CN117745247B - Rock-soil construction wisdom building site system - Google Patents

Abstract

The invention relates to the technical field of intelligent construction sites, in particular to a rock-soil construction intelligent construction site system, which comprises: a personnel management subsystem for collecting and managing personnel information; the device management subsystem is used for collecting and managing device information; an environmental monitoring subsystem for monitoring environmental information; the vision screen monitoring subsystem is used for collecting image data of the geotechnical engineering construction site; the construction management subsystem is used for monitoring and managing construction progress in real time; the supervision center is used for supervising the data information of each subsystem and timely issuing project information and notification notices; the data center is used for collecting and storing data information of each subsystem and realizing information sharing between each subsystem and the supervision center; the user side is used for remotely checking the data information collected and stored by the data center. The invention can be applied to most geotechnical construction projects and has strong adaptability to geotechnical engineering construction projects.

Description

Rock-soil construction wisdom building site system

Technical Field

The invention relates to the technical field of intelligent construction sites, in particular to an intelligent construction site system for rock-soil construction.

Background

The intelligent construction site is used as an intelligent and digital construction engineering management method, and is a unified information platform built by integrating the technical means of cloud computing, big data, artificial intelligence, BIM and the like by taking the Internet of things technology as a core, so that the whole process management and intelligent management of the construction engineering site are realized. The current intelligent construction site management system is mainly managed in the whole construction process, has strong functions, is not strong in adaptability to different construction projects, is poor in universality, is opaque in construction information, and has little relation to geotechnical engineering construction.

On the one hand, the existing intelligent construction site system aiming at geotechnical engineering construction has the problems of disordered information management of construction sites, insufficient equipment monitoring, missing environment monitoring and the like. On the other hand, the existing intelligent construction site system for geotechnical engineering construction generally relies on methods such as expert evaluation and linear regression, however, the methods depend on historical data too, and the problems that the prediction process is complex, the variable site factors in the construction process are not considered and the like exist, so that larger prediction deviation exists, the reasonable construction plan is not conveniently formulated, and the construction quality and efficiency are restricted. Therefore, there is a need to develop a set of intelligent site systems for geotechnical engineering construction to solve the above problems, and promote intelligent development of geotechnical engineering construction management while providing more choices for selection of geotechnical engineering construction management systems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides an intelligent construction site system for rock-soil construction.

To achieve the above object, the present invention provides an intelligent geotechnical construction site system, comprising:

the personnel management subsystem is used for collecting and managing personnel information of the geotechnical engineering construction site;

The equipment management subsystem is used for collecting and managing equipment information of the geotechnical engineering construction site;

the environment monitoring subsystem is used for monitoring environment information of a geotechnical engineering construction site;

The visual screen monitoring subsystem is used for collecting image data of a geotechnical engineering construction site;

the construction management subsystem is used for monitoring and managing construction progress in real time and comprises a construction progress module, a planning management module and a construction management transmission module;

the construction progress module is used for collecting the actual construction progress of geotechnical engineering projects;

The plan management module is used for receiving the actual construction progress, comparing the actual construction progress with the plan construction progress to obtain construction deviation, and predicting the construction period by using a construction period prediction model, wherein the construction period prediction model meets the following relation:

，

Wherein, To predict construction period,/>To plan construction period,/>Is a comprehensive evaluation function of the influence of equipment state and environmental condition on the construction period,/>Is the actual construction progress of the ith sub-project in the geotechnical engineering project,/>For the planned construction progress of the ith sub-project in geotechnical engineering projects,/>Planned construction period for the ith sub-project in geotechnical engineering projects,/>Is an error factor;

The construction management transmission module is used for transmitting the actual construction progress, the construction deviation and the predicted construction period to a data center;

the monitoring center is used for monitoring the data information of each subsystem in real time and timely issuing project information and notification notices;

the data center is used for collecting and storing data information of each subsystem and realizing information sharing between each subsystem and the supervision center;

The user side is used for remotely checking the data information collected and stored by the data center.

The invention can be applied to most geotechnical construction projects and has strong adaptability to geotechnical engineering construction projects.

Optionally, the data center includes:

The data acquisition module is used for acquiring data information of the personnel management subsystem, the equipment management subsystem, the environment monitoring subsystem, the video monitoring subsystem and the construction management subsystem;

The storage module is used for storing the data information acquired by the data acquisition module;

and the data sharing module is used for sharing the data information in the storage module to the supervision center and the user side.

Furthermore, the real-time data information of the geotechnical engineering construction sites is uniformly stored, so that the implementation condition of the geotechnical engineering construction sites can be accurately mastered by related personnel.

Optionally, the data center further includes an interface module, the interface module including:

The first file interface module is used for realizing information transmission among the data acquisition module, the personnel management subsystem, the equipment management subsystem, the environment monitoring subsystem, the video monitoring subsystem and the construction management subsystem by utilizing the Internet of things;

The second file interface module is used for realizing information transmission between the data sharing module and the supervision center by utilizing the Internet of things;

And the user interface realizes information transmission between the data sharing module and the user terminal by utilizing the Internet of things.

Furthermore, different interface modules are used for receiving or transmitting data, so that the information transmission efficiency can be improved, and the real-time response capability of the system is enhanced.

Optionally, the personnel management subsystem includes:

the personnel basic information module is used for collecting personnel basic information of a geotechnical engineering construction site;

The personnel attendance module is used for collecting personnel attendance conditions of geotechnical engineering construction sites;

And the personnel information transmission module is used for transmitting the personnel basic information and the personnel attendance to the data center.

Furthermore, the module for collecting the basic information of the personnel, checking in the personnel and transmitting the information is helpful for comprehensively knowing and managing the personnel information of the construction site, and basic data support is provided for guaranteeing the personnel safety, improving the working efficiency and the like.

Optionally, the device management subsystem includes:

the equipment foundation information module is used for collecting equipment foundation information of each construction equipment in the geotechnical engineering construction site;

the equipment positioning device is used for collecting real-time positions of all construction equipment in the geotechnical engineering construction site;

And the equipment information transmission module is used for transmitting the equipment basic information and the real-time position corresponding to the equipment basic information to the data center.

Further, the equipment management subsystem realizes comprehensive monitoring and management of construction equipment, which is helpful for ensuring normal operation of the equipment, improving the service efficiency of the equipment and reducing unnecessary maintenance cost.

Optionally, the environment monitoring subsystem includes:

the dust monitoring module is used for monitoring dust concentration in a geotechnical engineering construction site;

the noise monitoring module is used for monitoring the noise level in the geotechnical engineering construction site;

The weather monitoring module is used for monitoring the temperature, the humidity, the wind speed and the wind direction in the geotechnical engineering construction site;

The environment data transmission module is used for transmitting the data monitored by the dust monitoring module, the noise monitoring module and the weather monitoring module to the data center.

Furthermore, the environment of the construction site is monitored in real time through the environment monitoring subsystem, so that related personnel can master the real-time environment condition of the construction site, potential environmental problems can be prevented, and the construction safety is improved.

Optionally, the video monitoring subsystem includes:

the field image acquisition module is used for acquiring real-time image data of a geotechnical engineering construction field;

the image data transmission module is used for receiving the image data in real time and transmitting the image data to the data center in real time.

Furthermore, the video monitoring subsystem provides visual and real-time site pictures for remote supervision by collecting and transmitting image data in real time, thereby enhancing the supervision effectiveness and reducing the requirement of site patrol.

Optionally, the supervision center includes:

the remote monitoring center is used for monitoring and managing the data information collected by the data center in real time and timely issuing project information and notification notices;

And the on-site supervision center is used for displaying the data information, the project information and the notification notices collected by the data center in the geotechnical engineering construction site.

Furthermore, the supervision center can realize double supervision of remote and on-site, and can timely issue project information and notification notices, thereby enhancing the comprehensiveness and flexibility of supervision and ensuring the timeliness and accuracy of information.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of a frame of an intelligent construction site system for geotechnical construction according to an embodiment of the present invention.

Detailed Description

Specific embodiments of the invention will be described in detail below, it being noted that the embodiments described herein are for illustration only and are not intended to limit the invention. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be apparent to one of ordinary skill in the art that: no such specific details are necessary to practice the invention. In other instances, well-known circuits, software, or methods have not been described in detail in order not to obscure the invention.

Throughout the specification, references to "one embodiment," "an embodiment," "one example," or "an example" mean: a particular feature, structure, or characteristic described in connection with the embodiment or example is included within at least one embodiment of the invention. Thus, the appearances of the phrases "in one embodiment," "in an embodiment," "one example," or "an example" in various places throughout this specification are not necessarily all referring to the same embodiment or example. Furthermore, the particular features, structures, or characteristics may be combined in any suitable combination and/or sub-combination in one or more embodiments or examples. Moreover, those of ordinary skill in the art will appreciate that the illustrations provided herein are for illustrative purposes and that the illustrations are not necessarily drawn to scale.

It should be noted in advance that in an alternative embodiment, the same symbols or alphabet meaning and number are the same as those present in all formulas, except where separate descriptions are made.

In an alternative embodiment, referring to fig. 1, the present invention provides a smart construction site system for geotechnical construction, which includes a personnel management subsystem A1, a device management subsystem A2, an environment monitoring subsystem A3, a video monitoring subsystem A4, a construction management subsystem A5, a supervision center A6, a data center A7 and a user terminal A8.

Specifically, in this embodiment, the personnel management subsystem A1 is configured to collect and manage personnel information of a geotechnical engineering construction site; the equipment management subsystem A2 is used for collecting and managing equipment information of a geotechnical engineering construction site; the environment monitoring subsystem A3 is used for monitoring environment information of a geotechnical engineering construction site; the vision screen monitoring subsystem A4 is used for collecting image data of a geotechnical engineering construction site; the construction management subsystem A5 is used for monitoring and managing construction progress in real time; the supervision center A6 is used for carrying out real-time supervision on the data information of the personnel management subsystem A1, the equipment management subsystem A2, the environment monitoring subsystem A3, the video monitoring subsystem A4 and the construction management subsystem A5, and timely issuing project information and notification notices; the data center A7 is configured to collect and store data information of the personnel management subsystem A1, the equipment management subsystem A2, the environment monitoring subsystem A3, the video monitoring subsystem A4, and the construction management subsystem A5, and implement information sharing among the personnel management subsystem A1, the equipment management subsystem A2, the environment monitoring subsystem A3, the video monitoring subsystem A4, the construction management subsystem A5, and the supervision center A6; the user terminal A8 is configured to remotely view the data information collected and stored by the data center A7.

Specifically, in this embodiment, the personnel management subsystem A1 includes a personnel basic information module, a personnel attendance module and a personnel information transmission module. The personnel basic information module is used for collecting personnel basic information of a geotechnical engineering construction site; the personnel attendance module is used for collecting personnel attendance conditions of geotechnical engineering construction sites; the personnel information transmission module is used for transmitting the personnel basic information and the personnel attendance situation to the data center A7 through the Internet of things.

Further, the staff of geotechnical engineering project need register on the personnel basic information module in order to use the personnel attendance module. The personnel basic information module comprises a first display screen, the first display screen at least comprises two buttons of member registration and daily card punching, a worker registers on the personnel basic information module, namely clicks the member registration on the display screen, and then pops up an information acquisition page on the display screen, wherein the information acquisition page comprises an information acquisition table and a submit button. When the staff does not fill in the information acquisition table completely, the submit button is in a non-clickable state. After the staff inputs complete basic information of the staff, the submitting button can be clicked, then the basic information of the staff is transmitted to the data center A7 to be stored through the basic information of the staff module, thus the registration is completed, and the display screen automatically returns to the original page. The personnel basic information comprises the contents of name, age, sex, identification card number, home address, responsible item and the like.

Furthermore, the personnel attendance module and the personnel basic information module share a first display screen, the card punching process is similar to the registering process, after the personnel completes registering on the personnel basic information module, the personnel attendance module can transmit the name and the card punching time of the personnel to the data center A7 through the personnel information transmission module for storage by clicking a daily card punching button and filling in and submitting own name in a popped page.

Furthermore, the module for collecting the basic information of the personnel, checking in the personnel and transmitting the information is helpful for comprehensively knowing and managing the personnel information of the construction site, and basic data support is provided for guaranteeing the personnel safety, improving the working efficiency and the like.

Specifically, in this embodiment, the device management subsystem A2 includes a device basic information module, a device positioning device, and a device information transmission module. The equipment foundation information module is used for collecting equipment foundation information of each construction equipment in the geotechnical engineering construction site; the equipment positioning device is used for collecting real-time positions of all construction equipment in the geotechnical engineering construction site; the equipment information transmission module is used for transmitting the equipment basic information and the real-time position corresponding to the equipment basic information to the data center. The equipment management subsystem A2 realizes comprehensive monitoring and management of construction equipment, which is helpful for ensuring normal operation of the equipment, improving the service efficiency of the equipment and reducing unnecessary maintenance cost.

More specifically, the device basic information collected by the device basic information module includes a device name, a device number, a device source, a working time length and a health state, and the health state includes two states which can be normally operated and to be repaired. The equipment basic information module comprises at least one second display screen, the staff inputs equipment basic information on the second display screen, and then the equipment basic information module transmits the equipment basic information to the data center A7 through the equipment information transmission module for storage.

Furthermore, the equipment basic information module establishes an equipment information acquisition table by utilizing equipment numbers, and the equipment names, the equipment numbers and the equipment sources of each construction equipment are in one-to-one correspondence, so that the equipment names, the equipment numbers and the equipment sources of the construction equipment are only required to be input once, and then staff only need to fill in the working time and the health state of each construction equipment on the equipment information acquisition table every day. After filling and confirming, the staff clicks the submit button on the second display screen.

Furthermore, the device positioning device selects a vehicle-mounted GPS (global positioning system) positioner, and the specific model of the vehicle-mounted GPS positioner can be selected according to actual conditions. The equipment positioning device transmits the acquired real-time position to the data center A7 through the equipment information transmission module for storage.

Specifically, in this embodiment, the environment monitoring subsystem A3 includes a dust monitoring module, a noise monitoring module, a weather monitoring module, and an environment data transmission module. The dust monitoring module is used for monitoring dust concentration in a geotechnical engineering construction site; the noise monitoring module is used for monitoring the noise level in the geotechnical engineering construction site; the meteorological monitoring module is used for monitoring the temperature, the humidity, the wind speed and the wind direction in the geotechnical engineering construction site; the environment data transmission module is used for transmitting the data monitored by the dust monitoring module, the noise monitoring module and the weather monitoring module to the data center. In other alternative embodiments, the environmental monitoring subsystem A3 may also include a module that detects other environmental data information.

Further, the environment monitoring subsystem A3 adopts a pumping type dust on-line monitor, and comprises a dust monitoring module, a noise monitoring module and a weather monitoring module, so that 24-hour monitoring on PM2.5 concentration, PM10 concentration, noise size, temperature, humidity, wind speed and wind direction can be realized, the PM2.5 concentration, PM10 concentration, noise size, temperature, humidity, wind speed and wind direction collected by the environment data transmission module are transmitted to the environment data transmission module through a data line, and then the environment data transmission module can transmit the PM2.5 concentration, PM10 concentration, noise size, temperature, humidity, wind speed and wind direction to the data center A7 by utilizing the Internet of things for storage. The environment of the construction site is monitored in real time through the environment monitoring subsystem A3, so that related personnel can master the real-time environment condition of the construction site, potential environmental problems can be prevented, and the construction safety is improved.

Specifically, in this embodiment, the video monitoring subsystem A4 includes a field image acquisition module and an image data transmission module. The field image acquisition module is used for acquiring real-time image data of a geotechnical engineering construction field; the image data transmission module is used for receiving the image data in real time and transmitting the image data to the data center in real time.

Further, the site image acquisition module comprises a plurality of cameras which are distributed at different sites in the construction site to acquire real-time image data of the geotechnical engineering construction site, and the acquired image data is transmitted to the data center A7 in real time through the image data transmission module. The video monitoring subsystem provides visual and real-time site pictures for remote supervision by collecting and transmitting image data in real time, thereby enhancing the supervision effectiveness and reducing the requirement of site patrol.

Furthermore, the types and the number of the cameras can be selected by the staff according to actual needs, and the camera is not limited.

Specifically, in this embodiment, the construction management subsystem A5 includes a construction progress module, a plan management module, and a construction management transmission module. The construction progress module is used for collecting the actual construction progress of geotechnical engineering projects; the plan management module is used for receiving the actual construction progress, comparing the actual construction progress with the plan construction progress to obtain construction deviation, and predicting the construction period by using a construction period prediction model; the construction management transmission module is used for transmitting the actual construction progress, the construction deviation and the predicted construction period to the data center.

More specifically, the construction progress module comprises a third display screen, a worker inputs actual construction progress of each sub-item of the geotechnical engineering project on the third display screen, the actual construction progress is a percentage, then the plan management module compares the actual construction progress with the set plan construction progress to obtain construction deviation, and the data collected by the equipment management subsystem A2 and the environment monitoring subsystem A3 in the data center A7 are called to make predictions on the construction period by using a construction period prediction model, and the construction period prediction model meets the following relation:

Wherein, To predict construction period,/>To plan construction period,/>Is a comprehensive evaluation function of the influence of equipment state and environmental condition on the construction period,/>Is the actual construction progress of the ith sub-project in the geotechnical engineering project,/>For the planned construction progress of the ith sub-project in geotechnical engineering projects,/>Planned construction period for the ith sub-project in geotechnical engineering projects,/>Is an error factor. The planned construction progress is the ratio of the current construction days to the planned construction period,/>According to experience, 0.5,/>, is takenNamely construction deviation.

Further, comprehensive evaluation function calculation indexes including first to sixth indexes are obtained. The method comprises the steps of starting construction to the current moment, wherein the first index is the ratio of the number of times that construction equipment can normally run to the number of times to be repaired in a sub project, the second index is one half of the difference between the maximum value and the minimum value of PM2.5 concentration and the difference between the maximum value and the minimum value of PM10 concentration, the third index is one half of the difference between the maximum value and the minimum value of noise level, the fourth index is one half of the difference between the maximum value and the minimum value of temperature, the fifth index is one half of the difference between the maximum value and the minimum value of humidity, and the sixth index is one half of the difference between the maximum value and the minimum value of wind speed. And then carrying out normalization processing on the comprehensive evaluation function calculation indexes to sequentially obtain 6 normalization calculation indexes, wherein the normalization of the comprehensive evaluation function calculation indexes can be referred to the prior art.The following relation is specifically satisfied:

Wherein, Calculating index for mth normalization,/>，/>Calculating index weight of index for j-th comprehensive evaluation function,/>Obtained by expert evaluation method,/>。

The construction period prediction model considers factors which possibly affect the construction period in various construction processes, ensures the accuracy of prediction while being simple in calculation, is beneficial to taking countermeasure measures in advance to ensure the on-time completion of geotechnical engineering projects, and improves the universality of the system.

Specifically, in this embodiment, the data center A7 includes a data acquisition module, a storage module, a data sharing module, and an interface module. The data acquisition module is used for acquiring data information of the personnel management subsystem, the equipment management subsystem, the environment monitoring subsystem, the video monitoring subsystem and the construction management subsystem; the storage module is used for storing the data information acquired by the data acquisition module; the data sharing module is used for sharing the data information in the storage module to the supervision center and the user side.

More specifically, the interface module includes a first file interface module, a second file interface module, and a user interface module. The first file interface realizes information transmission between the data acquisition module and each subsystem by utilizing the Internet of things; the second file interface module utilizes the Internet of things to realize information transmission between the data sharing module and the supervision center A6; and the user interface realizes information transmission between the data sharing module and the user side A8 by utilizing the Internet of things.

Further, the first file interface module may be part of a data acquisition module and the second file interface module and the user interface module may be part of a data sharing module.

Furthermore, the data center A7 stores the real-time data information of the geotechnical engineering construction sites uniformly, so that the related personnel can accurately grasp the implementation condition of the geotechnical engineering construction sites. And the data is received or transmitted by using different interface modules, so that the information transmission efficiency can be improved, and the real-time response capability of the system can be enhanced.

Specifically, in this embodiment, the supervision center A6 includes a remote supervision center and a field supervision center. The remote supervision center is used for monitoring and managing the data information collected by the data center in real time and timely issuing project information and notification notices; the on-site supervision center is used for displaying data information, project information and notification notices collected by the data center in a geotechnical engineering construction site. The supervision center can realize remote and on-site double supervision, and can timely issue project information and notification notices, thereby enhancing the comprehensiveness and flexibility of supervision and ensuring the timeliness and accuracy of information.

More specifically, the remote supervision center comprises a fourth display screen, the on-site supervision center comprises a fifth display screen, the fourth display screen and the fifth display screen display device management subsystem A2, the environment monitoring subsystem A3, the view screen monitoring subsystem A4 and the construction management subsystem A5, and data information and project information collected in real time are convenient for staff to know geotechnical engineering projects and to master the actual conditions of construction sites in real time and accurately.

Furthermore, through the data sharing module and the second file interface module, the remote supervision center can query the latest data and the historical data in the data center A7 in real time, delete the historical data which are relatively long in the data center A7, and release the storage space in the data center A7. The manager can accurately grasp the actual situation of the construction site in real time and supervise the construction site by looking at the latest data in the data center A7. And the manager timely adjusts the construction plan by checking data information such as actual construction progress, construction deviation, predicted construction period and the like on a fourth display screen, and issues related notification notices on a remote supervision center, wherein the notification notices sent by the manager are displayed on the field supervision center for being checked by staff in the geotechnical engineering construction site.

Specifically, in this embodiment, the user side A8 includes a mobile device and a user side app, and a worker may log in to the user side app and view data in the data center A7 using a name and an id card used on the person management subsystem A1.

It should be noted that, in some cases, the actions described in the specification may be performed in a different order and still achieve desirable results, and in this embodiment, the order of steps is merely provided to make the embodiment more clear, and it is convenient to describe the embodiment without limiting it.

In summary, the system provided by the invention uses the personnel management subsystem, the equipment management subsystem, the environment monitoring subsystem, the video monitoring subsystem and the construction management subsystem to realize real-time acquisition of personnel information, equipment information, environment information, construction site information and construction progress information, and uniformly stores the information in the data center, related personnel can monitor the data information in real time through the monitoring center, and can remotely check the data information by using a user side, so that related personnel can accurately grasp the actual condition of the construction site in real time and monitor the construction site, the problems of disordered information management, insufficient equipment monitoring, missing environment monitoring and the like of the geotechnical engineering construction site are solved, reasonable construction plans are formulated, and the construction quality and efficiency are improved. In addition, the construction period prediction model introduced in the construction management subsystem considers factors which possibly affect the construction period in various construction processes, and ensures the accuracy of prediction while being simple in calculation, so that reasonable construction plans can be formulated, and the construction quality and efficiency can be improved.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention, and are intended to be included within the scope of the appended claims and description.

Claims (1)

1. An intelligent rock-soil construction site system, which is characterized by comprising:

the personnel management subsystem is used for collecting and managing personnel information of the geotechnical engineering construction site and comprises a personnel basic information module, a personnel attendance module and a personnel information transmission module;

the personnel basic information module is used for collecting personnel basic information of a geotechnical engineering construction site;

The personnel attendance module is used for collecting personnel attendance conditions of geotechnical engineering construction sites;

The personnel information transmission module is used for transmitting the personnel basic information and the personnel attendance to a data center;

The equipment management subsystem is used for collecting and managing equipment information of the geotechnical engineering construction site and comprises an equipment basic information module, an equipment positioning device and an equipment information transmission module;

The equipment foundation information module is used for collecting equipment foundation information of each construction equipment in the geotechnical engineering construction site;

the equipment positioning device is used for collecting real-time positions of all construction equipment in the geotechnical engineering construction site;

The equipment information transmission module is used for transmitting the equipment basic information and the real-time position corresponding to the equipment basic information to a data center;

The environment monitoring subsystem is used for monitoring environment information of a geotechnical engineering construction site and comprises a dust monitoring module, a noise monitoring module, a meteorological monitoring module and an environment data transmission module;

The dust monitoring module is used for monitoring dust concentration in a geotechnical engineering construction site;

the noise monitoring module is used for monitoring the noise level in the geotechnical engineering construction site;

The meteorological monitoring module is used for monitoring the temperature, the humidity, the wind speed and the wind direction in the geotechnical engineering construction site;

The environment data transmission module is used for transmitting the data monitored by the dust monitoring module, the noise monitoring module and the weather monitoring module to a data center;

the visual screen monitoring subsystem is used for acquiring image data of a geotechnical engineering construction site and comprises a site image acquisition module and an image data transmission module;

the field image acquisition module is used for acquiring real-time image data of a geotechnical engineering construction field;

the image data transmission module is used for receiving the image data in real time and transmitting the image data to a data center in real time;

the construction management subsystem is used for monitoring and managing construction progress in real time and comprises a construction progress module, a planning management module and a construction management transmission module;

the construction progress module is used for collecting the actual construction progress of geotechnical engineering projects;

The plan management module is used for receiving the actual construction progress, comparing the actual construction progress with the plan construction progress to obtain construction deviation, and predicting the construction period by using a construction period prediction model, wherein the construction period prediction model meets the following relation:

，

Wherein, To predict construction period,/>To plan construction period,/>Is a comprehensive evaluation function of the influence of equipment state and environmental condition on the construction period,/>Is the actual construction progress of the ith sub-project in the geotechnical engineering project,/>For the planned construction progress of the ith sub-project in geotechnical engineering projects,/>Planned construction period for the ith sub-project in geotechnical engineering projects,/>Is an error factor,/>The following relation is specifically satisfied:

Wherein, Calculating index for mth normalization,/>，/>Calculating index weight of the index for the j-th comprehensive evaluation function;

The construction management transmission module is used for transmitting the actual construction progress, the construction deviation and the predicted construction period to a data center;

the monitoring center is used for monitoring the data information of each subsystem in real time and timely issuing project information and notification notices, and comprises a remote monitoring center and a field monitoring center;

the remote supervision center is used for monitoring and managing the data information collected by the data center in real time and timely issuing project information and notification notices;

the on-site supervision center is used for displaying data information, project information and notification notices collected by the data center in the geotechnical engineering construction site;

the data center is used for collecting and storing data information of each subsystem and realizing information sharing between each subsystem and the supervision center, and comprises a data collecting module, a storage module, a data sharing module and an interface module, wherein the interface module comprises a first file interface module, a second file interface module and a user interface module;

the data acquisition module is used for acquiring data information of the personnel management subsystem, the equipment management subsystem, the environment monitoring subsystem, the video monitoring subsystem and the construction management subsystem;

the storage module is used for storing the data information acquired by the data acquisition module;

the data sharing module is used for sharing the data information in the storage module to the supervision center and the user side;

The first file interface utilizes the Internet of things to realize information transmission among the data acquisition module, the personnel management subsystem, the equipment management subsystem, the environment monitoring subsystem, the video monitoring subsystem and the construction management subsystem;

The second file interface module utilizes the Internet of things to realize information transmission between the data sharing module and the supervision center;

the user interface realizes information transmission between the data sharing module and the user terminal by utilizing the Internet of things;

The user side is used for remotely checking the data information collected and stored by the data center.