CN113110178A

CN113110178A - Construction site monitoring method and system based on Internet

Info

Publication number: CN113110178A
Application number: CN202110408714.6A
Authority: CN
Inventors: 聂华明; 丁勇俊; 陈志恒; 徐健; 赵丝嘉
Original assignee: Shenzhen Essex Technology Co ltd
Current assignee: Shenzhen Essex Technology Co ltd
Priority date: 2021-04-16
Filing date: 2021-04-16
Publication date: 2021-07-13

Abstract

The invention relates to the technical field of Internet, and discloses a construction site monitoring method and a construction site monitoring system based on the Internet, wherein the method comprises the following steps: acquiring equipment parameters, environment parameters and life body state parameters from scene parameters of a construction site scene; respectively updating corresponding model components in a preset construction site model according to the equipment parameters, the environment parameters and the life body state parameters to obtain updated model components; and when the scene parameters meet preset abnormal conditions, executing a corresponding warning strategy on the construction site scene based on the updated model component. The construction site monitoring system has the advantages that the completeness and the display effect when the scene parameters of the construction site are displayed are improved by setting the preset construction site model, corresponding model assemblies in the preset construction site model are respectively updated according to the acquired equipment parameters, environmental parameters and life state parameters, the construction site is intelligently and centrally monitored based on the updated model assemblies, the safety of the construction site is improved, and potential safety hazards are avoided.

Description

Construction site monitoring method and system based on Internet

Technical Field

The invention relates to the technical field of internet, in particular to a construction site monitoring method and system based on the internet.

Background

Traditional job site relies on manual scheduling and monitoring mostly to get rid of partial potential safety hazard, but along with social economy and building technology's development, the scale and the complexity of building site increase rapidly, the manual work is monitored the construction condition and has been unable effectively to guarantee construction standard and safety, therefore, in order to improve the control dynamics, construction site among the prior art mostly adopts a plurality of surveillance cameras to monitor the construction condition, the picture that a plurality of surveillance cameras were shot is concentrated in the list of monitor or a plurality of screens and is shown, the monitoring staff can comparatively grasp the real-time operating mode of job site rapidly through the observation and the affirmation to different pictures. However, the problem of a blind area of a visual field cannot be avoided in a monitoring picture acquired by the existing monitoring camera, the integrity of image information acquisition cannot be guaranteed, and potential safety hazards still exist. Meanwhile, because monitoring workers need to constantly switch the visual angles in a plurality of monitoring pictures, fatigue is easily caused, and certain important information is missed by the monitoring workers when the states are not good. In addition, no system integrating production monitoring, safety guarantee and other subsystems in the construction process of a construction site is integrated and matched with each other in the existing market, so how to intelligently and intensively monitor the construction site to improve the safety of the construction site and avoid potential safety hazards becomes a problem to be solved urgently.

The above is only for the purpose of assisting understanding of the technical aspects of the present invention, and does not represent an admission that the above is prior art.

Disclosure of Invention

The invention mainly aims to provide a construction site monitoring method and system based on the Internet, and aims to solve the technical problems of how to intelligently and centrally monitor a construction site so as to improve the safety of the construction site and avoid potential safety hazards.

In order to achieve the above object, the present invention provides an internet-based worksite monitoring method, comprising the steps of:

acquiring scene parameters of a construction site scene, and classifying the scene parameters to acquire class labels of the scene parameters;

acquiring equipment parameters, environment parameters and life body state parameters from the scene parameters according to the category labels;

respectively updating corresponding model components in a preset construction site model according to the equipment parameters, the environment parameters and the life body state parameters to obtain updated model components;

and when the scene parameters meet preset abnormal conditions, executing a corresponding warning strategy on the construction site scene based on the updated model component.

Optionally, before the step of updating the corresponding model components in the preset construction site model according to the device parameters, the environment parameters, and the living body state parameters, and obtaining updated model components, the method further includes:

performing live view scanning of a worksite scene to obtain co-planar image data and non-co-planar image data;

drawing a corresponding model component according to the coplanar image data and the non-coplanar image data;

and performing effect processing on the model assembly to obtain a preset construction site model, and updating the preset construction site model according to a preset period.

Optionally, the step of respectively updating corresponding model components in a preset construction site model according to the device parameters, the environment parameters, and the living body state parameters to obtain updated model components specifically includes:

embedding the equipment parameters into corresponding equipment model components in a preset construction site model to obtain updated equipment model components;

rendering the corresponding building site area component in the preset building site model according to the environment parameters to obtain an updated building site area component;

tracking and marking the life body state parameter to a corresponding life body model component in the preset construction site model to obtain an updated life body model component;

taking the updated equipment model component, the updated worksite area component and the updated animate body model component as updated model components.

Optionally, the step of executing a corresponding warning strategy for the worksite scene based on the updated model component when the scene parameter meets a preset abnormal condition specifically includes:

when the equipment parameters in the scene parameters meet preset abnormal conditions, highlighting a target equipment model component corresponding to target operation equipment with abnormal equipment parameters in the updated equipment model component, and displaying a real scene monitoring picture corresponding to the target operation equipment;

detecting whether associated running equipment with an association relation with the target running equipment exists or not according to the updated equipment model component;

when the associated equipment exists, sending out corresponding warning information based on the target running equipment and the associated running equipment;

and when the associated equipment does not exist, sending corresponding warning information based on the target operation equipment.

when the environmental parameters in the scene parameters meet preset abnormal conditions, analyzing the area influence range of the environmental parameters according to the updated construction site area components;

and positioning a corresponding construction site area in the construction site scene according to the area influence range, and sending corresponding warning information to the construction site area.

when the life body state parameters in the scene parameters meet preset abnormal conditions, highlighting a target life body model component corresponding to a target marked life body with abnormal life body state parameters in the updated life body model component, and sending corresponding warning information to the target marked life body;

recording the abnormal life body duration that the life body state parameter of the target life body meets the preset abnormal condition, and judging whether the abnormal life body duration exceeds a preset duration threshold value;

and when the abnormal time length of the life body exceeds a preset time length threshold value, searching an adjacent life body in the preset position range of the target mark life body according to the updated life body model component, and sending corresponding warning information to the adjacent life body.

respectively acquiring parameter ranges corresponding to various parameters in the scene parameters according to the category labels;

when any one of the scene parameters is not within the corresponding parameter range, executing a corresponding warning strategy on the construction site scene based on the updated model component;

or respectively acquiring parameter change rules corresponding to various parameters in the scene parameters according to the category labels;

and when any one of the scene parameters does not accord with the corresponding parameter change rule, executing a corresponding warning strategy on the construction site scene based on the updated model component.

In addition, to achieve the above object, the present invention further provides an internet-based worksite monitoring system, including:

the parameter classification module is used for acquiring scene parameters of a construction site scene, classifying the scene parameters and acquiring class labels of the scene parameters;

the parameter extraction module is used for acquiring equipment parameters, environment parameters and life body state parameters from the scene parameters according to the category labels;

the component updating module is used for respectively updating corresponding model components in a preset construction site model according to the equipment parameters, the environment parameters and the life body state parameters to obtain updated model components;

and the abnormity monitoring module is used for executing a corresponding warning strategy on the construction site scene based on the updated model component when the scene parameters meet preset abnormity conditions.

The internet-based worksite monitoring system further comprises:

a model construction module for live-action scanning of a worksite scene to obtain co-planar image data and non-co-planar image data;

the model construction module is also used for drawing a corresponding model component according to the coplanar image data and the non-coplanar image data;

the model building module is also used for carrying out preset effect processing on the model assembly to obtain a preset construction site model, and updating the preset construction site model according to a preset period.

The component updating module is further used for embedding the equipment parameters into corresponding equipment model components in a preset construction site model so as to obtain updated equipment model components;

the component updating module is further used for rendering the corresponding building site area component in the preset building site model according to the environment parameters so as to obtain an updated building site area component;

the component updating module is further used for tracking and marking the life body state parameters to corresponding life body model components in the preset construction site model so as to obtain updated life body model components;

the component update module is further configured to take the updated equipment model component, the updated worksite area component, and the updated animate body model component as updated model components.

In the invention, scene parameters of a construction site scene are obtained, and the scene parameters are classified to obtain class labels of the scene parameters; acquiring equipment parameters, environment parameters and life body state parameters from the scene parameters according to the category labels; respectively updating corresponding model components in a preset construction site model according to the equipment parameters, the environment parameters and the life body state parameters to obtain updated model components; and when the scene parameters meet preset abnormal conditions, executing a corresponding warning strategy on the construction site scene based on the updated model component. Compared with the prior art that the problem of blind areas of the vision field cannot be avoided when a monitoring picture acquired by a monitoring camera monitors a construction site, the integrity of the acquired image information cannot be ensured, and the potential safety hazard caused by distraction of monitoring workers cannot be avoided in the prior art, the method and the system improve the integrity and the display effect when the scene parameters of the construction site are displayed by setting the preset construction site model, respectively update the corresponding model components in the preset construction site model according to the acquired equipment parameters, environmental parameters and life state parameters, and intelligently and centrally monitor the construction site based on the jointly updated model components, thereby improving the safety of the construction site and avoiding the potential safety hazard.

Drawings

FIG. 1 is a schematic flow chart of a first embodiment of an Internet-based worksite monitoring method of the present invention;

FIG. 2 is a schematic flow chart of a second embodiment of the Internet-based worksite monitoring method of the present invention;

FIG. 3 is a schematic flow chart of a third embodiment of the Internet-based worksite monitoring method of the present invention;

FIG. 4 is a block diagram of a first embodiment of the Internet-based worksite monitoring system of the present invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The embodiment of the invention provides an internet-based construction site monitoring method, and referring to fig. 1, fig. 1 is a flow diagram of a first embodiment of the internet-based construction site monitoring method.

In this embodiment, the internet-based construction site monitoring method includes the following steps:

step S10: acquiring scene parameters of a construction site scene, and classifying the scene parameters to acquire class labels of the scene parameters;

step S20: acquiring equipment parameters, environment parameters and life body state parameters from the scene parameters according to the category labels;

it is easy to understand that, in order to improve the monitoring precision of the construction site, the scene parameters of the construction site scene (i.e. the site to be constructed) can be obtained first, and the scene parameters are classified to obtain the category labels of the scene parameters, and then the device parameters, the environment parameters and the life state parameters are obtained from the scene parameters according to the category labels, the scene parameters can be understood as the parameters obtained from various sensors of the construction site, and in the specific implementation, the sensors (such as a rotating speed sensor, a power sensor and the like) which are installed on the video monitoring of the construction site, the construction site devices (such as a mixing plant, a tower crane, a bulldozer, a material hoist and the like) and are used for detecting the operation state of the construction site devices in real time, the sensors (such as a body temperature sensor, a body condition monitoring sensor, a body temperature, Pulse sensor, etc.), the sensor (temperature sensor, humidity sensor, etc.) that is used for monitoring the construction environment that the job site was installed, etc. the data that transmit are obtained, then, classify the environmental parameter who obtains to obtain the classification label that the scene parameter corresponds, further, in order to reduce data interference, improve data purity, so that improve building site monitoring precision, can follow according to classification label required equipment parameter, environmental parameter and life form parameter are drawed from the scene parameter, so as to reduce data processing volume, improve data processing efficiency. Wherein the category label may be understood as a label established according to a category of a model component (e.g., an equipment model component, a worksite area component, a life body model component, etc.) for facilitating a subsequent modeling process, the equipment parameter may be understood as a parameter for representing a real-time operation state of a worksite equipment of a construction site and converted into a parameter of the equipment model component for facilitating an input into the model component, the environment parameter may be understood as a parameter for representing a real-time environment condition of the construction site and converted into a parameter of the worksite area model component for facilitating an input into the model component, the life body state parameter may be understood as a parameter for representing a real-time body state of a worker of the construction site and converted into a parameter of the life body model component for facilitating an input into the model component, the conversion may be understood as a label established according to a category of the parameter supported by the model component, The unit, format, and the like are subjected to a standardized conversion process.

Step S30: respectively updating corresponding model components in a preset construction site model according to the equipment parameters, the environment parameters and the life body state parameters to obtain updated model components;

it should be noted that after the device parameters, the environment parameters, and the life body state parameters are obtained, the device parameters may be input to a corresponding device model component in a preset construction site model to update the device model component, so as to obtain an updated device model component, where the device model component may be understood as a model component drawn according to construction site equipment of a construction site; the environment parameters can be input into corresponding building site area model components in a preset building site model to update the building site area components, so as to obtain updated building site area components, wherein the building site area components can be understood as model components drawn according to the influence degree and the influence range of the environment parameters on a building site area (which can be understood as an area needing monitoring and divided according to actual requirements in a construction site); the life body state parameters can be input into corresponding life body model components in a preset construction site model to update the life body model components to obtain updated life body model components, the life body model components can be understood as model components drawn according to life bodies (such as workers in a construction site), in specific implementation, the life body model components can be drawn based on job numbers corresponding to sensors configured on clothes worn by the workers, furthermore, in order to improve modeling efficiency, the preset life body model components can be adopted for the workers, and then the job numbers are used as marks of the preset life body model components. And then, performing integrated simultaneous processing on the updated equipment model component, the updated construction site area component and the updated living body model component, and taking the updated equipment model component, the updated construction site area component and the updated living body model component as updated model components.

Step S40: and when the scene parameters meet preset abnormal conditions, executing a corresponding warning strategy on the construction site scene based on the updated model component.

It is easy to understand that, in order to realize intelligent centralized management of a worksite scene, parameter ranges corresponding to various parameters in the scene parameters can be respectively obtained according to the category labels, and when any parameter in the scene parameters is not in the corresponding parameter range, a corresponding warning strategy is executed on the worksite scene based on the updated model component; or respectively acquiring parameter change rules corresponding to various parameters in the scene parameters according to the category labels; when any parameter in the scene parameters does not accord with the corresponding parameter change rule, executing a corresponding warning strategy on the construction site scene based on the updated model component, where the parameter change rule can be understood as the change rule of each parameter, such as whether the parameter suddenly drops or rises, whether the parameter has a jump phenomenon, etc., or as the change trend of each parameter in different stages, such as the start-up stage of the mixer, the rotation speed should be on the whole, the mixer is changed from the forward rotation stage to the reverse rotation stage, the absolute value of the rotation speed should be on the whole and then shows a trend of first decreasing and then increasing, etc. (for example only, the change rule may be different according to the difference of the equipment model, the mode, etc.), in the concrete implementation, the corresponding parameter change rule is not obtained only according to the category label, and other parameters can be listed to improve the judgment precision, for example, for the equipment parameters, the model, the using time and the like of the construction site equipment can be combined, and for the life form parameters, the age, the medical history and the like of the working personnel can be combined.

It should be noted that, when the scene parameters meet preset abnormal conditions, that is, any one of the scene parameters is not in the corresponding parameter range, or any one of the scene parameters does not meet the corresponding parameter change rule, a corresponding warning policy may be executed on the site scene based on the updated model component corresponding to the abnormal scene parameter, where the warning policy may be to send out corresponding warning information based on the abnormal scene parameter and highlight the updated model component corresponding to the abnormal scene parameter in the site model, so that a user may visually and stereoscopically know the current monitoring abnormal situation, thereby avoiding a potential safety hazard caused by a camera monitoring blind area, and further, in order to improve the intelligent degree of site monitoring, whether an associated model component having an association relationship exists may be analyzed based on the highlighted model component, when the association model component exists, sending out corresponding warning information based on the association model component, and timely reminding a user to take corresponding emergency measures; and analyzing the abnormal influence range based on the highlighted model component, and then sending corresponding warning information to the construction site area corresponding to the abnormal influence range.

In the embodiment, scene parameters of a construction site scene are obtained, and the scene parameters are classified to obtain category labels of the scene parameters; acquiring equipment parameters, environment parameters and life body state parameters from the scene parameters according to the category labels; respectively updating corresponding model components in a preset construction site model according to the equipment parameters, the environment parameters and the life body state parameters to obtain updated model components; and when the scene parameters meet preset abnormal conditions, executing a corresponding warning strategy on the construction site scene based on the updated model component. Compared with the prior art, the monitoring image acquired through the monitoring camera cannot avoid the problem of blind areas in the visual field during monitoring of the construction site, the integrity of the acquired image information cannot be guaranteed, and the potential safety hazard caused by distraction of monitoring workers in the prior art cannot be avoided.

Referring to fig. 2, fig. 2 is a schematic flow chart of a second embodiment of the internet-based worksite monitoring method of the present invention.

Based on the first embodiment, in this embodiment, before the step S30, the method further includes:

step S01: performing live view scanning of a worksite scene to obtain co-planar image data and non-co-planar image data;

it should be noted that, in order to improve the accuracy of the obtained model of the preset construction site model, live-action scanning may be performed on a construction site scene to be monitored (i.e., a site to be constructed) first to obtain coplanar image data and non-coplanar image data corresponding to the construction site scene, where the live-action scanning may be understood as performing live-action aerial photography by an unmanned aerial vehicle to obtain required modeling data (in a specific implementation, the modeling data required to be obtained may be selected according to different modeling software), and further, the obtained modeling data may be classified to obtain coplanar image data and non-coplanar image data, so as to draw corresponding model components according to the coplanar image data and the non-coplanar image data, where the classification criterion may be whether the modeling data corresponding to the construction site scene is on the same plane in a three-dimensional space, that is, the coplanar image data may be data corresponding to the construction site scene that is on the same plane in the three-dimensional space Image data, which may be image data for which the modeling data corresponding to the worksite scene is not co-planar in three-dimensional space.

Step S02: drawing a corresponding model component according to the coplanar image data and the non-coplanar image data;

it will be readily appreciated that, after the co-planar image data and the non-co-planar image data are obtained, a corresponding model component may be rendered based on the co-planar image data and the non-co-planar image data, including but not limited to a scene model component, an equipment model component, a worksite area component, and a living body model component, the scene model component may be understood as an overall architecture of a construction site (e.g., ground, a site rest station, etc.), the equipment model component may be understood as a model component drawn from site equipment of the construction site, the construction site area component can be understood as a model component drawn according to the influence degree and the influence range of the environmental parameters on the construction site area (which can be understood as an area needing monitoring divided according to actual requirements in a construction site), the animator model component may be understood as a model component drawn from an animate object, such as a worker at a construction site.

In a specific drawing process, in order to improve drawing efficiency, the coplanar image data and the non-coplanar image data can be subjected to image recognition by combining with video data shot by a camera of a construction site scene, then whether a corresponding model component exists is searched in a preset modeling database (which can be understood as a database storing various model components, the model component can be uploaded by a user, and can also be updated in real time along with modeling software) on the basis of a recognized object, and when the model component exists, the model component is directly called, and the model component is subjected to component size self-adaption processing; when the corresponding model component is not found, the model component with the highest similarity can be obtained, and then the model component with the highest similarity is correspondingly modified to obtain the required model component. It should be noted that, when selecting a model component based on a similarity, it may be determined whether the similarity is greater than a preset similarity, and if the similarity is less than the preset similarity, the basic model component is directly called to draw, where the preset similarity may be set according to an actual requirement, such as 60% or 75%, and this embodiment is not limited thereto.

Furthermore, in order to improve the drawing efficiency, for drawing of the construction site region assembly, a basic region assembly can be directly called from a preset modeling database, and then the region assembly is subjected to range definition according to the obtained coplanar image data and the non-coplanar image data; for the drawing of the life body model assembly, more workers are in a construction site scene, due to the factors such as uncertainty in movement, personnel mobility and the like, the workers can adopt the preset life body model assembly, then the identification information such as the work number of the workers is used as the identification of the preset life body model assembly, and then the identification information such as the work number is tracked and marked to the preset life body model assembly.

Step S03: and performing effect processing on the model assembly to obtain a preset construction site model, and updating the preset construction site model according to a preset period.

It should be noted that after the model component is obtained, the model component can be subjected to effect processing to obtain a preset construction site model, the effect processing can be proportional adjustment, effect enhancement, dynamic rendering and the like so as to improve the three-dimensional degree and the model display effect of the model component, and then the model component subjected to the effect processing is subjected to self-adaptive splicing processing to obtain the preset construction site model. In a specific implementation, as the construction progress is updated, the construction site is also changed, and therefore, in order to maintain the model accuracy, the preset construction site model may be updated in a preset period, where the preset period may be set according to actual requirements, for example, five working days, two weeks, and the like, which is not limited in this embodiment.

In this embodiment, a worksite scene is subjected to live-action scanning to obtain coplanar image data and non-coplanar image data; drawing a corresponding model component according to the coplanar image data and the non-coplanar image data; and performing effect processing on the model assembly to obtain a preset construction site model, and updating the preset construction site model according to a preset period. The drawing precision of the assembly is improved by adopting different drawing modes for different model assemblies, further, the model construction precision is also improved, the obtained preset construction site model is periodically updated in the embodiment to maintain the precision of the model, the construction site model is obtained, the integrity and the display effect of the scene parameters of a construction site are further improved when the scene parameters are displayed, and the intelligent degree of monitoring the construction site based on the preset construction site model is also improved.

Referring to fig. 3, fig. 3 is a schematic flow chart of a third embodiment of the internet-based worksite monitoring method of the present invention.

Based on the foregoing embodiments, in this embodiment, the step S30 specifically includes:

step S301: embedding the equipment parameters into corresponding equipment model components in a preset construction site model to obtain updated equipment model components;

step S302: rendering the corresponding building site area component in the preset building site model according to the environment parameters to obtain an updated building site area component;

step S303: tracking and marking the life body state parameter to a corresponding life body model component in the preset construction site model to obtain an updated life body model component;

step S304: taking the updated equipment model component, the updated worksite area component and the updated animate body model component as updated model components.

It should be noted that after obtaining the device parameters, the environment parameters, and the life body state parameters of the construction site scene, the device parameters may be embedded into a corresponding device model component in a preset construction site model to update the device model component, so as to obtain an updated device model component, where the device model component may be understood as a model component drawn according to construction site devices of a construction site; rendering a corresponding construction site area component in the preset construction site model according to the environment parameter so as to update the construction site area component, and obtaining an updated construction site area component, wherein the construction site area component can be understood as a model component drawn according to the influence degree and the influence range of the environment parameter on a construction site area (which can be understood as an area needing monitoring and divided according to actual requirements in a construction site); tracking and marking the life body state parameter to a corresponding life body model component in the preset construction site model so as to update the life body model component to obtain an updated life body model component, wherein the life body model component can be understood as a model component drawn according to a life body (such as a worker of a construction site); then, the updated equipment model component, the updated worksite area component and the updated living body model component are subjected to integrated simultaneous processing, and the updated equipment model component, the updated worksite area component and the updated living body model component are used as updated model components.

Accordingly, when the device parameters in the scene parameters meet preset abnormal conditions, a corresponding warning strategy may be executed on the worksite scene based on the updated device model component, that is, step S40 specifically includes:

step S401: when the equipment parameters in the scene parameters meet preset abnormal conditions, highlighting a target equipment model component corresponding to target operation equipment with abnormal equipment parameters in the updated equipment model component, and displaying a real scene monitoring picture corresponding to the target operation equipment;

step S402: detecting whether associated running equipment with an association relation with the target running equipment exists or not according to the updated equipment model component;

step S403: when the associated equipment exists, sending out corresponding warning information based on the target running equipment and the associated running equipment;

step S404: and when the associated equipment does not exist, sending corresponding warning information based on the target operation equipment.

In a specific implementation, in order to improve the safety of a construction site and avoid potential safety hazards, when it is detected that the equipment parameters in the scene parameters meet preset abnormal conditions, a target equipment model component corresponding to target operation equipment with abnormal equipment parameters can be highlighted in the updated equipment model component, and a live-action monitoring picture corresponding to the target operation equipment is displayed; further, in order to improve the intelligent degree of monitoring of a construction site, whether associated operation equipment having an association relation with the target operation equipment exists or not can be detected according to the updated equipment model component, corresponding warning information is sent out based on the target operation equipment and the associated operation equipment when the associated equipment exists, and corresponding warning information is sent out based on the target operation equipment when the associated equipment does not exist.

Accordingly, when the environmental parameters in the scene parameters meet preset abnormal conditions, a corresponding warning strategy may be executed on the worksite scene based on the updated worksite area component, that is, step S40 specifically includes:

step S405: when the environmental parameters in the scene parameters meet preset abnormal conditions, analyzing the area influence range of the environmental parameters according to the updated construction site area components;

step S406: and positioning a corresponding construction site area in the construction site scene according to the area influence range, and sending corresponding warning information to the construction site area.

In the concrete implementation, in order to improve the safety of a construction site and avoid potential safety hazards, when the environment parameters in the scene parameters are detected to accord with preset abnormal conditions, the area influence range of the environment parameters is analyzed according to the updated construction site area components, the corresponding construction site area in the construction site scene is positioned according to the area influence range, and corresponding warning information is sent out for the construction site area. If the situation that the environment temperature of the building site rest station is not within the preset environment temperature range is detected, analyzing the area influence range of the environment temperature of the building site rest station according to the updated building site area assembly, namely the building site rest station, sending corresponding warning information to the building site rest station, for example, reminding of evacuation, cooling and the like, wherein the preset environment temperature range can be set according to actual requirements, and the embodiment does not limit the situation.

Accordingly, when the life body status parameter in the scene parameter meets a preset abnormal condition, a corresponding warning strategy may be executed on the worksite scene based on the updated life body model component, that is, step S40 specifically includes:

step S407: when the life body state parameters in the scene parameters meet preset abnormal conditions, highlighting a target life body model component corresponding to a target marked life body with abnormal life body state parameters in the updated life body model component, and sending corresponding warning information to the target marked life body;

step S408: recording the abnormal life body duration that the life body state parameter of the target life body meets the preset abnormal condition, and judging whether the abnormal life body duration exceeds a preset duration threshold value;

step S409: and when the abnormal time length of the life body exceeds a preset time length threshold value, searching an adjacent life body in the preset position range of the target mark life body according to the updated life body model component, and sending corresponding warning information to the adjacent life body.

In a specific implementation, in order to improve the safety of a construction site and avoid potential safety hazards, when the life form status parameters in the scene parameters meet preset abnormal conditions, highlighting a target life body model component corresponding to a target mark life body with abnormal life body state parameters in the updated life body model component, and sends corresponding warning information to the target mark life body, for example, the body temperature of a certain life body (marked as the target life body) is detected not to be in the preset body temperature range, the body temperature abnormality prompt can be issued to the living body based on the communication device worn by the living body, or, sending a prompt of the abnormal body temperature of the living body in the construction site area to the construction site area where the living body is located, the preset body temperature range may be set according to actual requirements, which is not limited in this embodiment.

Further, the abnormal life body duration that the state parameter of the life body of the target life body meets the preset abnormal condition can be recorded, and whether the abnormal life body duration exceeds a preset duration threshold value is judged; when the abnormal duration of the living body exceeds a preset duration threshold, searching for an adjacent living body within a preset position range of the target marker living body according to the updated living body model component, and sending out corresponding warning information to the adjacent living body, where the preset duration threshold may be set according to actual requirements, such as 2 minutes and 5 minutes, which is not limited in this embodiment. For example, when the body temperature of the target living body is not within the preset body temperature range for more than 2 minutes, searching for a neighboring living body within the preset position range of the target marked living body according to the updated living body model component, and sending corresponding warning information to the neighboring living body, so that the neighboring living body can take corresponding first aid measures to the target living body, where the preset position range may be set according to actual needs, for example, 20 meters or 50 meters, which is not limited in this embodiment.

In this embodiment, the equipment parameters are embedded into corresponding equipment model components in a preset construction site model to obtain updated equipment model components; rendering the corresponding building site area component in the preset building site model according to the environment parameters to obtain an updated building site area component; tracking and marking the life body state parameter to a corresponding life body model component in the preset construction site model to obtain an updated life body model component; and the updated equipment model component, the updated construction site area component and the updated life body model component are used as the updated model component, so that the model component is intensively updated, the intelligent centralized monitoring is carried out on the construction site based on the simultaneous updated model component, the safety of the construction site is improved, and potential safety hazards are also avoided. Further, in this implementation, different warning strategies are adopted for different scene parameter anomalies based on the updated model component, so that the safety of a construction site is further improved, and potential safety hazards are avoided.

Referring to fig. 4, fig. 4 is a block diagram illustrating a first embodiment of the internet-based worksite monitoring system of the present invention.

As shown in fig. 4, an internet-based worksite monitoring system according to an embodiment of the present invention includes:

the parameter classification module 10 is configured to acquire scene parameters of a construction site scene, classify the scene parameters, and acquire category labels of the scene parameters;

a parameter extraction module 20, configured to obtain device parameters, environment parameters, and life form status parameters from the scene parameters according to the category tag;

the component updating module 30 is configured to update corresponding model components in a preset construction site model according to the device parameters, the environment parameters, and the living body state parameters, so as to obtain updated model components;

and the abnormity monitoring module 40 is used for executing a corresponding warning strategy on the construction site scene based on the updated model component when the scene parameter meets a preset abnormity condition.

A second embodiment of the internet-based worksite monitoring system of the present invention is presented based on the above-described first embodiment of the internet-based worksite monitoring system of the present invention.

In this embodiment, the internet-based worksite monitoring system further comprises:

The component updating module 30 is further configured to embed the device parameters into a corresponding device model component in a preset worksite model to obtain an updated device model component;

the component updating module 30 is further configured to render the corresponding building site area component in the preset building site model according to the environment parameter, so as to obtain an updated building site area component;

the component updating module 30 is further configured to track and mark the living body state parameter to a corresponding living body model component in the preset construction site model to obtain an updated living body model component;

the component update module 30 is further configured to take the updated equipment model component, the updated worksite area component, and the updated living body model component as updated model components.

The anomaly monitoring module 40 is further configured to highlight, in the updated device model component, a target device model component corresponding to a target operating device with abnormal device parameters when the device parameters in the scene parameters meet preset anomaly conditions, and display a live-action monitoring picture corresponding to the target operating device;

the anomaly monitoring module 40 is further configured to detect whether there is an associated operating device having an association relationship with the target operating device according to the updated device model component;

the anomaly monitoring module 40 is further configured to send corresponding warning information based on the target running device and the associated running device when the associated device exists;

the anomaly monitoring module 40 is further configured to send corresponding warning information based on the target running device when the associated device does not exist.

The anomaly monitoring module 40 is further configured to, when the environmental parameter in the scene parameter meets a preset anomaly condition, analyze an area influence range of the environmental parameter according to the updated worksite area component;

and the abnormity monitoring module 40 is further used for positioning a corresponding construction site area in the construction site scene according to the area influence range and sending corresponding warning information to the construction site area.

The anomaly monitoring module 40 is further configured to highlight, in the updated animate model component, a target animate model component corresponding to a target marked animate body with an abnormal animate body state parameter when the animate body state parameter in the scene parameter meets a preset anomaly condition, and send corresponding warning information to the target marked animate body;

the abnormality monitoring module 40 is further configured to record an abnormal life duration when the life state parameter of the target life meets the preset abnormal condition, and determine whether the abnormal life duration exceeds a preset duration threshold;

the anomaly monitoring module 40 is further configured to search for an adjacent living entity within the preset position range of the target marker living entity according to the updated living entity model component when the abnormal duration of the living entity exceeds a preset duration threshold, and send corresponding warning information to the adjacent living entity.

The anomaly monitoring module 40 is further configured to obtain parameter ranges corresponding to various parameters in the scene parameters according to the category labels;

the anomaly monitoring module 40 is further configured to, when any one of the scene parameters is not within the corresponding parameter range, execute a corresponding warning strategy for the worksite scene based on the updated model component;

the anomaly monitoring module 40 is further configured to obtain parameter change rules corresponding to various parameters in the scene parameters according to the category labels;

the anomaly monitoring module 40 is further configured to, when any one of the scene parameters does not conform to the corresponding parameter change rule, execute a corresponding warning strategy for the worksite scene based on the updated model component.

Other embodiments or specific implementation manners of the internet-based construction site monitoring system of the present invention may refer to the above method embodiments, and are not described herein again.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., a rom/ram, a magnetic disk, an optical disk) and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. An internet-based worksite monitoring method, comprising the steps of:

2. The internet-based worksite monitoring method of claim 1, wherein, before the step of updating corresponding model components in a preset worksite model according to the equipment parameters, the environmental parameters and the living body state parameters, respectively, and obtaining updated model components, the method further comprises:

3. The internet-based worksite monitoring method of claim 1, wherein the step of respectively updating corresponding model components in a preset worksite model according to the equipment parameters, the environment parameters, and the living body state parameters to obtain updated model components comprises:

4. The internet-based worksite monitoring method of claim 3, wherein the step of executing a corresponding warning strategy for the worksite scene based on the updated model component when the scene parameter meets a preset abnormal condition specifically comprises:

5. The internet-based worksite monitoring method of claim 3, wherein the step of executing a corresponding warning strategy for the worksite scene based on the updated model component when the scene parameter meets a preset abnormal condition specifically comprises:

6. The internet-based worksite monitoring method of claim 3, wherein the step of executing a corresponding warning strategy for the worksite scene based on the updated model component when the scene parameter meets a preset abnormal condition specifically comprises:

7. The internet-based worksite monitoring method of any one of claims 1 to 3, wherein the step of executing a corresponding warning strategy on the worksite scene based on the updated model component when the scene parameter meets a preset abnormal condition specifically comprises:

8. An internet-based worksite monitoring system, comprising:

9. The internet-based worksite monitoring system of claim 8, further comprising:

10. The internet-based worksite monitoring system of claim 8, wherein the component update module is further configured to embed the equipment parameters into corresponding equipment model components in a preset worksite model to obtain updated equipment model components;