obtain an interpretation result; and comparing the interpretation result with the actual progress data of the target construction, and verifying the accuracy of the actual progress data of the target construction.

The target mark section is a mark section of a basic construction project of the actual progress to be verified, and the target process is a process of the basic construction project of the actual progress to be verified. The target construction site photo is a construction site photo corresponding to at least one of the target mark segment and the target process. The target construction actual progress data is construction actual progress data corresponding to at least one of the target mark section and the target process. The interpretation result is a construction progress analysis result obtained by carrying out photo interpretation on the target construction site photo, and the construction progress analysis result comprises an advance, a normal or a delay of the engineering progress. Photo interpretation is a commonly used method for extracting image information.

Specifically, the terminal determines at least one of a target mark segment and a target process; determining a target construction site photo from the construction site photos according to at least one of the target mark segment and the target process, and determining target construction actual progress data from the construction actual progress data; photo interpretation is carried out on the photo of the target construction site, construction progress information is extracted, and an interpretation result is obtained based on the construction progress information; and comparing the interpretation result with the actual progress data of the target construction, and verifying the accuracy of the actual progress data of the target construction.

In the embodiment, the photo interpretation is carried out on the photo of the construction site to obtain the interpretation result, the construction actual progress data is rechecked according to the interpretation result, the purpose of actual progress verification can be achieved, and the purpose of improving the management and control efficiency of the infrastructure construction project is further achieved.

In one embodiment, as shown in fig. 4, a infrastructure project management and control system is provided, which includes a project management and control unit, a personnel management and control unit, a basic function unit and a mobile APP in addition to a safety management and control unit, a progress management and control unit, a quality management and control unit and a platform cockpit. The infrastructure engineering management and control system, an interactive system, a cloud platform, an internet of things platform and big data which are in butt joint with the infrastructure engineering management and control system form an intelligent engineering management and control platform.

The project management and control unit is used for managing and controlling the infrastructure projects from project dimensions, and comprises the steps of summarizing project information of the infrastructure projects of the whole network, establishing project accounts, managing the project accounts, and inquiring the project information, counting the project information and the like.

The personnel management and control unit is used for managing and controlling the infrastructure construction from personnel dimensionality, and comprises personnel ledger management, personnel information inquiry, face recognition inquiry and the like.

The basic function module comprises authorization management, authority management, configuration management, attendance information inquiry, personal setting, my information, system announcement and the like. The authorization management is a function for providing the system personnel to issue the self authority. The authority management is to add personnel roles, extend personnel attribute definition and maintain basic information. Configuration management is the function of providing business rules and data dictionary configuration management for the system. The attendance information inquiry is to inquire attendance data of the person and subordinate persons by connecting a real-name system.

The infrastructure construction management and control system is used for management and control and can comprise the following steps:

(1) the method comprises the steps of collecting audio and video, attendance identification, safety monitoring, positioning and environment sensing data of an engineering field through various field device terminals (such as audio and video monitoring equipment, face identification equipment, fingerprint scanning equipment, infrared monitoring equipment and the like), and uniformly summarizing through technologies such as a cloud platform, an Internet of things platform and big data.

(2) Based on the acquired basic data, the business process is comprehensively combed from multiple dimensions such as safety, progress, design, quality, project and personnel, the business data such as progress plan management process, progress statistics process and the like are integrated, and a plurality of management and control units with unified data, standard process and strong business pertinence are formed and comprise a safety management and control unit, a progress management and control unit, a quality management and control unit, a project management and control unit, a personnel management and control unit and the like. And different account number authorities are set based on different departments and different posts, for example, the quality control unit can only be used by quality control personnel, and a project manager can only manage the project to which the manager belongs.

(3) Monitoring and early warning technologies such as face recognition, behavior monitoring and foreign matter monitoring are adopted to monitor the contents of personnel, equipment, environment, vehicles, materials and the like in engineering construction in real time.

(4) The method is characterized in that dynamic management and control and scientific decision are taken as targets, a real-time, dynamic and intelligent platform cockpit is constructed on the basis of basic data collection, monitoring and early warning, the platform cockpit is a capital construction panoramic visual display platform and is used for full-caliber intelligent engineering display within the authority range of automatic positioning according to the functions of roles of network, province, city and county, and multiple data analysis display and monitoring and early warning are provided.

(5) The system comprises an artificial intelligence platform, a 4A platform, a power grid resource center, a hardware equipment manufacturer system, a short message platform and the like, and is integrated comprehensively to realize single sign-on, unified management and unified scheduling of the system.

(6) The mobile APP based on the mobile phone end is built, a convenient channel for data acquisition and real-time communication is provided for construction site personnel, and the mobile APP can provide practical functions such as basic service, project overview, examination and approval management, card printing attendance and field shooting. The mobile APP is an effective supplement to the PC desktop version management system, the blank of construction site management is filled, and by adopting a mode of combining site and background, the real-time performance of data acquisition is guaranteed, and a foundation is provided for remote command and scheduling.

According to the method, the artificial intelligence and the infrastructure construction project are deeply integrated, the project safety control, the progress control, the quality control, the project control and the personnel control are covered, the project data and the early warning information within the authority range of the display of the roles of province, city and county according to the network are provided, and the control efficiency of the infrastructure construction project is effectively improved.

It should be understood that, although the steps in the flowcharts related to the embodiments as described above are sequentially displayed as indicated by arrows, the steps are not necessarily performed sequentially as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least a part of the steps in the flowcharts related to the embodiments described above may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, and the execution order of the steps or stages is not necessarily sequential, but may be rotated or alternated with other steps or at least a part of the steps or stages in other steps.

Based on the same inventive concept, the embodiment of the application also provides a infrastructure construction management and control device for realizing the infrastructure construction management and control method. The implementation scheme for solving the problem provided by the device is similar to the implementation scheme described in the method, so that specific limitations in one or more embodiments of the infrastructure construction management and control device provided below may refer to the limitations on the infrastructure construction management and control method in the foregoing, and details are not described here.

In one embodiment, as shown in fig. 5, there is provided a infrastructure management and control apparatus 500, including: an acquisition module 502, an analysis module 504, and an early warning module 506, wherein:

the acquisition module 502 is used for acquiring basic data and service data, wherein the basic data comprises construction site photos, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the service data comprises progress planning data and construction actual progress data.

The analysis module 504 is configured to determine a plurality of management units, where the plurality of management units at least includes a security management unit, a progress management unit, and a quality management unit.

The analysis module 504 is further configured to analyze the basic data and the service data based on the plurality of control units to obtain an analysis result, where the analysis result at least includes one of a security analysis result, a progress analysis result, and a quality analysis result.

The analysis module 504 is further configured to determine corresponding warning information based on the analysis result.

And the early warning module 506 is configured to generate a platform cockpit of the infrastructure project based on the basic data, the service data and the analysis result, and display early warning information in the platform cockpit according to the account authority and the region authority corresponding to the current login account.

In one embodiment, the infrastructure construction management and control apparatus 500 further includes a permission module, where the permission module is configured to determine each object account, and configure an account permission of each object account based on a department and a position corresponding to each object account, where the object accounts include an account belonging to a construction party and an account belonging to a participating party; for the account numbers belonging to the construction party, the region authority of each account number belonging to the construction party is configured to belong to a network level, a provincial level, a prefecture level or a district and county level based on the geographic position of the project construction site and the region jurisdiction authority corresponding to the account number belonging to the construction party.

In one embodiment, the progress plan data comprises construction progress plan data and material progress plan data, the safety analysis result comprises an object post-arrival and post-progress result, an equipment safety monitoring result and a vehicle in-and-out monitoring result, the progress analysis result comprises a construction progress analysis result and a material progress analysis result, and the quality analysis result comprises a weather monitoring result, a dust monitoring result, a construction site water consumption monitoring result and a construction site electricity consumption monitoring result; the analysis module 504 is further configured to analyze the construction site photos and the object position data according to the risk point distribution conditions through the safety control unit, so as to obtain the job-on-duty result of the object; analyzing the equipment monitoring data according to the equipment monitoring parameter template to obtain an equipment safety monitoring result; analyzing the vehicle monitoring data according to the vehicle record information to obtain a vehicle access monitoring result; comparing the construction progress planning data with the construction actual progress data through a progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a construction progress analysis result; comparing the material progress planning data with the material monitoring data to obtain a material progress analysis result; and analyzing the environment monitoring data through the quality control unit to obtain a quality analysis result.

In one embodiment, the construction progress plan data includes a first-level progress plan, a second-level progress plan and a third-level progress plan, the second-level progress plan is obtained by performing detailed division on nodes of the first-level progress plan, the third-level progress plan is obtained by performing detailed division on nodes of the second-level progress plan, and the construction progress analysis result includes a first-level construction progress analysis result, a second-level construction progress analysis result and a third-level construction progress analysis result; the analysis module 504 is further configured to compare the first-level progress plan with the actual construction progress data through the progress control unit, and determine whether the engineering progress is advanced, normal, or delayed to obtain a first-level construction progress analysis result; comparing the second-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a second-level construction progress analysis result; and comparing the three-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a three-level construction progress analysis result.

In one embodiment, the construction progress plan data further includes a key path progress plan, the construction progress analysis result further includes a key path progress analysis result, and the analysis module 504 is further configured to extract a key node from nodes of the third-level progress plan through a key node library to obtain a key path; the key path supports the operations of adding, modifying and deleting; and comparing the key path progress plan with the actual construction progress data, and judging whether the project progress is advanced, normal or delayed to obtain a key path progress analysis result.

In one embodiment, the actual construction progress data is obtained by reporting by a constructor according to the completion condition of the construction progress, and the infrastructure management and control device 500 further includes a verification module, which is configured to query a construction site photo according to at least one of a target segment and a target process to obtain a target construction site photo, and query the actual construction progress data to obtain the actual construction progress data of the target; interpreting the target construction site picture, and extracting the engineering construction progress to obtain an interpretation result; and comparing the interpretation result with the actual progress data of the target construction, and verifying the accuracy of the actual progress data of the target construction.

All or part of each module in the infrastructure engineering management and control device can be realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a terminal, and its internal structure diagram may be as shown in fig. 6. The computer apparatus includes a processor, a memory, an input/output interface, a communication interface, a display unit, and an input device. The processor, the memory and the input/output interface are connected by a system bus, and the communication interface, the display unit and the input device are connected by the input/output interface to the system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The input/output interface of the computer device is used for exchanging information between the processor and an external device. The communication interface of the computer device is used for carrying out wired or wireless communication with an external terminal, and the wireless communication can be realized through WIFI, a mobile cellular network, NFC (near field communication) or other technologies. The computer program is executed by a processor to realize a infrastructure engineering management and control method. The display unit of the computer equipment is used for forming a visual and visible picture, and can be a display screen, a projection device or a virtual reality imaging device, the display screen can be a liquid crystal display screen or an electronic ink display screen, the input device of the computer equipment can be a touch layer covered on the display screen, a key, a track ball or a touch pad arranged on the shell of the computer equipment, and can also be an external keyboard, a touch pad or a mouse and the like.

Those skilled in the art will appreciate that the architecture shown in fig. 6 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, a computer device is provided, comprising a memory and a processor, the memory having stored therein a computer program, the processor implementing the steps of the above-described method embodiments when executing the computer program.

In an embodiment, a computer-readable storage medium is provided, on which a computer program is stored, which computer program, when being executed by a processor, carries out the steps of the above-mentioned method embodiments.

In an embodiment, a computer program product is provided, comprising a computer program which, when being executed by a processor, carries out the steps of the above-mentioned method embodiments.

It should be noted that, the user information (including but not limited to user equipment information, user personal information, etc.) and data (including but not limited to data for analysis, stored data, displayed data, etc.) referred to in the present application are information and data authorized by the user or sufficiently authorized by each party, and the collection, use and processing of the related data need to comply with the relevant laws and regulations and standards of the relevant country and region.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, database, or other medium used in the embodiments provided herein may include at least one of non-volatile and volatile memory. The nonvolatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, high-density embedded nonvolatile Memory, resistive Random Access Memory (ReRAM), Magnetic Random Access Memory (MRAM), Ferroelectric Random Access Memory (FRAM), Phase Change Memory (PCM), graphene Memory, and the like. Volatile Memory can include Random Access Memory (RAM), external cache Memory, and the like. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others. The databases referred to in various embodiments provided herein may include at least one of relational and non-relational databases. The non-relational database may include, but is not limited to, a block chain based distributed database, and the like. The processors referred to in the embodiments provided herein may be general purpose processors, central processing units, graphics processors, digital signal processors, programmable logic devices, quantum computing based data processing logic devices, etc., without limitation.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present application shall be subject to the appended claims.

Claims

1. A infrastructure project management and control method is characterized by comprising the following steps:

analyzing the basic data and the business data based on a plurality of control units to obtain an analysis result, wherein the analysis result at least comprises one of a safety analysis result, a progress analysis result and a quality analysis result;

and generating a platform cockpit of the infrastructure project based on the basic data, the service data and the analysis result, and displaying the early warning information in the platform cockpit according to the account authority and the region authority corresponding to the current login account.

2. The method of claim 1, further comprising:

determining each object account, and configuring account authority of each object account based on a department and a post corresponding to each object account, wherein the object accounts comprise accounts belonging to a construction party and accounts belonging to a participating party;

for the accounts belonging to the construction party, the region authority of each account belonging to the construction party is configured to belong to a network level, a provincial level, a local city level or a prefecture level based on the geographic position of the project construction site and the region administration authority corresponding to the account belonging to the construction party.

3. The method of claim 2, wherein the schedule data comprises construction schedule data and material schedule data, the safety analysis results comprise object-to-post job-providing results, equipment safety monitoring results and vehicle in-and-out monitoring results, the schedule analysis results comprise construction schedule analysis results and material schedule analysis results, and the quality analysis results comprise weather monitoring results, dust monitoring results, site water monitoring results and site electricity monitoring results;

the analyzing the basic data and the service data based on the plurality of control units to obtain an analysis result, including:

analyzing the construction site photos and the object position data according to the risk point distribution condition through the safety control unit to obtain the post-arrival and job-carrying results of the objects; analyzing the equipment monitoring data according to an equipment monitoring parameter template to obtain an equipment safety monitoring result; analyzing the vehicle monitoring data according to vehicle record information to obtain a vehicle access monitoring result;

comparing the construction progress planning data with the construction actual progress data through the progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a construction progress analysis result; comparing the material progress planning data with the material monitoring data to obtain a material progress analysis result;

4. The method of claim 3, wherein the construction progress plan data includes a primary progress plan, a secondary progress plan and a tertiary progress plan, the secondary progress plan is obtained by performing detailed division on nodes of the primary progress plan, the tertiary progress plan is obtained by performing detailed division on nodes of the secondary progress plan, and the construction progress analysis result includes a primary construction progress analysis result, a secondary construction progress analysis result and a tertiary construction progress analysis result;

through the progress control unit, the construction progress plan data and the construction actual progress data are compared, and the project progress is judged to be in advance, normal or delayed, so that a construction progress analysis result is obtained, and the method comprises the following steps:

comparing the primary progress plan with the construction actual progress data through the progress control unit, and judging whether the engineering progress is advanced, normal or delayed to obtain a primary construction progress analysis result; comparing the second-level progress plan with the construction actual progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a second-level construction progress analysis result; and comparing the three-level progress plan with the actual construction progress data, and judging whether the engineering progress is advanced, normal or delayed to obtain a three-level construction progress analysis result.

5. The method according to claim 4, wherein the construction progress plan data further includes a key path progress plan, the construction progress analysis result further includes a key path progress analysis result, the comparing, by the progress control unit, the construction progress plan data and the construction actual progress data determines whether the construction progress is advanced, normal, or delayed, and the construction progress analysis result is obtained, further comprising:

extracting key nodes from the nodes of the three-level progress plan through a key node library to obtain a key path; the key path supports adding, modifying and deleting operations;

and comparing the key path progress plan with the actual construction progress data, and judging whether the project progress is advanced, normal or delayed to obtain a key path progress analysis result.

6. The method according to any one of claims 1 to 5, wherein the actual construction progress data is obtained by reporting by a construction party according to the completion condition of the construction progress, and the method further comprises:

inquiring the construction site photo according to at least one of the target mark segment and the target process to obtain a target construction site photo, and inquiring actual construction progress data to obtain actual construction progress data of the target;

interpreting the target construction site picture, and extracting the engineering construction progress to obtain an interpretation result;

and comparing the interpretation result with the target construction actual progress data, and verifying the accuracy of the target construction actual progress data.

7. The utility model provides a capital construction engineering management and control device which characterized in that, the device includes:

the system comprises an acquisition module, a data processing module and a data processing module, wherein the acquisition module is used for acquiring basic data and business data, the basic data comprises construction site photos, object position data, equipment monitoring data, vehicle monitoring data, material monitoring data and environment monitoring data, and the business data comprises progress planning data and construction actual progress data;

the analysis module is further configured to analyze the basic data and the service data based on a plurality of control units to obtain an analysis result, where the analysis result at least includes one of a security analysis result, a progress analysis result, and a quality analysis result;

the analysis module is further used for determining corresponding early warning information based on the analysis result;

and the early warning module is used for generating a platform cockpit of a infrastructure project based on the basic data, the service data and the analysis result, and displaying the early warning information in the platform cockpit according to the account number authority and the region authority corresponding to the current login account number.

8. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor, when executing the computer program, implements the steps of the method of any of claims 1 to 6.

9. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 6.

10. A computer program product comprising a computer program, characterized in that the computer program realizes the steps of the method of any one of claims 1 to 6 when executed by a processor.