CN116011859A - Complete set management method for digital concrete engineering construction - Google Patents

Abstract

The invention provides a digital concrete engineering construction complete set management method, which belongs to the technical field of concrete construction supervision, and the system for realizing the method comprises a storage server, a computer, a display, a digital information management platform, a remote client, field visual monitoring equipment, wearable positioning equipment, a weather monitoring system and a temperature sensing system, wherein the storage server and the computer are connected with the digital information management platform, and the program client, the field visual monitoring equipment, the wearable positioning equipment, the weather monitoring system and the temperature sensing system are connected with the digital information management platform. Aiming at the whole process management of concrete subsection project, the digital management reconstruction is realized through an informatization technology, and the management upgrading is carried out from the professional dimension. The digital collaborative management platform for the whole concrete construction process is used as a management tool to realize multiparty collaborative management of owners, construction parties, supervision parties, suppliers and the like, and the information transmission is timely and accurate, has strong traceability and is more convenient to communicate.

Description

Complete set management method for digital concrete engineering construction

Technical Field

The invention relates to the technical field of concrete construction supervision, in particular to a digital concrete engineering construction complete set management method.

Background

In the construction engineering of building engineering, the construction stage of concrete subsection engineering is the most important component part of main structure construction, and generally comprises: the method comprises the technical procedures of design, construction and deployment, concrete production, transportation, warehouse entry technology, form removal, maintenance and the like, wherein each procedure is respectively completed by different units. In the traditional management mode, after each procedure is completed, the next procedure is handed over in sequence, and the next procedure can be carried out after the procedure is qualified through the handover inspection of each unit, the acceptance inspection of the total contractor unit and the supervision acceptance inspection, until all procedures are completed, and finally the procedure is delivered for use.

Disadvantages of the prior art: (1) The management mode has low informatization degree, the main pipe factors are more by manually transmitting information, the information transmission time delay of each link is not easy to control, and the information is easy to be lost, missed or deviate. (2) The quality of the previous process has great influence on the quality of the subsequent process, the whole quality is greatly influenced after the correction, and (3) the information delay easily causes the difficulty in controlling the engineering progress, thereby greatly influencing the whole construction period.

The concrete engineering construction is the most basic subsection engineering in engineering construction and is the most important link for influencing the quality of a main body structure in the fields of industrial and civil buildings in China. The quality of the concrete material and the control quality of the process in the construction process need to be controlled in a refined mode, and due to the fact that the control parameters are more and the complexity is high, the final quality of the concrete structure can be affected by the implementation deviation of any control node, such as cracking or insufficient bearing capacity. In the conventional management mode, the management is controlled by personal experience of a manager in most cases, and deviation is easy to occur. In case of quality problems, not only the reinforcement cost is very high, but also the technical difficulty is very high.

Disclosure of Invention

The invention aims to provide a complete set of digital concrete engineering construction management method, which solves the technical problems that the prior concrete construction process has low informatization management degree, the construction quality can not be ensured, and the construction process can not be monitored.

In order to improve the informatization and intellectualization degree in the management process, a digital collaborative management method needs to be reconstructed to realize the goal of project management and a real-time intelligent decision mechanism, the innovation of the management method is realized based on a digital collaborative management platform, the information transmission across tissues and departments is more efficient and complete, and a closed-loop management system runs through the whole management process: the basic data is an engineering integral target for providing intelligent decision basis, automatically triggering decision flow by a grading early warning mechanism, accurately adjusting process progress, collecting management progress data, feeding back decision results and integrating data into an iterative basic database, and finally realizing quality and quantity guarantee delivery of concrete engineering construction.

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

the system for realizing the method comprises a storage server, a computer, a display, a digital information management platform, a remote client, a site visual monitoring device, a wearable positioning device, a weather monitoring system and a temperature sensing system, wherein the storage server and the computer are connected with the digital information management platform, the remote client, the site visual monitoring device, the wearable positioning device, the weather monitoring system and the temperature sensing system are connected with the digital information management platform, and the display is connected with the digital information management platform for display, and the method comprises the following steps:

step 1: configuring a computer, a storage server and two displays, and constructing a digital information management platform;

step 2: after the platform is built, inputting basic data into a business module of the digital information management platform to form a control index database, and setting a management target automatic management program of construction sub-project;

step 3: the visual monitoring equipment is deployed on the construction site, debugging is completed, port design is carried out to form a link address, and then the link address is connected with the port of the informationized platform;

step 4: deploying a weather monitoring system in the construction site range to acquire weather data, forming the weather real-time data into a data file, periodically carrying out data transmission connection with a digital information management platform, and displaying data in a cockpit;

step 5: deploying temperature sensing equipment at a construction position, debugging data, determining a sensor error value, and detecting temperature data in a construction process in real time;

step 6: before construction, wearing wearable equipment for constructors, debugging, monitoring personnel trajectories in the construction process, judging safety conditions, if dangerous conditions are met, timely sending early warning information by a system, displaying the early warning information in a cockpit, and sending a message to appointed management personnel for first time crisis treatment;

step 7: in the construction process, manager, supervision and owner each side conduct cooperative acceptance on quality through a client, the quality is uploaded to a digital information management platform, and the digital information management platform automatically feeds back and lists correction decisions to complete management closed loop;

step 8: after the project acceptance delivery, the digital information management platform automatically generates and files a project acceptance report.

In step 1, the digital information management platform includes five service modules and a data display cockpit, wherein the five service modules include a design management module, a resource element management module, a quality acceptance module, a process monitoring module and a safety management module, and the data cockpit displays control data and monitoring pictures of a linkage concrete construction site in real time.

Further, in step 2, a related national legal regulation provision database, an industry technical specification provision database, a design file database, a human resource information database, a material information database, an equipment information database and a mechanical information database are arranged in the control index database.

Further, in step 5, a temperature sensing device port program is written, data processed by errors of the temperature sensing device are formed into a data file, the data file is periodically connected with the digital information management platform in an information transmission mode, and real-time temperature data are displayed on a cockpit panel.

Further, the concrete process of monitoring the temperature data of the construction process in the step 5 is that the data of the internal and external temperatures of the concrete in the concrete construction process are collected in real time, index data affecting the quality of the concrete are compared with basic database data and weather monitoring data, the data can cause cracking and strength reduction, after abnormality is found, early warning grading is automatically carried out, decision making opinion is made, a production unit is informed of decision information such as factory temperature adjustment, water cooling and covering heat preservation is automatically carried out, the decision information is automatically sent to a manager, the manager is automatically appointed to carry out treatment according to the decision information, after the data are recovered to be normal, early warning is released, follow-up work is normally carried out, the data are collected in real time, and finally data are integrated, so that data support is provided for database data iteration.

In step 4, the weather conditions are key conditions affecting the concrete construction process and the construction quality, natural data of temperature and humidity are collected in real time, the natural data are compared with basic database data, the data indexes affecting the concrete quality are analyzed, the early warning level is pushed by automatic decision, the early warning level corresponds to a treatment method, the treatment method comprises a measure method of delay, coverage and moisture spraying, the measure method is automatically sent to related staff in charge, the related staff in charge of working carries out treatment, system authentication is submitted after the treatment is completed, after the collected data are normal, decision opinion is pushed by the system automatically, early warning is released, normal construction is carried out according to a plan, and after the manager starts, the program resumes normal collection.

Further, in step 6, a safety monitoring sensor is configured on the wearable device, safety data of monitoring personnel, personnel track, acceleration and data of distance from a dangerous source are compared with safety data of a basic database, if the safety data is abnormal, early warning prompt is carried out according to an early warning level, management personnel and operators receive treatment comments at the same time and correct the treatment comments in time, the construction progress is continued after the data are normal, meanwhile, actual construction progress data are counted in real time, the real-time statistics is compared with progress plan data in the basic database, early warning prompt is automatically carried out after the abnormality, the management personnel carry out work correction according to decision data, and early warning is released after the data are normal.

Further, step 2 sets up management objective automatic management program of construction sub-project, establishes management closed loop management control mechanism, carries on early warning reminding according to data after data acquisition, carries on decision after generating early warning reminding, carries on decision after carrying on decision, then carries on data integration to the implemented data, forms the closed loop management mode of data, builds up corresponding standardized work flow, manages and supports data, carries on data standard, checks and uses data as index, first sets up specific standard of management objective, carries on standardized entry of key data in design result into digital information management platform, forms basic database with concrete material parameter, relevant national legal regulation, relevant industry technical standard, data required by construction process, the data input of the resource elements and the mechanical equipment related to project management is formed into database data, the data is endowed with connection attributes, each management stage of each level of the construction department is automatically assigned, then, a standard working procedure is built according to the construction process sequence, each procedure data of inspection, acceptance, concrete production stirring stations, transportation, warehouse entry, vibration, form removal, maintenance, repair and the like is collected from an intelligent module in real time, a comparison decision is made with the database data, the next procedure is automatically carried out according to the standard, if abnormality occurs, the early warning level is automatically judged according to the data, then, decision data is sent to a manager for disposal, the data enters a working procedure after the management action is completed, after the management action returns to normal, the next procedure is carried out until all procedures are completed, finally, the process data is automatically integrated into a database, the comparison analysis is carried out with a basic database, the database data is automatically iterated based on the analysis result, the closed loop management is completed.

In step 6, a safety monitoring sensor configured by a wearable device of a constructor records the vibration time, the safety monitoring sensor records the stay time, the vibration time at each position is not lower than 20 seconds and is used as a vibration point record, the system automatically eliminates the record points which do not meet the time requirement, after the concrete pouring is completed, the program counts the distance between the vibration points and compares the distance standard requirement in a basic database, if the distance between the actual vibration points is larger than the distance standard, the concrete quality risk is generated, the vibration points need to be newly increased between the two vibration points at the position, the whole process is monitored, the comprehensive analysis of the monitoring data is performed in the platform and compared with the control data of the database, the comprehensive analysis result of the monitoring data predicts whether the concrete quality index is in a normal range, if abnormal occurs, the system makes an intelligent decision, gives a risk level and a processing method, the decision is automatically pushed to related responsible personnel, the related personnel starts a processing program until the monitoring data is recovered to be normal, the early warning of the system is released, the subsequent monitoring work is completed, and finally.

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

(1) The invention establishes a comprehensive digital management method aiming at the whole process management of concrete subsection project, realizes digital management reconstruction through an informatization technology, and carries out management upgrading from a professional dimension. The digital collaborative management platform of the whole concrete construction process is used as a management tool to realize multiparty collaborative management of owners, construction parties, supervision parties, suppliers and the like, so that the information transmission is timely and accurate, the traceability is strong, and the communication is more convenient;

(2) And taking the data as a main line, and establishing a highly-targeted management closed-loop mechanism and an intelligent decision mechanism. A basic database is established, and related laws and regulations, industry standards, design requirements and the like are set up to realize early warning grading and intelligent decision making of key factors such as quality, progress, safety and the like in the management process;

(3) The display cockpit can display key control data and on-site monitoring pictures on line in real time, thereby realizing the intuitiveness of management and timeliness of problem treatment and providing quality guarantee for the final delivery of concrete engineering;

(4) The management efficiency and the management quality are greatly improved, the management comprehensive cost is greatly reduced, the method can be applied to concrete engineering construction of conventional construction projects, and the popularization is strong.

Drawings

FIG. 1 is a schematic diagram of a digital information collaborative management platform structure according to the present invention;

FIG. 2 is a schematic diagram of a management closed-loop mechanism of the present invention;

FIG. 3 is a schematic diagram of the data application principle of the visual intelligent module of the present invention;

FIG. 4 is a schematic diagram of the data application principle of the weather monitoring module of the present invention;

FIG. 5 is a schematic diagram of the data application principle of the temperature sensing system of the present invention;

fig. 6 is a schematic view of the concrete quality control principle of the present invention.

In the drawing, a host of a 1-64 bit operating system; 2-a storage server; 3-data cockpit display; 4-a field monitoring monitor; 5-development of a digital collaborative management platform system for concrete engineering construction; 6-module navigation display; 7-database construction; 8-a visual monitoring module; 9-a weather monitoring module; 10-a temperature sensing module; 11-port design.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail below by referring to the accompanying drawings and by illustrating preferred embodiments. It should be noted, however, that many of the details set forth in the description are merely provided to provide a thorough understanding of one or more aspects of the invention, and that these aspects of the invention may be practiced without these specific details.

1-6, the digital concrete engineering construction complete set management method comprises a proprietary storage server, a computer host, two displays, a digital information management platform, a mobile phone APP applet, a set of field visual monitoring equipment, a set of wearable positioning equipment, a set of weather monitoring system, a set of temperature sensing system and the like.

A method for collaborative management of digitized information in the whole process of concrete engineering construction comprises the following steps:

step one: a computer host with a 64-bit operating system, a storage server and two displays are configured.

Step two: and constructing a digital information management platform. The system comprises five business modules and a data display cockpit, wherein the business modules comprise design management, resource element management, quality acceptance, process monitoring and safety management, and the data cockpit displays control data and monitoring pictures of a linkage site in real time. And (3) building a standardized flow and a curing flow approval system in the platform, and organically and orderly coordinating the business and organization structures of each plate.

Step three: after the platform is built, basic data are input into each module, and a control index database is formed. The database comprises: eight basic databases such as national legal regulations, industry technical specification, design files, human resource information, material information, equipment information, mechanical information and the like are involved.

Step four: and (3) deploying visual monitoring equipment on a construction site, debugging, designing ports to form a link address, and connecting with the port of the informationized platform.

Step five: and a weather monitoring system is deployed in the construction range, weather real-time data are formed into a data file, the data file is connected with an informatization platform at regular intervals, and the data is displayed in a cockpit.

Step six: and deploying temperature sensing equipment at the construction position, debugging data, and determining a sensor error value. And writing a port program, forming data files by error processing data, periodically connecting with a port of a management platform, and displaying real-time data on a cockpit panel.

Step seven: before construction, wearing wearable equipment for constructors, debugging, monitoring personnel trails in the construction process, judging safety conditions, if dangerous conditions are met, timely sending early warning information by the system, displaying the early warning information in a cockpit, and sending information to appointed management personnel for first time crisis treatment.

Step eight: in the construction process, manager, supervision and owner in each stage conduct cooperative acceptance on quality, the quality is uploaded to a platform, and the platform automatically feeds back and intelligently rectifies and makes decisions to complete management closed loop.

Step nine: after the project acceptance delivery, the platform automatically generates and files a project acceptance report.

Description of the principles

1. The method is characterized in that resource elements are combed aiming at the whole process of concrete construction subsection engineering, the digital management method is used for carrying out management mode reconstruction, connection attributes are endowed to key data through computer logic, data are transmitted across departments and layers in a system, the data are timely and accurately realized, barriers among the departments are opened, and the digital reconstruction of management is completed.

2. And establishing a management and control mechanism of a management closed loop according to the management target of the concrete construction subsection project, and establishing a closed loop management mode of data, early warning, decision making, implementation and data integration to data, thereby preparing a standardized workflow corresponding to the closed loop management mode. The management is supported by data, the decision is based on the data, the standard is implemented by the data, and the inspection is based on the data. Firstly, setting specific standards of management targets, carrying out standardized entry system on key data in design results, forming a basic database by data such as concrete material parameters, relevant national legal and regulatory regulations, relevant industry technical standards, construction process requirements and the like, and entering data such as project management relevant resource elements, mechanical equipment and the like to form database data, wherein each data is endowed with connection attributes, and each management stage of each level of each department is automatically assigned; secondly, building a standard working procedure according to a construction process sequence, collecting process data of each process such as acceptance, concrete production stirring stations, transportation, warehouse entry, vibration, form removal, maintenance, repair and the like from an intelligent module in real time, comparing and deciding with database data, automatically judging an early warning level according to the data if abnormality occurs, sending decision data to a manager for treatment, entering the working procedure after the management action is completed, and entering the next process after returning to normal until all the processes are completed; and finally, automatically integrating the process data into a database, comparing and analyzing the database with a basic database, and automatically iterating and upgrading the database data based on the analysis result to finish closed-loop management.

3. The principle is applied to the data of the visual intelligent module. The module is mainly used for monitoring and early warning aiming at safety and progress management targets, and the images are independently displayed according to the characteristic of strong visual property of the visualization. The wearable equipment is provided with a safety monitoring sensor, safety data of monitoring personnel, such as personnel track, acceleration, distance from a dangerous source and the like, are compared with the safety data of a basic database, if the safety data is abnormal, early warning prompt is carried out according to the early warning level, management personnel and operating personnel receive processing comments at the same time, correction is carried out in the first time, and the construction process is continued after the data are normal; meanwhile, the actual construction progress data are counted in real time, the actual construction progress data are compared with the progress plan data in the basic database, early warning prompt is automatically entered after abnormality, management staff work and revise according to decision data, and early warning is released after the data are normal.

4. The weather monitoring module data applies principles. The weather condition is the key condition affecting the concrete construction process and the construction quality, natural data such as cold, heat, temperature, humidity and the like are collected in real time, the data is compared and analyzed with basic database data, the data index affecting the concrete quality is automatically decided and pushed to the early warning level by the system, the early warning level corresponds to the treatment method, such as delay, coverage, moisturizing spraying and other measures, the early warning level is automatically sent to related personnel, the related personnel are processed by the formulator, the system authentication is submitted after the processing is finished, after the collected data is normal, the system automatically puts forward decision opinion to perform normal construction according to a plan, and after the manager starts, the program resumes normal collection.

5. The temperature sensing system data applies principles. According to the sensor principle, the data of the internal and external temperatures of the concrete in the concrete construction process are collected in real time, index data affecting the quality of the concrete is compared with basic database data and weather monitoring data, such as data of cracking, strength reduction and the like, after abnormality is found, the system automatically performs early warning grading and makes processing decisions, such as notifying a production unit of decision information of adjusting factory temperature, water supply cooling, covering heat preservation and the like, the decision information is automatically sent to related personnel, the designated personnel carries out treatment according to the decision information, after the data is recovered to be normal, early warning of the system is released, follow-up work is normally carried out, the data is collected in real time, and finally, data support is provided for database data iteration through integrating data.

6. And (3) according to a concrete quality control principle, comprehensively analyzing data and intelligently deciding. The concrete quality risk mainly comprises the phenomenon that the concrete strength is insufficient and the concrete cracks, and standard data such as the concrete strength range, the allowable crack width and the like are provided in a basic database. Therefore, key control indexes in the construction process are as follows: the intelligent concrete system comprises a concrete outlet temperature, a concrete warehouse-in temperature, initial setting time, temperature rise in the interior of the concrete, temperature rise in the surface of the concrete, external temperature of the concrete, water content of the concrete, rainfall, vibrating track, vibrating time, cold joint time interval, progress time and the like, and can be directly obtained and displayed in real time through the intelligent module. The vibration track is recorded by a safety monitoring sensor configured by a wearable device of a constructor in the visual intelligent module; and (3) the vibration time, recording the stay time through a safety monitoring sensor, recording the vibration time at each position which is not less than 20 seconds as a vibration point, automatically removing the record points which do not meet the time requirement, counting the distance between the vibration points through a program after the concrete pouring is completed, comparing the distance with the distance standard requirement in a basic database, and if the distance between the actual vibration points is greater than the distance standard, generating concrete quality risk and re-increasing the vibration points between the two vibration points. The other indexes are monitored in the whole process, the data are comprehensively analyzed through an algorithm in the platform and compared with the control data of the database, the comprehensive analysis result of the monitoring data predicts whether the concrete quality index is in a normal range, if abnormal occurs, the system makes an intelligent decision, gives a risk level and a processing method, the decision is automatically pushed to related personnel, the related personnel starts a processing program until the monitoring data are recovered to be normal, the system early warning is released, the subsequent monitoring work is continued, and finally delivery is completed.

The method is characterized by comprising the following steps of carrying out digital reconstruction aiming at the whole process management of the concrete subsection project construction stage in the project construction, developing a digital collaborative management platform as a management tool based on a management closed-loop mechanism, and integrating five management elements of digitalization of resource elements, standardization of business processes, visualization of construction processes, real-time monitoring and early warning of quality progress, and linkage of safety management. And establishing a basic database and a standard control system to form an intelligent decision basis.

Concrete quality monitoring is controlled through comprehensive data intelligent decision making. And (3) port design, linking the collaboration platform with intelligent modules such as a sensor and monitoring equipment, displaying the management process in real time and monitoring the management quality. Comparing the real-time collected data with the data of the basic database to form an early warning level, correspondingly performing intelligent decision making, normally performing construction after early warning is released, finally forming analysis data by the data, and fusing with the original database for continuous iterative optimization, thereby ensuring the delivery of the quality and the quantity of the concrete engineering.

The foregoing is merely a preferred embodiment of the present invention and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present invention, which are intended to be comprehended within the scope of the present invention.

Claims (9)

1. A digital concrete engineering construction complete set management method is characterized in that: the system for realizing the method comprises a storage server, a computer, a display, a digital information management platform, a remote client, a site visual monitoring device, a wearable positioning device, a weather monitoring system and a temperature sensing system, wherein the storage server and the computer are connected with the digital information management platform, the remote client, the site visual monitoring device, the wearable positioning device, the weather monitoring system and the temperature sensing system are connected with the digital information management platform, and the display is connected with the digital information management platform for display, and the method comprises the following steps:

step 1: configuring a computer, a storage server and two displays, and constructing a digital information management platform;

step 2: after the platform is built, inputting basic data into a business module of the digital information management platform to form a control index database, and setting a management target automatic management program of construction sub-project;

step 3: the visual monitoring equipment is deployed on the construction site, debugging is completed, port design is carried out to form a link address, and then the link address is connected with the port of the informationized platform;

step 4: deploying a weather monitoring system in the construction site range to acquire weather data, forming the weather real-time data into a data file, periodically carrying out data transmission connection with a digital information management platform, and displaying data in a cockpit;

step 5: deploying temperature sensing equipment at a construction position, debugging data, determining a sensor error value, and detecting temperature data in a construction process in real time;

step 6: before construction, wearing wearable equipment for constructors, debugging, monitoring personnel trajectories in the construction process, judging safety conditions, if dangerous conditions are met, timely sending early warning information by a system, displaying the early warning information in a cockpit, and sending a message to appointed management personnel for first time crisis treatment;

step 7: in the construction process, manager, supervision and owner each side conduct cooperative acceptance on quality through a client, the quality is uploaded to a digital information management platform, and the digital information management platform automatically feeds back and lists correction decisions to complete management closed loop;

step 8: after the project acceptance delivery, the digital information management platform automatically generates and files a project acceptance report.

2. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: in step 1, the digital information management platform comprises five service modules and a data display cockpit, wherein the five service modules comprise a design management module, a resource element management module, a quality acceptance module, a process monitoring module and a safety management module, and the data cockpit displays control data and monitoring pictures of a linkage concrete construction site in real time.

3. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: in the step 2, a related national legal regulation provision database, an industrial technical specification provision database, a design file database, a human resource information database, a material information database, an equipment information database and a mechanical information database are arranged in the control index database.

4. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: and 5, programming a port program of the temperature sensing equipment, forming a data file from the data processed by the errors of the temperature sensing equipment, periodically connecting with the information transmission of the digital information management platform, and displaying real-time temperature data on a cockpit panel.

5. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: the concrete process of monitoring the temperature data of the construction process in step 5 is that the data of the internal and external temperatures of the concrete in the concrete construction process are collected in real time, index data affecting the quality of the concrete are compared with basic database data and weather monitoring data, the data can cause cracking and strength reduction, after abnormality is found, early warning grading is automatically carried out, processing decision opinion is made, a production unit is informed of decision information of adjusting factory temperature, cooling through water and covering heat preservation, the decision information is automatically sent to a manager, the manager is automatically appointed to treat according to the decision information, after the data are recovered to be normal, early warning is released, follow-up work is normally carried out, the data are collected in real time during the period, and finally data are integrated, and data support is provided for database data iteration.

6. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: in the step 4, weather conditions are key conditions affecting the concrete construction process and construction quality, natural data of temperature and humidity are collected in real time, the natural data are compared with basic database data for analysis, data indexes affecting the concrete quality are automatically decided, early warning levels are pushed, the early warning levels correspond to treatment methods, the treatment methods comprise delay, coverage and moisture spraying measures, the treatment methods are automatically sent to relevant working responsible personnel, the relevant working responsible personnel conduct treatment, system authentication is submitted after the treatment is completed, after the collected data are normal, decision opinion is automatically pushed by the system, early warning is released, normal construction is conducted according to a plan, and after the management personnel start, the program resumes normal collection.

7. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: in step 6, safety monitoring sensors are configured on the wearable equipment, safety data of monitoring personnel, personnel track, acceleration and data of distances from dangerous sources are compared with safety data of a basic database, if the safety data is abnormal, early warning prompt is carried out according to early warning levels, management personnel and operators receive processing comments at the same time, correction is carried out in time, construction progress is continued after the data are normal, meanwhile, actual construction progress data are counted in real time, the safety data are compared with progress plan data in the basic database, early warning prompt is automatically carried out after the abnormality, the management personnel carry out working correction according to decision data, and early warning is released after the data are normal.

8. The digital concrete engineering construction complete set management method according to claim 1, wherein the method comprises the following steps: setting a management target automatic management program of construction sub-project, setting a management closed-loop management control mechanism, carrying out early warning reminding according to data after data acquisition, carrying out decision making after the early warning reminding is generated, carrying out data integration on the implemented data to form a closed-loop management mode of the data, preparing a corresponding standardized work flow, managing the data as a support, carrying out data-based standard on the decision making, checking the data as an index, firstly setting specific standard of the management target, carrying out standardized entry of key data in the design result into a digital information management platform, forming a basic database according to data required by the project management related resource elements and mechanical equipment, carrying out data entry into a database data according to the related national legal regulation, endowing connection attribute to the project management related resource elements and the mechanical equipment, carrying out automatic decision making for each management stage of the construction sub-project, setting up standard work flow according to the construction process sequence, carrying out data-based on the decision making, carrying out standard of transportation, warehouse entry, vibration, module, maintenance and maintenance, carrying out automatic regression analysis on the data from the intelligent data to the intelligent data base after the automatic decision making, carrying out the comparison with the data, carrying out the automatic analysis of the data, and carrying out the comparison with the data, and carrying out the automatic analysis, and carrying out the comparison and the step-up and the step-by the automatic decision-by the personnel after the automatic decision-making the data is completed in comparison with the data, if the automatic decision-making the data is completed and the step is completely analyzed by comparing with the data of the data input into the automatic decision database after the data is carried out the normal decision and the quality is carried out the quality and the quality is finally after the quality is compared with the quality is stored, the closed loop management is completed.

9. The digital concrete engineering construction complete set management method according to claim 8, wherein the method comprises the following steps: in step 6, the security monitoring sensor configured by the wearable equipment of constructors records the vibration time, the security monitoring sensor records the stay time, the vibration time at each position is not less than 20 seconds as a vibration point record, the system automatically eliminates the record points which do not meet the time requirement, after the concrete pouring is completed, the program counts the distance between the vibration points and compares the distance standard requirement in a basic database, if the distance between the actual vibration points is greater than the distance standard, the concrete quality risk is generated, the vibration points are required to be newly increased between the two vibration points at the position, the whole process is monitored, the platform comprehensively analyzes the data and compares the data with the database control data, the comprehensive analysis result of the monitoring data predicts whether the concrete quality index is in a normal range, if the concrete quality index is abnormal, the system intelligently decides, the risk level and the processing method are given, the decision is automatically pushed to the related responsible person until the monitoring data is recovered, the system early warning is released, the subsequent monitoring work is completed, and finally, the delivery program is started.

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