CN114662948B - Construction engineering quality detection supervision method and system - Google Patents

Abstract

The invention relates to the technical field of construction engineering, and discloses a construction engineering quality detection supervision method and a construction engineering quality detection supervision system. The problem that detection data are deviated from the real situation to bring great hidden danger to the construction engineering quality is avoided.

Description

Construction engineering quality detection supervision method and system

Technical Field

The invention relates to the technical field of construction engineering, in particular to a construction engineering quality detection supervision method and system.

Background

In recent years, the construction industry management has advanced into information-based construction, and as an important means for engineering quality supervision, the standardization of engineering quality detection and detection market has attracted more and more attention from government authorities.

In the management mode of the traditional detection mechanism at present, certain loopholes exist in multiple layers such as people, machines, materials, methods and rings, deviation of detection data and the real situation is easily caused, and serious loopholes even breed corruption, so that great hidden dangers are brought to the quality of construction projects.

In order to better improve the supervision and control strength and further promote the engineering quality supervision standardization and normalized construction, the invention of the real-time and dynamic supervision system for the construction engineering quality detection is the current primary task. How to provide a comprehensive, accurate, real-time and dynamic monitoring system and method for detecting the quality of construction engineering becomes a technical problem to be solved urgently in the prior art.

Disclosure of Invention

Aiming at the technical problems existing in the prior stage, the invention provides a new construction project quality detection monitoring method and system by combining an expected completion time axis and a real-time image monitoring system, and can provide comprehensive, accurate and real-time dynamic detection for the construction project quality.

In some embodiments of the application, a double-line supervision mode combining the construction expected completion time axis and the construction site real-time monitoring is established, the supervision platform can be used for monitoring in real time and issuing detection tasks, and the expected completion data and the real-time completion data are compared to realize the double-line supervision on the construction project quality and the construction time.

In some embodiments of the application, construction progress early warning and construction progress inquiry processes are increased, reason analysis is carried out by inquiring construction history numbers, expected completion time axes are corrected in time through reason feedback, detection time task nodes are generated through the expected progress time axes, and supervision of detection tasks is completed. And the dynamic supervision of construction quality detection is better realized.

Some embodiments of the present application provide a construction engineering quality detection supervision method, including:

acquiring original data of a construction project, establishing an expected progress time axis and a detection task time node according to the original data, and sending a detection task instruction according to the detection task time node;

monitoring the construction progress in real time and acquiring real-time data of the construction progress; acquiring the real-time data of the construction progress and generating a first time accumulated value;

determining a corresponding point of the construction progress real-time data on the expected progress time axis, and generating a second time accumulated value;

and acquiring a difference value between the first time accumulated value and the second time accumulated value, and judging whether the current construction progress accords with an expected value according to a difference value result.

In some embodiments of the application, when a difference between the first time cumulative value and the second time cumulative value is obtained and whether the current construction progress meets an expected value is determined according to a difference result, the method specifically includes:

when the first time accumulated value is lower than the second time accumulated value, judging whether the absolute value of the difference value exceeds a first preset value or not;

if the absolute value is larger than the first preset value, sending a self-checking task instruction to a constructor task terminal;

if the absolute value is not greater than the first preset value, a rechecking task instruction is sent to a task terminal of the detection mechanism;

after the rechecking task instruction is sent to the detection mechanism task terminal, detection data uploaded by a detection mechanism are obtained, and if the detection data do not exceed a threshold value, a construction task instruction is given; and if the detection data exceeds the threshold value, sending a rectification task instruction to a construction party, and after rectification is finished, sending a rechecking task instruction to the detection mechanism and acquiring the detection data until the detection is qualified.

In some embodiments of the application, after sending self-checking task instruction to constructor, obtain the self-checking data that constructor uploaded, if self-checking data does not exceed the threshold value, then send the rechecking task instruction to detection mechanism task terminal and obtain detection data, if detection data exceeds the threshold value, then send the rectification task instruction to the constructor, treat after the rectification is accomplished, right detection mechanism sends the rechecking task instruction and obtains detection data, until detecting qualified.

In some embodiments of the present application, when obtaining a difference between the first time cumulative value and the second time cumulative value, and determining whether the current construction progress meets an expected value according to the difference result, specifically:

when the first time accumulated value is higher than the second time accumulated value, judging whether the absolute value result exceeds a second preset value;

if the absolute value is larger than the second preset value, sending a progress early warning instruction to a constructor task terminal;

and sending a reason query instruction to a constructor, acquiring construction history index data and construction expected data, performing reason query and correcting the time axis of the expected progress.

And if the absolute value is not greater than the second preset value, sending a construction continuing instruction to a constructor.

And sending a reason query instruction to a construction party, acquiring construction history index data and construction expected data, performing reason query and correcting the time axis of the expected progress.

In some embodiments of the application, when a difference between the first time cumulative value and the second time cumulative value is obtained, and whether the current construction progress meets an expected value is determined according to the difference result, the method specifically includes:

and if the first time accumulated value is the same as the second time accumulated value, sending a continuous construction instruction to a constructor, and when the detection task time node is reached, sending a detection task instruction to the constructor.

Some embodiments of the present application provide a construction engineering quality detection supervisory system, including:

the data processing unit is used for processing the construction project data and generating an expected progress time shaft and a detection task time node;

the data acquisition unit is used for acquiring data of 24 hours on a construction site; uploading the data to a data processing module;

a time stamp generating unit for generating a first time accumulation value and a second time accumulation value, and generating a difference value of the first time accumulation value and the second time accumulation value;

a task terminal for receiving task book and uploading test data

And the task processing unit is used for sending the related task instruction to the task terminal.

And the task monitoring unit is used for monitoring the time nodes of all the detection tasks, ensuring the construction progress of the detection tasks, sending task reminders to the detection mechanism according to the tasks in the expected time nodes, and monitoring according to the predicted task completion time of the detection mechanisms.

In some embodiments of the present application, the task processing unit includes:

a first acquisition module configured to acquire first time accumulated value data and second time accumulated value data, and acquire an absolute value of the difference;

and the first judging module is used for judging the magnitude relation between the first time accumulated value and the second time accumulated value and judging the magnitude relation between the absolute value result of the difference and a preset value.

In some embodiments of the present application, the task processing unit further includes:

a second obtaining module, configured to obtain the detection data uploaded by the task terminal

The second judgment module is used for judging whether the detection data exceeds a preset threshold value or not;

and the processing module is used for sending related task instructions based on the judgment results of the first judgment module and the second judgment module.

In some embodiments of the present application, the data acquisition unit comprises:

the image acquisition module comprises a plurality of image acquisition devices and is used for acquiring 24-hour images of a construction site;

and the environment data acquisition module is used for collecting environment data of the construction site.

Some embodiments of the present application further comprise:

the authority identification unit is used for verifying the authority of the login person;

and the data storage unit is used for storing the detection data and the data sent by the information acquisition unit.

Aiming at the technical problems existing in the prior stage, the invention provides a new construction project quality detection and supervision method and system by combining an expected completion time axis and a real-time image monitoring system, so that the construction time and quality of the construction project are monitored doubly, a beneficiary can monitor the construction progress and the construction quality in real time through a terminal at any time, and the comprehensive, accurate, real-time and dynamic detection of the construction project quality can be provided. The problem that detection data deviate from the real situation to bring great hidden danger to the construction engineering quality is avoided.

Drawings

FIG. 1 is a schematic view of a construction project quality detection supervision system according to an embodiment of the present application;

fig. 2 is a schematic flow chart of a construction engineering quality detection supervision method in an embodiment of the present application;

FIG. 3 is a flow chart of a construction engineering quality detection and supervision method in the embodiment of the present application

Detailed Description

The following detailed description of embodiments of the present invention is provided in connection with the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present application, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present application.

The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, the meaning of "a plurality" is two or more unless otherwise specified.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

As shown in fig. 1, some embodiments of the present application provide a construction engineering quality detection and supervision system, which specifically includes:

the data processing unit is used for processing the construction project data and generating an expected progress time shaft and a detection task time node;

the data acquisition unit is used for acquiring 24-hour data of a construction site; uploading the data to a data processing module;

a time stamp generating unit for generating a first time cumulative value and a second time cumulative value, and generating a difference value of the first time cumulative value and the second time cumulative value;

task terminal for receiving task book and uploading test data

And the task processing unit is used for sending the related task instruction to the task terminal.

The task monitoring unit is used for monitoring the time nodes of all the detection tasks, ensuring the construction progress of the detection tasks, sending task reminders to the detection mechanism according to the tasks in the expected time nodes, and monitoring according to the predicted task completion time;

the authority identification unit is used for limiting the authority of a login user, and a construction party, a detection mechanism and a third party of the login user log in through different terminals;

the data storage unit is used for storing the detection data and the data sent by the information acquisition module, and backing up the acquired real-time construction data, the self-test task return data, the recheck task return data, the detection task return data and other related data, so that the checking is convenient;

the task terminal is preferably mobile equipment or computer equipment of a construction party and a detection mechanism;

the first time accumulated value is the time interval from the project starting time to the time of generating the first time accumulated value, and the second time accumulated value is the time interval from the project starting time to the time corresponding to the time shaft of the construction progress real-time data in the expected progress;

in some embodiments of the present application, the processing unit is preferably:

a first acquisition module configured to acquire first time accumulated value data and second time accumulated value data, and acquire an absolute value of the difference;

the first judgment module is used for judging the magnitude relation between the first time accumulated value and the second time accumulated value and judging the magnitude relation between the absolute value result of the difference and a preset value;

a second obtaining module, configured to obtain the detection data uploaded by the task terminal

The second judgment module is used for judging whether the detection data exceeds a preset threshold value;

and the processing module is used for sending related task instructions based on the judgment results of the first judgment module and the second judgment module.

In some embodiments of the present application, the data acquisition unit comprises:

the image acquisition module comprises a plurality of image acquisition devices and is used for acquiring 24-hour images of a construction site;

the environment data acquisition module is used for collecting environment data of a construction site;

furthermore, the image acquisition module is preferably a plurality of image acquisition devices, is arranged at a construction site and is used for acquiring 24-hour image information of a construction project,

the environment data acquisition unit is preferably a temperature and humidity monitoring device and is used for collecting environment data of the construction site.

In another preferred implementation manner based on the foregoing embodiment, the present implementation manner provides a construction engineering quality detection and supervision method, including the following steps:

acquiring original data of a construction project, establishing an expected progress time axis and a detection task time node according to the original data, and sending a detection task instruction according to the detection task time node;

monitoring the construction progress in real time and acquiring real-time data of the construction progress; acquiring the construction progress data and generating a first time accumulated value;

determining a corresponding point of the construction progress real-time data on the expected progress time axis, and generating a second time accumulated value;

and acquiring a difference value between the first time accumulated value and the second time accumulated value, and judging whether the current construction progress conforms to an expected value according to the difference value result.

When the difference between the first time accumulated value and the second time accumulated value is obtained and whether the current construction progress accords with an expected value is judged according to the difference result, the method specifically comprises the following steps:

when the first time accumulated value is lower than the second time accumulated value, judging whether the absolute value of the difference value exceeds a first preset value or not;

if the absolute value is larger than the first preset value, sending a self-checking task instruction to a constructor task terminal;

if the absolute value is not greater than the first preset value, a rechecking task instruction is sent to a task terminal of the detection mechanism;

after the rechecking task instruction is sent to the detection mechanism task terminal, detection data uploaded by a detection mechanism are obtained, and if the detection data do not exceed a threshold value, a construction task instruction is given; and if the detection data exceeds the threshold value, sending a rectification task instruction to a construction party, and after rectification is finished, sending a rechecking task instruction to the detection mechanism and acquiring the detection data until the detection is qualified.

After a self-checking task instruction is sent to a construction party, self-checking data uploaded by the construction party are obtained, if the self-checking data do not exceed a threshold value, a rechecking task instruction is sent to a detection mechanism task terminal, the detection data are obtained, if the detection data exceed the threshold value, an rectification task instruction is sent to the construction party, after rectification is completed, a rechecking task instruction is sent to a detection mechanism, and detection data are obtained until detection is qualified.

When the difference between the first time cumulative value and the second time cumulative value is obtained and whether the current construction progress meets an expected value is judged according to the difference result, the method specifically comprises the following steps:

when the first time accumulated value is higher than the second time accumulated value, judging whether the absolute value result exceeds a second preset value;

if the absolute value is larger than the second preset value, sending a progress early warning instruction to a constructor task terminal;

and sending a reason query instruction to a constructor, acquiring construction history index data and construction expected data, performing reason query and correcting the time axis of the expected progress.

And if the absolute value is not greater than the second preset value, sending a construction continuing instruction to a constructor.

And sending a reason query instruction to a construction party, acquiring construction history index data and construction expected data, performing reason query and correcting the time axis of the expected progress.

When the difference between the first time accumulated value and the second time accumulated value is obtained and whether the current construction progress accords with an expected value is judged according to the difference result, the method specifically comprises the following steps:

and if the first time accumulated value is the same as the second time accumulated value, sending a continuous construction instruction to a constructor, and when the detection task time node is reached, sending a detection task instruction to the constructor.

In another preferred implementation based on the above embodiment, taking a high-rise construction project as an example, a constructor inputs original data of a constructor, a supervision system generates an expected completion time axis according to the original project data, and the specific process is to extract expected time data of construction to different heights according to floor heights as marking data, and establish the expected completion time axis according to the expected time data;

specifically, the acquiring of the original data comprises the following steps of construction organization design: the method mainly comprises the steps of project overview and characteristics, guidance thought of project construction arrangement and construction stage division; construction layout, construction order and overall project progress (network plan); the main construction method and quality assurance measures; labor consumption; construction machinery, materials, semi-finished products and prefabricated parts demand amount plan and transportation plan; planning large temporary facilities; construction preparation work plan; safety measures; a construction floor plan; a mass system; security systems, etc.

The method comprises the steps that key time nodes are extracted from an expected completion time axis to establish detection task time nodes, the detection task time nodes refer to task nodes needing quality detection when a construction period is normal, a supervisory system sends detection task instructions to a detection mechanism according to the detection task time nodes, detection data returned by the detection mechanism are checked to judge whether the detection data are qualified or not, if the detection data are qualified, construction tasks of the next stage are carried out, if the detection data are not qualified, a rectification task instruction is sent to a constructor, and a rechecking detection instruction is sent to the detection mechanism until the rectification is qualified.

The visitor can get into supervisory systems through the authentication of authority module identification module to can acquire construction progress real-time data, its construction progress real-time data is collected through the data acquisition module of predetermineeing in the job site, after the visitor acquires construction progress real-time data, generate the first time cumulative value, and extract the mark data in the real-time data collected and be floor height, confirm the corresponding time of the real-time progress of present stage on the time axis of expected completion according to the mark data, and generate the second mark time.

By judging the magnitude relation between the first time cumulative value and the second time cumulative value and the absolute value difference value, a related task instruction is sent out,

the specific process is that when the first time accumulated value is lower than the second time accumulated value, namely the actual construction speed is higher than an expected value, the possibility of quality reduction caused by over-high construction exists at the moment, the visitor should carry out dynamic monitoring, and the process is that the absolute value of the difference value of the first time accumulated value and the second time accumulated value is processed, and whether the absolute value result exceeds a first preset value is judged.

The first preset value is a set value, and is set according to the characteristics of the construction project, and represents the maximum safety advance of the actual construction speed, in this embodiment, the first preset value is 14 days, that is, the maximum safety advance of the actual construction speed is 14 days.

If the absolute value of the difference value between the first time accumulated value and the second time accumulated value is greater than the first preset value for 14 days, the visitor sends a self-checking task instruction to a task terminal of a construction party, the task terminal is mobile equipment or computer equipment, the construction party needs to return self-checking data through the task terminal within the time specified by the self-checking task instruction, and the supervision system judges whether the self-checking data is qualified or not and dispatches a specified task after obtaining the returned self-checking data.

Specifically, the monitoring system judges whether the returned self-checking data exceeds a threshold value, wherein the threshold value is a national specified construction standard value or is lower than a national standard value. The self-checking data comprises construction project detection data and construction site real-time environment data. If the self-checking data do not exceed the threshold, a rechecking task instruction is sent to a detection mechanism task terminal, the detection mechanism task terminal is mobile equipment or computer equipment, the detection mechanism needs to return the rechecking data through the task terminal within the time specified by the rechecking task instruction, the supervision system judges whether the returned rechecking data exceed the threshold, and only when the rechecking data are qualified, the construction party can perform the construction task of the next stage.

If the rechecking data returned by the detection mechanism exceeds a threshold value, the supervision system sends a rectification task instruction to the construction party, the construction party rectifies unqualified projects, the supervision system monitors according to the specified rectification task time, and if the task data after rectification is not returned in an overdue period, a promotion instruction is sent to the construction party.

Specifically, after acquiring the correction data returned by the construction party, the supervision platform sends a rechecking task instruction to the detection mechanism, the detection mechanism needs to return the rechecking data through the task terminal within the time specified by the rechecking task instruction, the supervision system judges whether the returned rechecking data exceeds a threshold value, the construction party can perform the construction task of the next stage only when the rechecking data is qualified, the correction task is issued again if the rechecking data is unqualified until the detection is qualified, and the construction party can perform the construction task of the next stage.

When the first time accumulated value is higher than the second time accumulated value, namely the actual construction speed is lower than an expected value, the possibility of construction delay delivery caused by too slow construction exists at the moment, the visitor should perform dynamic monitoring, the process is to perform absolute value processing on the difference value of the first time accumulated value and the second time accumulated value, and judge whether the absolute value result exceeds a second preset value.

The first preset value is a set value, and is set according to the characteristics of the construction project to indicate the allowed maximum delay period of the actual construction speed, and in the embodiment, the second preset value is 7 days, namely the allowed maximum delay period of the actual construction speed is 7 days.

And if the absolute value of the difference value between the first time accumulated value and the second time accumulated value is greater than the second preset value for 7 days, the supervision system sends a construction early warning instruction to a constructor task terminal, the constructor returns a reason analysis report according to the construction early warning instruction, the supervision system acquires construction historical data, analyzes whether the reason analysis report returned by the constructor is reliable or not, and corrects the time axis of the expected progress.

Specifically, a constructor acquires data such as constructor data, construction material data and construction weather data, judges whether the construction period belongs to a human factor or an uncontrollable factor, performs duty pursuit processing if the construction period belongs to the human factor or the uncontrollable factor, and corrects the time axis of the expected progress only if the construction period belongs to the uncontrollable factor.

And if the absolute value of the difference value between the first time accumulated value and the second time accumulated value is not more than the second preset value for 7 days, when a detection task node is reached, the monitoring platform sends a detection task to a detection mechanism task terminal, and after the data to be detected is qualified, a next-stage construction task is sent to a construction side task terminal until the construction is finished.

When the first time accumulated value is matched with the second time accumulated value, when the detection task node is reached, the monitoring platform sends a detection task to the detection mechanism task terminal, and after the data to be detected is qualified, the monitoring platform sends a next-stage construction task to the construction side task terminal until the construction is completed.

In summary, the embodiments of the present invention provide a new method and system for monitoring and supervising construction engineering quality, which implement dual monitoring of construction time and quality of a high-rise engineering, and a beneficiary can monitor construction progress and construction quality in real time through a terminal at any time, and can provide comprehensive, accurate, real-time and dynamic detection of the high-rise engineering quality. The problem that detection data deviate from the real situation to bring great hidden danger to the construction engineering quality is avoided.

Example 2, the invention was achieved by the following steps:

taking a road construction project as an example, a constructor inputs original data of constructors, a supervisory system generates an expected completion time axis according to the original project data, the specific process is that expected time data built to different lengths are extracted according to road length as marking data, and the expected completion time axis is established through the expected time data;

and extracting a key time node on an expected completion time axis to establish a detection task time node, wherein the detection task time node is a task node which needs quality detection when the construction period is normal, the supervisory system sends a detection task instruction to the detection mechanism according to the detection task time node, checks detection data returned by the detection mechanism, judges whether the detection data is qualified or not, if the detection data is qualified, carries out the next-stage construction task, if the detection data is unqualified, sends a task correcting instruction to a construction party, and issues a rechecking detection instruction to the detection mechanism until the correction is qualified.

The visitor can get into supervisory systems through the authentication of authority module identification module to can acquire construction progress real-time data, its construction progress real-time data is collected through the data acquisition module of predetermineeing in the job site, after the visitor acquires construction progress real-time data, generate the first time cumulative value, and extract the mark data in the real-time data collected and be floor height, confirm the corresponding time of the real-time progress of present stage on the time axis of expected completion according to the mark data, and generate the second mark time.

Sending out related task instructions by judging the magnitude relation between the first time accumulation value and the second time accumulation value and the absolute value difference value,

the specific process is that when the first time accumulated value is lower than the second time accumulated value, namely the actual construction speed is higher than an expected value, the possibility of quality reduction caused by over-high construction exists at the moment, the visitor should carry out dynamic monitoring, and the process is that the absolute value of the difference value of the first time accumulated value and the second time accumulated value is processed, and whether the absolute value result exceeds a first preset value is judged.

The first preset value is a set value, and is set according to the characteristics of the construction project, and represents the maximum safety advance of the actual construction speed, in this embodiment, the first preset value is 7 days, that is, the maximum safety advance of the actual construction speed is 7 days.

If the absolute value of the difference value between the first time accumulated value and the second time accumulated value is greater than the first preset value for 7 days, the visitor sends a self-checking task instruction to a task terminal of a construction party, the task terminal is mobile equipment or computer equipment, the construction party needs to return self-checking data through the task terminal within the time specified by the self-checking task instruction, and the supervision system judges whether the self-checking data is qualified or not and dispatches a specified task after acquiring the returned self-checking data.

Specifically, the monitoring system judges whether the returned self-checking data exceeds a threshold value, wherein the threshold value is a national specified construction standard value or is lower than a national standard value. The self-checking data comprises construction project detection data and construction site real-time environment data. If the self-checking data do not exceed the threshold, a rechecking task instruction is sent to a detection mechanism task terminal, the detection mechanism task terminal is mobile equipment or computer equipment, the detection mechanism needs to return the rechecking data through the task terminal within the time specified by the rechecking task instruction, the supervision system judges whether the returned rechecking data exceed the threshold, and only when the rechecking data are qualified, the construction party can perform the construction task of the next stage.

If the rechecking data returned by the detection mechanism exceeds a threshold value, the supervision system sends a rectification task instruction to the construction party, the construction party rectifies unqualified projects, the supervision system monitors according to the specified rectification task time, and if the task data after rectification is not returned in an overdue period, a promotion instruction is sent to the construction party.

Specifically, the supervision platform sends a rechecking task instruction to the detection mechanism after acquiring the correction data returned by the construction party, the detection mechanism needs to return the rechecking data through the task terminal within the time specified by the rechecking task instruction, the supervision system judges whether the returned rechecking data exceeds a threshold value, the construction party can carry out the construction task of the next stage only when the rechecking data is qualified, the correction task is issued again if the rechecking data is unqualified until the detection is qualified, and the construction party can carry out the construction task of the next stage.

When the first time accumulated value is higher than the second time accumulated value, namely the actual construction speed is lower than an expected value, the possibility of construction delay delivery caused by too slow construction exists at the moment, the visitor should perform dynamic monitoring, the process is to perform absolute value processing on the difference value of the first time accumulated value and the second time accumulated value, and judge whether the absolute value result exceeds a second preset value.

The first preset value is a set value, and is set according to the characteristics of the construction project, so that the maximum delay period allowed by the actual construction speed is represented, in the embodiment, the second preset value is 3 days, namely, the maximum delay period allowed by the actual construction speed is 3 days.

And if the absolute value of the difference value between the first time accumulated value and the second time accumulated value is greater than the second preset value for 3 days, the supervision system sends a construction early warning instruction to a constructor task terminal, the constructor returns a reason analysis report according to the construction early warning instruction, the supervision system acquires construction historical data, analyzes whether the reason analysis report returned by the constructor is reliable or not, and corrects the time axis of the expected progress.

Specifically, a constructor acquires data such as constructor data, construction material data and construction weather data, judges whether the construction period belongs to a human factor or an uncontrollable factor, performs duty pursuit processing if the construction period belongs to the human factor or the uncontrollable factor, and corrects the time axis of the expected progress only if the construction period belongs to the uncontrollable factor.

And if the absolute value of the difference value between the first time accumulated value and the second time accumulated value is not more than the second preset value for 3 days, when a detection task node is reached, the monitoring platform sends a detection task to a detection mechanism task terminal, and after the data to be detected is qualified, a next-stage construction task is sent to a construction side task terminal until the construction is completed.

When the first time accumulated value is matched with the second time accumulated value, when the detection task node is reached, the monitoring platform sends a detection task to the detection mechanism task terminal, and after the data to be detected is qualified, the monitoring platform sends a next-stage construction task to the construction side task terminal until the construction is completed.

In summary, the embodiment of the invention provides a new construction engineering quality detection and supervision method and system, which can realize double monitoring of the construction time and quality of road engineering, and a beneficiary can monitor the construction progress and the construction quality in real time through a terminal at any time, and can provide comprehensive, accurate, real-time and dynamic detection of the road engineering quality. The problem that detection data deviate from the real situation to bring great hidden danger to the construction engineering quality is avoided.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and substitutions can be made without departing from the technical principle of the present invention, and these modifications and substitutions should also be regarded as the protection scope of the present invention.

Claims (9)

1. A construction engineering quality detection and supervision method is characterized by comprising

Acquiring original data of a construction project, establishing an expected progress time axis and a detection task time node according to the original data, and sending a detection task instruction according to the detection task time node;

monitoring the construction progress in real time and acquiring real-time data of the construction progress; acquiring the real-time data of the construction progress and generating a first time accumulated value;

determining a corresponding point of the construction progress real-time data on the expected progress time axis, and generating a second time accumulated value;

acquiring a difference value between the first time accumulated value and the second time accumulated value, and judging whether the current construction progress conforms to an expected value or not according to the difference value result;

when the difference between the first time accumulated value and the second time accumulated value is obtained and whether the current construction progress accords with an expected value is judged according to the difference result, the method specifically comprises the following steps:

when the first time accumulated value is lower than the second time accumulated value, judging whether the absolute value of the difference value exceeds a first preset value;

if the absolute value is larger than the first preset value, sending a self-checking task instruction to a constructor task terminal;

if the absolute value is not greater than the first preset value, a rechecking task instruction is sent to a task terminal of the detection mechanism;

after the rechecking task instruction is sent to the detection mechanism task terminal, detection data uploaded by a detection mechanism are obtained, and if the detection data do not exceed a threshold value, a construction task instruction is given; if the detection data exceed the threshold value, a rectification task instruction is sent to a construction party, after rectification is completed, a rechecking task instruction is sent to the detection mechanism, and detection data are obtained until detection is qualified.

2. The construction engineering quality detection and supervision method according to claim 1, wherein the self-checking data uploaded by the construction party is acquired after a self-checking task instruction is sent to the construction party, if the self-checking data does not exceed a threshold value, a rechecking task instruction is sent to a detection mechanism task terminal and the detection data is acquired, if the detection data exceeds the threshold value, a renovating task instruction is sent to the construction party, and after the renovation is completed, a rechecking task instruction is sent to the detection mechanism and the detection data is acquired until the detection is qualified.

3. The construction engineering quality detection and supervision method according to claim 1, wherein when a difference between the first time cumulative value and the second time cumulative value is obtained, and whether the current construction progress meets an expected value is judged according to the difference result, specifically:

when the first time accumulated value is higher than the second time accumulated value, judging whether the absolute value result of the difference value exceeds a second preset value;

if the absolute value is larger than the second preset value, sending a progress early warning instruction to a constructor task terminal;

sending a reason query instruction to a construction party, acquiring construction history index data and construction expected data, performing reason query and correcting the time axis of the expected progress;

if the absolute value is not greater than the second preset value, sending a construction continuing instruction to a constructor;

and sending a reason query instruction to a constructor, acquiring construction history index data and construction expected data, performing reason query and correcting the time axis of the expected progress.

4. The construction engineering quality detection and supervision method according to claim 1, wherein when a difference between the first time cumulative value and the second time cumulative value is obtained, and whether the current construction progress meets an expected value is judged according to the difference result, specifically:

and if the first time accumulated value is the same as the second time accumulated value, sending a continuous construction instruction to a constructor, and when the detection task time node is reached, sending a detection task instruction to the constructor.

5. A construction engineering quality detection and supervision system adopting the method of any one of claims 1 to 4, characterized by comprising:

the data processing unit is used for acquiring construction project data and generating an expected progress time axis and a detection task time node;

the data acquisition unit is used for acquiring 24-hour data of a construction site; uploading the data to a data processing module;

a time stamp generating unit for generating a first time cumulative value and a second time cumulative value, and generating a difference value of the first time cumulative value and the second time cumulative value;

task terminal for receiving task book and uploading test data

The task processing unit is used for sending a related task instruction to the task terminal;

and the task monitoring unit is used for monitoring the time nodes of all the detection tasks, ensuring the construction progress of the detection tasks, sending task reminders to the detection mechanism according to the tasks in the expected time nodes, and monitoring according to the predicted task completion time of the detection mechanisms.

6. The construction project quality detection and supervision system according to claim 5, wherein the task processing unit includes:

a first acquisition module configured to acquire first time accumulated value data and second time accumulated value data, and acquire an absolute value of the difference;

and the first judging module is used for judging the magnitude relation between the first time accumulated value and the second time accumulated value and judging the magnitude relation between the absolute value result of the difference and a preset value.

7. The construction project quality detection and supervision system according to claim 6, wherein the task processing unit further includes:

a second obtaining module, configured to obtain the detection data uploaded by the task terminal

The second judgment module is used for judging whether the detection data exceeds a preset threshold value or not;

and the processing module is used for sending related task instructions based on the judgment results of the first judgment module and the second judgment module.

8. The construction project quality detection and supervision system according to claim 5, wherein the data acquisition unit includes:

the image acquisition module comprises a plurality of image acquisition devices and is used for acquiring 24-hour images of a construction site;

and the environment data acquisition module is used for collecting environment data of the construction site.

9. The construction engineering quality detection and supervision system according to claim 5, further comprising:

the authority identification unit is used for verifying the authority of the login user;

and the data storage unit is used for storing the detection data and the data sent by the data acquisition unit.

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