CN113128961B - Wisdom building site management cloud platform system - Google Patents

Abstract

The invention discloses a smart building site management cloud platform, which is used for acquiring construction project information and acquiring a building model to be constructed of a current construction project according to the construction project information; then determining a construction process according to the building model to be constructed, and acquiring theoretical material demand and theoretical personnel and equipment demand corresponding to each construction link in the construction process; the construction progress of each construction link is monitored in real time, theoretical material demand and theoretical personnel equipment demand are dynamically updated according to the construction progress, residual material demand and residual personnel equipment demand are obtained, current construction projects are managed according to the residual material demand and the residual personnel equipment demand, resources of the construction projects can be effectively and reasonably controlled, and orderly construction is guaranteed.

Description

Wisdom building site management cloud platform system

Technical Field

The invention relates to the technical field of intelligent construction sites, in particular to a cloud platform system for intelligent construction site management.

Background

The intelligent construction site is characterized in that an informatization means is used, engineering projects are accurately designed and simulated through a three-dimensional design platform, and a construction project informatization ecological circle with interconnection cooperation, intelligent production and scientific management is built around construction process management.

When handling complicated construction project, current wisdom building site management platform is to the construction demand, the management and control and the renewal of resources such as material, length of time, personnel's equipment often are not timely during the construction, because the cross use of resource or occupy for can not cooperate the operation between each construction link, lead to the construction project can not accomplish as scheduled, consequently how effectual reasonable management and control is carried out the resource of construction project, the orderly going on that guarantees the construction becomes the problem of treating promptly.

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 an intelligent building site management cloud platform system, and aims to solve the problem that how to effectively and reasonably manage and control the resources of a construction project and ensure the orderly progress of construction become urgent to solve.

In order to achieve the above object, the present invention provides a smart site management cloud platform system, including:

the information acquisition module is used for acquiring construction project information and acquiring a building model to be constructed of a current construction project according to the construction project information;

the demand determining module is used for determining a construction process according to the building model to be constructed and acquiring theoretical material demand and theoretical personnel and equipment demand corresponding to each construction link in the construction process;

the progress monitoring module is used for monitoring the construction progress of each construction link in real time, dynamically updating the theoretical material demand and the theoretical personnel equipment demand according to the construction progress, and obtaining the residual material demand and the residual personnel equipment demand;

and the project management module is used for managing the current construction project according to the residual material demand and the residual personnel and equipment demand.

Preferably, the information obtaining module is further configured to obtain construction project information, and read electronic drawing information included in the construction project information;

the information acquisition module is further used for acquiring the drawing type of the electronic drawing contained in the electronic drawing information;

the information acquisition module is further used for determining a building model to be constructed of the current construction project according to the electronic drawing when the drawing type is a three-dimensional drawing.

Preferably, the information obtaining module is further configured to obtain a drawing format of the electronic drawing when the drawing type is a two-dimensional drawing;

the information acquisition module is further used for determining a drawing browsing application according to the drawing format, calling the drawing browsing application to convert the electronic drawing into a three-dimensional electronic drawing, and determining the building model to be constructed of the current construction project according to the three-dimensional electronic drawing.

Preferably, the requirement determining module is further configured to obtain a building component model corresponding to the building model to be constructed;

the demand determining module is further configured to obtain geometric information corresponding to the building component model, perform simulated splicing on the building component model according to the geometric information, and record a splicing sequence;

and the requirement determining module is also used for determining a construction process according to the splicing sequence.

Preferably, the demand determination module is further configured to obtain production material information corresponding to the building component model;

the demand determining module is further used for determining material demand and personnel and equipment demand corresponding to each building component model according to the geometric information and the production material information;

the requirement determining module is further used for determining theoretical material requirements and theoretical personnel equipment requirements corresponding to each construction link in the construction process according to the material requirements and the personnel equipment requirements corresponding to the building component model.

Preferably, the demand determination module is further configured to monitor the construction progress of each construction link in real time, and obtain theoretical material consumption and actual material consumption according to the construction progress;

the demand determining module is further configured to generate material supplement reminding information when the actual material consumption is greater than the theoretical material consumption, and send the material supplement reminding information to a logistics service terminal;

the demand determining module is further configured to dynamically update the theoretical material demand according to the actual material consumption, so as to obtain a remaining material demand.

Preferably, the demand determining module is further configured to monitor the construction progress of each construction link in real time, and obtain theoretical personnel and equipment demand and actual personnel and equipment demand according to the construction progress;

the demand determining module is further used for generating staff equipment supplement reminding information when the actual staff equipment demand is larger than the theoretical staff equipment demand, and sending the staff equipment supplement reminding information to the logistics service terminal.

Preferably, the progress monitoring module is further configured to monitor the construction environment of the current construction project and constructors through preset monitoring equipment to obtain a monitoring result;

the progress monitoring module is also used for extracting a monitoring video in the monitoring result, and performing danger identification on the monitoring video through a preset image identification algorithm to obtain an identification result;

and the project management module is also used for carrying out dangerous construction early warning according to the identification result.

Preferably, the progress monitoring module is further configured to extract a monitoring video in the monitoring result, extract a key frame of the monitoring video, and perform risk identification on the extracted key frame through a preset image identification algorithm to obtain an identification result.

Preferably, the progress monitoring module is further configured to perform frame-by-frame identification on the monitoring video, and classify each frame of video image according to a frame identification result to obtain a classified video frame;

the progress monitoring module is further used for extracting key frames of the classified video frames, and performing danger identification on the extracted key frames through a preset image identification algorithm to obtain an identification result.

The intelligent construction site management cloud platform system acquires construction project information and acquires a to-be-constructed building model of a current construction project according to the construction project information; then determining a construction process according to the building model to be constructed, and acquiring theoretical material demand and theoretical personnel and equipment demand corresponding to each construction link in the construction process; the construction progress of each construction link is monitored in real time, theoretical material demand and theoretical personnel equipment demand are dynamically updated according to the construction progress, residual material demand and residual personnel equipment demand are obtained, current construction projects are managed according to the residual material demand and the residual personnel equipment demand, resources of the construction projects can be effectively and reasonably controlled, and orderly construction is guaranteed.

Drawings

FIG. 1 is a block diagram of a first embodiment of a smart worksite management cloud platform system according to 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.

Referring to fig. 1, fig. 1 is a block diagram illustrating a first embodiment of a smart worksite management cloud platform system according to the present invention.

As shown in fig. 1, the smart worksite management cloud platform system may include: an information acquisition module 101, a requirement determination module 102, a progress monitoring module 103, and a project management module 104.

It should be noted that above-mentioned wisdom building site management cloud platform system can be one kind and be used for carrying out (such as security protection, material, personnel and equipment, construction progress etc.) the electronic information platform of all-round management to the construction project of wisdom building site in this embodiment, and this electronic information platform can rely on external hardware equipment (for example monitoring camera, unmanned aerial vehicle, all kinds of electronic products such as alarm) etc. to monitor the safety and the daily construction condition of building site, guarantees construction safety, orderly the going on. The intelligent building site management cloud platform system (hereinafter referred to as a cloud platform) can be loaded on electronic products with human-computer interaction interfaces, such as smart phones, tablet computers and the like, in the form of application software APP, so that users can use the system.

In this embodiment, the information obtaining module 101 is configured to obtain construction project information, and obtain a to-be-constructed building model of a current construction project according to the construction project information;

the construction project information may be an electronic document or file in which construction project information (project name, project site, design unit, supervision unit, planned start/completion date, etc.) is recorded, and may be previously imported by a constructor into the smart site management cloud platform system.

In this embodiment, the construction project information may also include electronic drawing information, that is, a drawing file of the building to be constructed, where a drawing drawn in the drawing file may be a two-dimensional plan view or a three-dimensional perspective view, but the building model to be constructed is a three-dimensional model.

It should be understood that the building model to be constructed may be recorded in the electronic drawing information, and in practical applications, the information obtaining module 101 in the cloud platform may read the electronic drawing information from the construction project information, and then obtain the building model to be constructed of the current construction project according to the electronic drawing information.

The requirement determining module 102 is configured to determine a construction process according to the building model to be constructed, and obtain theoretical material requirements and theoretical personnel and equipment requirements corresponding to each construction link in the construction process;

it should be understood that in the case of building model determination, the building model may be split, then the split model members or sub-models may be spliced, and then the construction process may be determined according to the order of splicing. For example, the building model a is composed of three submodels (a1, a2, A3), wherein the submodel A3 must be installed after the installation of the submodel a2 is completed, and the submodel a2 must be installed after the construction of the submodel a1 is completed, and the construction process at this time may be a1-a 2-A3. However, the construction process does not represent the limitation of the processing or production time of the model or the solid building, for example, the solid buildings corresponding to the sub-models a1, a2 and A3 may be constructed simultaneously or sequentially, which is not limited in this embodiment.

It is understood that different construction processes correspond to different construction links, for example, the construction process of the sub-model a1 may include three construction links a1, a2 and a 3. In order to reasonably manage and control the resources of the construction project, the theoretical material demand and the theoretical personnel equipment demand corresponding to each construction link in the construction process can be calculated or estimated, and then the preparation work before construction is carried out according to the theoretical material demand and the theoretical personnel equipment demand.

The theoretical material demand can be the quantity of materials theoretically needed when the construction task is completed in each construction link. The theoretical personnel and equipment demand can be the quantity of theoretically required constructors and construction equipment when construction tasks are completed in each construction link.

The progress monitoring module 103 is used for monitoring the construction progress of each construction link in real time, and dynamically updating the theoretical material demand and the theoretical personnel equipment demand according to the construction progress to obtain the residual material demand and the residual personnel equipment demand;

it should be noted that, in this embodiment, the construction progress (for example, the progress of the construction link a1 is 30%, the progress of the construction link a2 is 10%, and the like) may be manually input by a manager of the construction project at certain time intervals. Of course, the construction progress can also be obtained by the cloud platform through model comparison or integrity calculation according to the monitoring image acquired by the external hardware equipment. Specifically, the cloud platform can identify a building being built from the monitoring image and extract the current three-dimensional profile of the building; then reading the complete three-dimensional outline of the building from a building model to be constructed of electronic drawing information according to the view angle corresponding to the current three-dimensional outline; matching the current three-dimensional contour with the complete three-dimensional contour; and finally, determining the integrity of the building according to the matching result, and further determining the construction progress according to the integrity.

It should be understood that the progress of construction is often accompanied by consumption of materials or change of personnel and equipment, and the manpower and material resources required for different construction stages are usually different. Therefore, in the embodiment, theoretical material demand and theoretical personnel equipment demand are dynamically updated according to the construction progress to obtain residual material demand and residual personnel equipment demand, so that managers can intuitively and effectively master the use condition of construction resources.

And the project management module 104 is used for managing the current construction project according to the residual material demand and the residual personnel and equipment demand.

It should be understood that after the residual material demand and the residual personnel and equipment demand are obtained, the manager can better supply materials and allocate personnel and equipment to the construction project, and guarantee the scheduled delivery of the construction project.

In the specific implementation, the cloud platform can judge whether the materials in stock meet the subsequent construction requirements according to the demand of the remaining materials, and if not, the cloud platform sends reminding messages (such as voice calls, short messages, mails and the like) to the back service terminal (which can be a mobile phone or a personal computer of a person in charge of the back office of the construction project) to inform the back service terminal of supplementing the materials as soon as possible. In addition, the cloud platform can allocate constructors and construction equipment according to the demand of the residual personnel and equipment, so that intelligent management of a construction site is realized.

The intelligent building site management cloud platform system acquires construction project information and acquires a to-be-constructed building model of a current construction project according to the construction project information; then determining a construction process according to the building model to be constructed, and acquiring theoretical material demand and theoretical personnel and equipment demand corresponding to each construction link in the construction process; the construction progress of each construction link is monitored in real time, theoretical material demand and theoretical personnel equipment demand are dynamically updated according to the construction progress, residual material demand and residual personnel equipment demand are obtained, current construction projects are managed according to the residual material demand and the residual personnel equipment demand, resources of the construction projects can be effectively and reasonably controlled, and orderly construction is guaranteed.

Based on the first embodiment, a second embodiment of the intelligent worksite management cloud platform system of the present invention is provided.

The resources of the construction project are reasonably controlled for better realization, and the scientificity of project management is improved. In this embodiment, the requirement determining module 102 is further configured to obtain a building component model corresponding to the building model to be constructed;

it should be noted that the building element model may be a three-dimensional model corresponding to the building element constituting the building model to be constructed. For example, the building model a to be constructed may be composed of three building elements b, c, d, and then the model corresponding to the building elements b, c, d is the building element model.

Correspondingly, the requirement determining module 102 is further configured to obtain geometric information corresponding to the building component model, perform simulated splicing on the building component model according to the geometric information, and record a splicing sequence;

it should be noted that the geometric information may be data or parameters representing the spatial geometry of the object, such as length, width, height, surface area, volume, angle, radian, and the like.

In practical application, the cloud platform can simulate and splice building component models into building models to be constructed according to the geometric information, and simultaneously record the splicing sequence of each building component.

Correspondingly, the requirement determining module 102 is further configured to determine a construction process according to the splicing sequence.

In specific implementation, after the splicing sequence of each building member is determined, an initial construction process can be determined according to the splicing sequence. In this embodiment, the construction process may also be a final construction process determined after the constructor performs manual demonstration and discussion on the initial construction process, so that the final construction process conforms to the actual construction condition.

As an embodiment, the requirement determining module 102 is further configured to obtain production material information corresponding to the building component model; determining material demand and personnel and equipment demand corresponding to each building component model according to the geometric information and the production material information; and determining theoretical material demand and theoretical personnel and equipment demand corresponding to each construction link in the construction process according to the material demand and the personnel and equipment demand corresponding to the building component model.

It should be understood that the production material information may be information on the brand, model, quantity, and specification of materials required to construct the physical building corresponding to the building component model, such as the brand, model, quantity, and specification of cement, steel bars, and ceramic tiles required to construct the stairs.

It can be understood that after the geometric information and the production material information corresponding to the building component models are determined, the material demand and the personnel and equipment demand corresponding to each building component model can be determined according to the geometric information and the production material information. For example, the number of materials such as cement, steel bars, ceramic tiles and the like required for building a stair 3 m high and 1.5 m wide, the number of construction personnel, the number of construction tools and tools required to be used and the like.

In specific implementation, after the material demand and the personnel and equipment demand corresponding to all building component models are determined, the theoretical material demand and the theoretical personnel and equipment demand corresponding to each construction link in the construction process can be determined.

As another implementation manner, the demand determination module 102 is further configured to monitor a construction progress of each construction link in real time, and obtain a theoretical material consumption amount and an actual material consumption amount according to the construction progress; when the actual material consumption is larger than the theoretical material consumption, generating material supplement reminding information, and sending the material supplement reminding information to a logistics service terminal; and meanwhile, dynamically updating the theoretical material demand according to the actual material consumption to obtain the residual material demand.

As another embodiment, the demand determining module 102 is further configured to monitor a construction progress of each construction link in real time, and obtain theoretical personnel demand and actual personnel demand according to the construction progress; and when the actual personnel and equipment demand is greater than the theoretical personnel and equipment demand, generating personnel and equipment supplement reminding information, and sending the personnel and equipment supplement reminding information to the logistics service terminal.

The intelligent building site management cloud platform system can realize automatic determination of the construction process and improve the scientificity of construction project management by acquiring the building component model corresponding to the building model to be constructed and the geometric information corresponding to the building component model, simulating and splicing the building component model according to the geometric information, recording the splicing sequence and finally determining the construction process according to the splicing sequence.

Based on the first embodiment, a third embodiment of the intelligent worksite management cloud platform system of the present invention is provided.

In order to smoothly acquire the building model to be constructed, in this embodiment, the information acquisition module 101 is further configured to acquire construction item information and read electronic drawing information included in the construction item information; acquiring the drawing type of the electronic drawing contained in the electronic drawing information; and when the drawing type is a three-dimensional drawing, determining the building model to be constructed of the current construction project according to the electronic drawing.

It should be noted that the electronic drawing information may be a drawing file including a building to be constructed, and a graph drawn in the drawing file may be a two-dimensional plan view or a three-dimensional perspective view. The drawing type can be obtained from the file attribute corresponding to the electronic drawing, for example, the general drawing format of the two-dimensional drawing is the dwg format, and the drawing format of the three-dimensional drawing is various, for example, sldasm, rvt, and the like. The type of drawing (two-dimensional or three-dimensional) can be roughly identified according to the drawing format, and application software for opening or browsing the drawing can be determined, for example, software for browsing the drawing in rvt format is Revit, and software for browsing the drawing in dwg format is autoCAD.

It should be understood that, for a three-dimensional drawing, a model in the drawing can be directly derived to obtain a building model to be constructed of a current construction project, and a two-dimensional drawing needs to be subjected to graphic conversion to obtain the three-dimensional drawing.

Further, when the electronic drawing is not a three-dimensional drawing, in order to smoothly acquire the building model to be constructed by the cloud platform, in this embodiment, the information acquisition module 101 is further configured to acquire a drawing format of the electronic drawing when the drawing type is a two-dimensional drawing; determining a drawing browsing application according to the drawing format, calling the drawing browsing application to convert the electronic drawing into a three-dimensional electronic drawing, and determining the building model to be constructed of the current construction project according to the three-dimensional electronic drawing.

It should be understood that the two-dimensional drawing usually draws a two-dimensional plan view, and in this case, to obtain the building model to be constructed (a three-dimensional model), the two-dimensional plan view needs to be converted into a three-dimensional perspective view. In this embodiment, the platform may determine the drawing browsing application according to the drawing format, then call the drawing browsing application to convert the two-dimensional electronic drawing into the three-dimensional electronic drawing, and finally determine the building model to be constructed of the current construction project according to the three-dimensional electronic drawing.

The intelligent construction site management cloud platform system reads electronic drawing information contained in construction project information by acquiring the construction project information; then acquiring the drawing type of the electronic drawing contained in the electronic drawing information; when the drawing type is a three-dimensional drawing, directly determining a building model to be constructed of the current construction project according to the electronic drawing; when the drawing type is a two-dimensional drawing, the drawing format of the electronic drawing is obtained, then the drawing browsing application is determined according to the drawing format, the drawing browsing application is called to convert the electronic drawing into a three-dimensional electronic drawing, and then the building model to be constructed of the current construction project is determined according to the three-dimensional electronic drawing, so that the building model can be smoothly obtained.

Based on the first embodiment, a fourth embodiment of the intelligent worksite management cloud platform system of the present invention is provided.

It should be noted that, for a construction site, the quality and progress of a project are important, but the safety of constructors is more important, and once a dangerous situation or accident occurs in the construction site, the loss is immeasurable, and the situation is serious, so that the construction site is shut down. Therefore, in order to ensure the construction safety of the construction site, in this embodiment, the progress monitoring module 103 is further configured to monitor the construction environment of the current construction project and constructors through preset monitoring equipment to obtain a monitoring result; extracting a monitoring video in the monitoring result, and performing danger identification on the monitoring video through a preset image identification algorithm to obtain an identification result; and carrying out dangerous construction early warning according to the identification result.

It should be noted that the preset monitoring device may be a preset safety monitoring device, such as an entrance guard, a camera, a smoke/fire alarm, etc., and these devices may implement safety monitoring, such as helmet identification, reflective garment identification, smoke extraction identification, mobile phone detection, pedestrian intrusion identification, smoke/fire identification, etc., according to different functions. The present embodiment mainly takes the monitoring camera as an example for explanation.

In this embodiment, the platform can receive the monitoring video that preset monitoring equipment gathered, then identifies the danger source (for example flame, liquid are revealed, pedestrian invades job site etc.) in the video and obtains the identification result, then judges whether the building site takes place or probably takes place the dangerous situation according to the identification result to carry out dangerous early warning in advance, guarantee construction safety.

Further, in order to reduce the calculation amount of the cloud platform, the accuracy of danger identification is guaranteed at the same time. In this embodiment, the progress monitoring module 103 is further configured to extract the monitoring video in the monitoring result, extract a key frame of the monitoring video, and perform risk identification on the extracted key frame through a preset image identification algorithm to obtain an identification result.

It should be noted that the preset image recognition algorithm may be a technology for processing, analyzing and understanding the image to recognize various different patterns of targets and objects. The image recognition algorithm in the embodiment can be obtained by training or configuring the neural network algorithm according to the requirements of the user.

It should be understood that the key frame extraction may be extracting an image frame containing a target object or thing, such as extracting a picture containing a material warehouse, extracting a picture containing an oil storage tank, and the like. In this embodiment, the target object may be calibrated by a user in advance based on sample pictures containing the target object or object, and in the key frame extraction process, the platform may identify and extract key frames in the surveillance video based on the sample pictures.

As another implementation manner, the progress monitoring module 103 in this embodiment is further configured to perform frame-by-frame identification on the monitoring video, and classify each frame of video image according to a frame identification result to obtain a classified video frame; and extracting key frames of the classified video frames, and performing danger identification on the extracted key frames through a preset image identification algorithm to obtain an identification result.

It should be appreciated that at the worksite, the safety of the constructors is always the first place to be ranked. Therefore, in the embodiment, the classification of the video images may be performed by dividing the images into the images including the constructor or the human and the images not including the constructor or the human, then performing the key frame extraction on the classified video frames respectively, and performing the danger identification on the extracted key frames through a preset image identification algorithm to obtain the identification result, so that the danger identification is targeted, and the safety of the constructor is ensured as much as possible.

The intelligent building site management cloud platform system monitors the construction environment of the current construction project and constructors through preset monitoring equipment to obtain a monitoring result; then extracting a monitoring video in the monitoring result, and carrying out danger identification on the monitoring video through a preset image identification algorithm to obtain an identification result; and finally, dangerous construction early warning is carried out according to the identification result, and the construction safety of the construction site can be effectively guaranteed.

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 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 (6)

1. A smart worksite management cloud platform system, comprising:

the information acquisition module is used for acquiring construction project information and reading electronic drawing information contained in the construction project information;

the information acquisition module is further used for acquiring the drawing type of the electronic drawing contained in the electronic drawing information;

the information acquisition module is further used for determining a building model to be constructed of the current construction project according to the electronic drawing when the drawing type is a three-dimensional drawing;

the information acquisition module is further used for acquiring the drawing format of the electronic drawing when the drawing type is a two-dimensional drawing;

the information acquisition module is further used for determining a drawing browsing application according to the drawing format, calling the drawing browsing application to convert the electronic drawing into a three-dimensional electronic drawing, and determining a building model to be constructed of the current construction project according to the three-dimensional electronic drawing;

the demand determining module is used for determining a construction process according to the building model to be constructed and acquiring theoretical material demand and theoretical personnel and equipment demand corresponding to each construction link in the construction process;

the progress monitoring module is used for monitoring the construction progress of each construction link in real time, dynamically updating the theoretical material demand and the theoretical personnel equipment demand according to the construction progress, and obtaining the residual material demand and the residual personnel equipment demand;

the project management module is used for managing the current construction project according to the residual material demand and the residual personnel and equipment demand;

the demand determining module is further used for splitting the building model to obtain split model components or submodels;

the requirement determining module is also used for splicing the model members or the sub-models and determining a construction process according to the splicing sequence;

the progress monitoring module is used for monitoring the construction environment of the current construction project and constructors through preset monitoring equipment so as to obtain a monitoring result;

the progress monitoring module is further used for extracting a monitoring video in the monitoring result, extracting a key frame of the monitoring video, and performing danger identification on the extracted key frame through a preset image identification algorithm to obtain an identification result;

and the project management module is also used for carrying out dangerous construction early warning according to the identification result.

2. The intelligent worksite management cloud platform system of claim 1, wherein said requirement determining module is further configured to obtain a building component model corresponding to said building model to be constructed;

the demand determining module is further configured to obtain geometric information corresponding to the building component model, perform simulated splicing on the building component model according to the geometric information, and record a splicing sequence;

and the requirement determining module is also used for determining a construction process according to the splicing sequence.

3. The intelligent worksite management cloud platform system of claim 2, wherein said requirement determining module is further configured to obtain production material information corresponding to said building component model;

the demand determining module is further used for determining material demand and personnel and equipment demand corresponding to each building component model according to the geometric information and the production material information;

the requirement determining module is further used for determining theoretical material requirements and theoretical personnel equipment requirements corresponding to each construction link in the construction process according to the material requirements and the personnel equipment requirements corresponding to the building component model.

4. The intelligent building site management cloud platform system of claim 3, wherein the demand determination module is further configured to monitor a construction progress of each construction link in real time, and obtain a theoretical material consumption amount and an actual material consumption amount according to the construction progress;

the demand determining module is further configured to generate material supplement reminding information when the actual material consumption is greater than the theoretical material consumption, and send the material supplement reminding information to a logistics service terminal;

the demand determining module is further configured to dynamically update the theoretical material demand according to the actual material consumption, so as to obtain a remaining material demand.

5. The intelligent building site management cloud platform system of claim 3, wherein the demand determination module is further configured to monitor a construction progress of each construction link in real time, and obtain theoretical personnel equipment demand and actual personnel equipment demand according to the construction progress;

the demand determining module is further used for generating staff equipment supplement reminding information when the actual staff equipment demand is larger than the theoretical staff equipment demand, and sending the staff equipment supplement reminding information to the logistics service terminal.

6. The intelligent worksite management cloud platform system of claim 1, wherein the progress monitoring module is further configured to perform frame-by-frame identification on the monitoring video, and classify each frame of video image according to a frame identification result to obtain a classified video frame;

the progress monitoring module is further used for extracting key frames of the classified video frames, and performing danger identification on the extracted key frames through a preset image identification algorithm to obtain an identification result.

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