CN112465381B - Building engineering construction progress data sharing scheduling management cloud platform based on cloud computing - Google Patents

Abstract

The invention discloses a cloud computing-based cloud platform for sharing, scheduling and managing construction progress data of building engineering, which comprises an engineering plate decomposition module, a construction progress acquisition module, a database and a cloud platform, wherein weights of different project sub-projects in corresponding sub-projects are counted and analyzed through the engineering plate decomposition module and the construction progress acquisition module in combination with the cloud platform, the progress of each sub-project in each sub-project is quantitatively displayed in combination with influence factors of weather conditions, and then the current construction progress of a total project is counted.

Description

Building engineering construction progress data sharing scheduling management cloud platform based on cloud computing

Technical Field

The invention belongs to the technical field of constructional engineering, and relates to a cloud platform for sharing, scheduling and managing construction progress data of constructional engineering based on cloud computing.

Background

With the development of cities and the progress of society, the management of construction progress becomes more and more necessary. Engineering management is nowadays popularized, software becomes an important carrier of information exchange, and in the building industry, a mature project management cloud platform can be constructed through the software, so that the whole engineering management system is penetrated, which is not seen in the current building engineering field.

At present, in the construction project implementation process of the building engineering, project progress data information is usually recorded in a form that engineering technicians manually record or input carriers such as computers, and due to the fact that work technicians have a plurality of problems of lagging and being prone to making mistakes when recording data, progress management of the construction project cannot be timely mastered, the construction progress is prone to being slow in progress and difficult to guarantee quality and guarantee quantity to complete the construction plan.

Disclosure of Invention

Aiming at the problems, the invention provides a cloud platform for sharing, scheduling and managing construction progress data of building engineering based on cloud computing, which is characterized in that weights of different project sub-projects in corresponding project sub-projects are counted and analyzed through an engineering plate decomposition module and a construction progress acquisition module in combination with the cloud platform, influence factors of weather conditions are combined, the progress of each project sub-project in each project sub-project is quantitatively displayed, the construction progress of the total project is further counted, the accuracy of calculating the construction progress is improved, visual display is facilitated for engineering managers, different measures are taken according to the construction progress, construction plans are completed with guaranteed quality and guaranteed quantity, and the problems in the prior art are solved.

The purpose of the invention can be realized by the following technical scheme:

a cloud computing-based cloud platform for sharing, scheduling and managing construction progress data of a building project comprises an engineering plate decomposition module, a construction progress acquisition module, a database and a cloud platform;

the construction progress acquisition module is respectively connected with the engineering plate decomposition module, the database and the cloud platform, and the cloud platform is connected with the database;

the engineering plate decomposition module is used for dividing projects needing to be built in a target project into a plurality of subsection projects, numbering the divided subsection projects according to the sequence of construction time, sequentially marking the divided subsection projects as 1,2, a.so, i, a.so, g, dividing different work types in the same subsection project according to construction types, dividing the divided subsection projects into a plurality of subsection projects, numbering the divided subsection projects according to a preset sequence, and sequentially marking the divided subsection projects as 1,2, a.so, e, a.so, f;

the construction progress acquisition module comprises a volume measuring instrument and is used for detecting the project sub-projects under construction in each sub-project, acquiring the constructed building volume of each sub-project in each sub-project and forming a project building volume set S_i(s_i1,s_i2,...,s_ie,...,s_if)，s_ie is expressed as the built building volume of the e-th project in the ith project, the planned building volume of each project in each project stored in the database is extracted, and each project is divided intoThe constructed building volume of each project sub-item in the project is compared with the corresponding planned construction building volume to form a sub-item project building volume comparison set S'_i(s′_i1,s′_i2,...,s′_ie,...,s′_if)，s′_ie is a contrast value of the volume of the built building of the e-th project in the ith project, if the contrast value is 0, the project is built, if the contrast value is more than 0, the project is not built, and the formed project building volume contrast set is sent to the cloud platform;

the database is used for storing the planned construction cost of each subsection project, the planned construction building volume of each subsection project in each subsection project, the rated yield of manpower and the construction progress influence coefficients corresponding to different weather type grades;

the cloud platform comprises a data preprocessing module, a weather obtaining module, a human resource management module, a material resource management module, a cloud server and a construction progress sharing module;

the weather acquisition module, the human resource management module and the material resource management module are respectively connected with the data preprocessing module and the cloud server, and the construction progress subentry module is connected with the cloud server;

the data preprocessing module receives the project construction volume comparison set sent by the construction progress acquisition module, extracts the project with the contrast value of 0 in the project construction volume comparison set, marks the project as constructed project, and marks the constructed project in each project as 1,2,_i(x_i1,x_i2,...,x_ij,...,x_ik)，x_ij represents the jth constructed subentry project in the ith subentry project, the subentry project with the contrast value larger than 0 in the subentry project building volume contrast set is extracted and marked as the unfinished subentry project, and the unfinished subentry projects in each subentry project are sequentially marked as 1,2,_i(z_i1,z_i2,...,z_ip,z_iq)，z_ip represents a pth project which is not built and completed in the ith project, the project completion set is respectively sent to the cloud server and the material resource management module, and the project incomplete set is respectively sent to the weather acquisition module, the human resource management module, the material resource management module and the cloud server;

the weather acquisition module receives the project unfinished set sent by the data preprocessing module, extracts each project unfinished in each project in the project unfinished set, acquires weather conditions in the project construction process of each project unfinished in each distribution process, divides the acquired weather conditions in the project construction process of each project unfinished in each distribution process according to the weather type grade, and forms a construction weather type grade set C_i(c_i1,c_i2,...,c_ip,...,c_iq)，c_ip is expressed as the weather category grade in the construction process of the pth project which is not constructed in the ith project, and the constructed construction weather category grade set is sent to the cloud server;

the human resource management module receives the unfinished project set sent by the data preprocessing module, extracts the project which is not built in each project in the unfinished project set, obtains human resources required by the project which is not built in each project, and forms a project human resource set A_i(a_i1,a_i2,...,a_ip,...,a_iq)，a_ip represents a human resource value allocated to the pth project which is not built in the ith project, and the formed project human resource set is sent to the cloud server;

the material resource management module receives the project completion set sent by the data preprocessing module, extracts the constructed project in each project in the project completion set, acquires the material resource amount required by each project constructed in each project, and forms the project material resource setB_i(b_i1,b_i2,...,b_ij,...,b_ik)，b_ij represents the material resource amount required by the jth completed project in the ith project, receives the unfinished project set sent by the data preprocessing module, extracts the material resource amount required by the unfinished projects in each project in the unfinished project set, and forms an unfinished project material resource set D_i(d_i1,d_i2,...,d_ip,...,d_iq)，d_ip is expressed as the material resource amount of the pth unfinished project in the ith project, and the formed finished project material resource set and unfinished project material resource set are sent to the cloud server;

the cloud server receives the project-completed material resource set sent by the material resource management module, extracts the material resource quantity required by each project built and completed in each sub project in the project-completed material resource set, extracts the planned construction cost of each sub project stored in the database, and counts the weight of each project built and completed in each sub project according to the planned construction cost of each sub project and the material resource quantity input by each project built and completed in each sub project to form a project-completed weight set w_i(w_i1,w_i2,...,w_ij,...,w_ik)，w_ij represents the weight of the jth constructed project in the ith project, receives the unfinished project material resource set sent by the material resource management module, extracts the material resource quantity required by each project which is not constructed in each project in the unfinished project material resource set, and calculates the weight of each project which is not constructed in each project according to the material resource quantity input by each project which is not constructed in each project to form an unfinished project weight set w'_i(w′_i1,w′_i2,...,w′_ip,...,w′_iq)，w′_ip represents the right of the jth constructed project in the ith projectWeighing;

the cloud server receives the construction weather category grade set sent by the weather obtaining module, extracts weather category grades in the construction process of unfinished project items in each branch project in the weather category grade set, extracts construction progress influence coefficients corresponding to different weather category grades stored in the database, compares the weather category grades of the project items which are not finished in each branch project in the construction process with the construction progress influence coefficients corresponding to different weather category grades to form a construction progress influence coefficient set C'_i(c′_i1,c′_i2,...,c′_ie,...,c′_if)，c′_ie represents the construction progress influence coefficient of the e th project which is not built in the ith project;

the cloud server receives the project human resource collection sent by the human resource management module, extracts human resource values allocated in each project which is not built in each project in the project human resource collection, extracts the manpower yield quota stored in the database, calculates the plan completion ratio of each project which is not built in each project in combination with the planned construction building volume of each project in each project, records the plan completion ratio of each project which is built in each project as 1, and sends the plan completion ratio of each project which is not built in each project and the plan completion ratio of each project which is built in each project to the construction progress sub-project module;

the cloud server calculates the construction progress of the total project according to the calculated weight of each constructed project and the calculated weight of each project which is not constructed in each project, the plan completion ratio of each project which is not completed in each project, the influence coefficient of the construction progress of each project which is not constructed in each project, and sends the calculated construction progress of the total project to the construction progress sharing module;

and the construction progress sharing module receives and respectively displays the plan completion ratio of each project which is not constructed and is completed in each project, the total project construction progress and the plan completion ratio of each project which is constructed and completed in each project, which are sent by the cloud server.

Furthermore, each project in each project is constructed simultaneously in the construction process.

Further, the weather category grades are light rain, medium rain, heavy rain, small snow, medium snow, heavy snow, light fog, heavy fog, sunny day, cloudy day and cloudy day respectively;

furthermore, the vehicle speed influence coefficients corresponding to light rain, medium rain and heavy rain are delta 1 < delta 2 < delta 3, the vehicle speed influence coefficients corresponding to small snow, medium snow and heavy snow are lambda 1 < lambda 2 < lambda 3, the vehicle speed influence coefficients corresponding to light fog, heavy fog and heavy fog are xi 1 < xi 2 < xi 3, and the construction progress influence coefficients corresponding to sunny days, cloudy days and cloudy days are 0.

Furthermore, the weight calculation mode of the constructed project in each project is that

b_ij is the amount of material resources needed in the jth completed project in the ith project, G_iThe planned construction cost of the ith branch project is expressed, and the weight calculation mode of the project which is not constructed and is completed in each branch project is

d_iAnd p represents the material resource amount of the p-th unfinished project in the ith project.

Furthermore, the plan completion ratio of each project which is not built in each project is calculated in the way that

a_ip represents the value of human resources allocated to the p th project which is not built in the ith project, R represents the manpower quota yield, V_ipExpressed as the planned construction building volume of the p th unfinished project in the ith project.

Further, the construction progress of the overall project is calculated in the mode of

c′_iAnd e is expressed as a construction progress influence coefficient of the e th unfinished project in the ith project.

Has the advantages that:

(1) according to the construction schedule calculation method, the weights of different project sub-projects in corresponding sub-projects are counted and analyzed through the project plate decomposition module and the construction schedule acquisition module in combination with the cloud platform, the schedule of each sub-project in each sub-project is quantitatively displayed in combination with the influence factors of weather conditions, the current construction schedule of the total project is further counted, the problems that the calculation result error of the project construction schedule calculation method in the prior art is large or the calculation process is too subjective are solved, the accuracy of the calculation of the construction schedule is improved, the project managers can conveniently and visually display the calculation schedule, different measures are taken according to the construction schedule, and the construction schedule is finished with guaranteed quality and quantity.

(2) According to the invention, at the weather obtaining module, the corresponding construction progress influence coefficient is counted and analyzed by obtaining the weather condition of the project in the construction process of the project which is not built and completed in each project, and the influence factor on the construction progress is more scientifically considered, so that when the current construction progress of the total project is calculated, the data is closer to a real numerical value, and the calculation precision and reliability of the calculation of the construction progress are improved.

(3) In the construction progress sharing module, the current construction progress of the total project and the current construction progress of the project manager can be visually displayed by the plan completion ratio of the project which is constructed and not constructed in each project, the weather condition of the project which is not constructed and not constructed, so that the project manager can conveniently adjust the personnel and material resources in the construction task according to the data, and further the current construction progress can be effectively adjusted in real time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a block diagram of the present invention.

Fig. 2 is a schematic block diagram of a cloud platform.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a cloud platform for sharing, scheduling and managing construction progress data of a building project based on cloud computing comprises a project plate decomposition module, a construction progress acquisition module, a database and a cloud platform;

the construction progress acquisition module is respectively connected with the engineering plate decomposition module, the database and the cloud platform, and the cloud platform is connected with the database;

the engineering plate decomposition module is used for dividing projects needing to be built in a target project into a plurality of subsection projects, numbering the divided subsection projects according to the sequence of construction time, sequentially marking the divided subsection projects as 1,2, a.so, i, a.so, g, dividing different work types in the same subsection project according to construction types, dividing the divided subsection projects into a plurality of subsection projects, numbering the divided subsection projects according to a preset sequence, and sequentially marking the divided subsection projects as 1,2, a.so, e, a.so, f;

the construction progress acquisition module comprises a volume measuring instrument and is used for detecting the project sub-projects under construction in each sub-project, acquiring the constructed building volume of each sub-project in each sub-project and forming a project building volume set S_i(s_i1,s_i2,...,s_ie,...,s_if)，s_ie is expressed as the ith division projecte constructed building volumes of the project sub-projects, extracting the planned construction building volume of each project sub-project in each project sub-project stored in the database, comparing the constructed building volume of each project sub-project in each project sub-project with the corresponding planned construction building volume to form a project sub-project building volume comparison set S'_i(s′_i1,s′_i2,...,s′_ie,...,s′_if)，s′_ie is a contrast value of the volume of the built building of the e-th project in the ith project, if the contrast value is 0, the project is built, if the contrast value is more than 0, the project is not built, and the formed project building volume contrast set is sent to the cloud platform;

the database is used for storing the planned construction cost of each subsection project, storing the planned construction building volume of each subsection project in each subsection project, storing the rated yield of manpower, storing the construction progress influence coefficients corresponding to different weather types and grades, wherein the vehicle speed influence coefficients corresponding to light rain, medium rain and heavy rain are delta 1 < delta 2 < delta 3, the vehicle speed influence coefficients corresponding to small snow, medium snow and heavy snow are lambda 1 < lambda 2 < lambda 3, the vehicle speed influence coefficients corresponding to light fog, heavy fog and heavy fog are xi 1 < xi 2 < xi 3, and the construction progress influence coefficients corresponding to fine days, cloudy days and cloudy days are 0;

the cloud platform comprises a data preprocessing module, a weather obtaining module, a human resource management module, a material resource management module, a cloud server and a construction progress sharing module;

the weather acquisition module, the human resource management module and the material resource management module are respectively connected with the data preprocessing module and the cloud server, and the construction progress subentry module is connected with the cloud server;

the data preprocessing module receives the project construction volume comparison set sent by the construction progress acquisition module, extracts the project with the contrast value of 0 in the project construction volume comparison set, marks the project as constructed project, and marks the constructed project in each project as 1,2,engineering completion set X_i(x_i1,x_i2,...,x_ij,...,x_ik)，x_ij represents the jth constructed subentry project in the ith subentry project, the subentry project with the contrast value larger than 0 in the subentry project building volume contrast set is extracted and marked as the unfinished subentry project, and the unfinished subentry projects in each subentry project are sequentially marked as 1,2,_i(z_i1,z_i2,...,z_ip,z_iq)，z_ip represents a pth project in the ith project which is not built, and the project completion sets in all projects are simultaneously constructed in the construction process and are respectively sent to the cloud server and the material resource management module, and the project incomplete sets are respectively sent to the weather acquisition module, the human resource management module, the material resource management module and the cloud server;

the weather acquisition module receives the project unfinished set sent by the data preprocessing module, extracts each project unfinished in each project in the project unfinished set, acquires weather conditions in the project construction process of each project unfinished in each distribution process, divides the acquired weather conditions in the project construction process of each project unfinished in each distribution process according to the weather type grade, and forms a construction weather type grade set C_i(c_i1,c_i2,...,c_ip,...,c_iq)，c_ip is expressed as the weather type grade in the construction process of the p th project which is not built in the ith project, the weather type grades are respectively light rain, medium rain, heavy rain, small snow, medium snow, heavy snow, light fog, heavy fog, sunny day, cloudy day and cloudy day, and the formed construction weather type grade set is sent to a cloud server;

according to the method, the weather conditions of the project which is not built in each project are obtained, the corresponding construction progress influence coefficient is obtained through statistical analysis, the influence factors on the construction progress are considered more scientifically, the data are closer to real numerical values when the current construction progress of the total project is calculated, and the calculation precision and reliability of the calculation of the construction progress are improved.

The human resource management module receives the unfinished project set sent by the data preprocessing module, extracts the project which is not built in each project in the unfinished project set, obtains human resources required by the project which is not built in each project, and forms a project human resource set A_i(a_i1,a_i2,...,a_ip,...,a_iq)，a_ip represents a human resource value allocated to the pth project which is not built in the ith project, and the formed project human resource set is sent to the cloud server;

the material resource management module receives the project completion set sent by the data preprocessing module, extracts the constructed project in each project in the project completion set, acquires the material resource amount required by each project constructed in each project, and forms a project material resource set B_i(b_i1,b_i2,...,b_ij,...,b_ik)，b_ij represents the material resource amount required by the jth completed project in the ith project, receives the unfinished project set sent by the data preprocessing module, extracts the material resource amount required by the unfinished projects in each project in the unfinished project set, and forms an unfinished project material resource set D_i(d_i1,d_i2,...,d_ip,...,d_iq)，d_ip is expressed as the material resource amount of the pth unfinished project in the ith project, and the formed finished project material resource set and unfinished project material resource set are sent to the cloud server;

the cloud server receives the project material resource collection which is sent by the material resource management module and is completed, extracts the material resource quantity required by each project which is built and completed in each project in the project material resource collection which is completed, and extracts the dataThe planned construction cost of each branch project stored in the library is calculated according to the planned construction cost of each branch project and the input material resource amount of the constructed branch project in each branch project, the weight of the constructed branch project in each branch project is counted, and a finished branch project weight set w is formed_i(w_i1,w_i2,...,w_ij,...,w_ik)，w_ij represents the weight of the jth constructed project in the ith project, receives the unfinished project material resource set sent by the material resource management module, extracts the material resource quantity required by each project which is not constructed in each project in the unfinished project material resource set, and calculates the weight of each project which is not constructed in each project according to the material resource quantity input by each project which is not constructed in each project to form an unfinished project weight set w'_i(w′_i1,w′_i2,...,w′_ip,...,w′_iq)，w′_ip is the weight of the jth constructed project in the ith project, and the weight calculation mode of the constructed project in each project is

b_ij is the amount of material resources needed in the jth completed project in the ith project, G_iThe planned construction cost of the ith branch project is expressed, and the weight calculation mode of the project which is not constructed and is completed in each branch project is

d_ip represents the material resource amount of the p-th unfinished project in the ith project;

the cloud server receives the construction weather category grade set sent by the weather acquisition module, extracts the weather category grade in the construction process of unfinished project in each project in the weather category grade set, and extracts construction progress shadows corresponding to different weather category grades stored in the databaseAnd a noise coefficient, wherein the weather type grade of the project which is not constructed in each branch project in the construction process is compared with the construction progress influence coefficients corresponding to different weather type grades to form a construction progress influence coefficient set C'_i(c′_i1,c′_i2,...,c′_ie,...,c′_if)，c′_ie represents the construction progress influence coefficient of the e th project which is not built in the ith project;

the cloud server receives the project human resource collection sent by the human resource management module, extracts the human resource values allocated in each project which is not built in each project in the project human resource collection, extracts the manpower yield quota stored in the database, combines the planned construction building volume of each project in each project, and counts the plan completion ratio of each project which is not built in each project, wherein the plan completion ratio of each project which is not built in each project is calculated in the mode of

a_ip represents the value of human resources allocated to the p th project which is not built in the ith project, R represents the manpower quota yield, V_ipRepresenting the planned construction building volume of the pth project in the ith project, which is not constructed, recording the planned completion ratio of each project constructed in each project as 1, and sending the planned completion ratio of each project which is not constructed and is constructed in each project and the planned completion ratio of each project constructed and completed to the construction progress project division module;

the cloud server calculates the construction progress of the total project according to the calculated weight of each constructed project in each project and the calculated weight of each project which is not constructed, the plan completion ratio of each project which is not constructed in each project, the construction progress influence coefficient of each project which is not constructed in each project, and the calculation mode of the construction progress of the total project is that

c′_iAnd e is expressed as a construction progress influence coefficient of the e th unfinished project in the ith project. Sending the counted total engineering construction progress to a construction progress sharing module;

and the construction progress sharing module receives and respectively displays the plan completion ratio of each project which is not constructed and is completed in each project, the total project construction progress and the plan completion ratio of each project which is constructed and completed in each project, which are sent by the cloud server.

The current construction progress of the total project is visually displayed through the plan completion ratio of the project projects which are built and not built in each project, the weather condition of the project which is not built and not completed, and the current construction progress of the total project is conveniently adjusted by engineering management personnel through the data, so that the current construction progress is effectively adjusted in real time.

According to the construction schedule calculation method, the weights of different project sub-projects in corresponding sub-projects are counted and analyzed through the project plate decomposition module and the construction schedule acquisition module in combination with the cloud platform, the schedule of each sub-project in each sub-project is quantitatively displayed in combination with the influence factors of weather conditions, the current construction schedule of the total project is further counted, the problems that the calculation result error of the project construction schedule calculation method in the prior art is large or the calculation process is too subjective are solved, the accuracy of the calculation of the construction schedule is improved, the project managers can conveniently and visually display the calculation schedule, different measures are taken according to the construction schedule, and the construction schedule is finished with guaranteed quality and quantity.

The foregoing is merely exemplary and illustrative of the principles of the present invention and various modifications, additions and substitutions of the specific embodiments described herein may be made by those skilled in the art without departing from the principles of the present invention or exceeding the scope of the claims set forth herein.

Claims (7)

1. The utility model provides a building engineering construction progress data sharing dispatch management cloud platform based on cloud, its characterized in that: the construction progress analysis system comprises an engineering plate decomposition module, a construction progress acquisition module, a database and a cloud platform;

the construction progress acquisition module is respectively connected with the engineering plate decomposition module, the database and the cloud platform, and the cloud platform is connected with the database;

the engineering plate decomposition module is used for dividing projects needing to be built in a target project into a plurality of subsection projects, numbering the divided subsection projects according to the sequence of construction time, sequentially marking the divided subsection projects as 1,2, a.so, i, a.so, g, dividing different work types in the same subsection project according to construction types, dividing the divided subsection projects into a plurality of subsection projects, numbering the divided subsection projects according to a preset sequence, and sequentially marking the divided subsection projects as 1,2, a.so, e, a.so, f;

the construction progress acquisition module comprises a volume measuring instrument and is used for detecting the project sub-projects under construction in each sub-project, acquiring the constructed building volume of each sub-project in each sub-project and forming a project building volume set S_i(s_i1,s_i2,…,s_ie,…,s_if)，s_ie is the constructed building volume of the e-th project in the ith project, the planned construction building volume of each project in each project is extracted and stored in the database, and the constructed building volume of each project in each project is compared with the corresponding planned construction building volume to form a project building volume comparison set S'_i(s′_i1,s′_i2,...,s′_ie,...,s′_if)，s′_ie is a contrast value of the volume of the built building of the e-th project in the ith project, if the contrast value is 0, the project is built, if the contrast value is more than 0, the project is not built, and the formed project building volume contrast set is sent to the cloud platform;

the database is used for storing the planned construction cost of each subsection project, the planned construction building volume of each subsection project in each subsection project, the rated yield of manpower and the construction progress influence coefficients corresponding to different weather type grades;

the cloud platform comprises a data preprocessing module, a weather obtaining module, a human resource management module, a material resource management module, a cloud server and a construction progress sharing module;

the weather acquisition module, the human resource management module and the material resource management module are respectively connected with the data preprocessing module and the cloud server, and the construction progress itemizing module is connected with the cloud server;

the data preprocessing module receives the project construction volume comparison set sent by the construction progress acquisition module, extracts the project with the contrast value of 0 in the project construction volume comparison set, marks the project as constructed project, and marks the constructed project in each project as 1,2,_i(x_i1,x_i2,...,x_ij,...,x_ik)，x_ij represents the jth constructed subentry project in the ith subentry project, the subentry project with the contrast value larger than 0 in the subentry project building volume contrast set is extracted and marked as the unfinished subentry project, and the unfinished subentry projects in each subentry project are sequentially marked as 1,2,_i(z_i1,z_i2,...,z_ip,z_iq)，z_ip represents a pth project which is not built and completed in the ith project, the project completion set is respectively sent to the cloud server and the material resource management module, and the project incomplete set is respectively sent to the weather acquisition module, the human resource management module, the material resource management module and the cloud server;

the weather acquisition module receives the project unfinished set sent by the data preprocessing module, extracts each project unfinished in each project in the project unfinished set, acquires weather conditions in the project construction process of each project unfinished in each distribution process, and acquires weather conditions in each project unfinished in each distribution processThe weather conditions of each project construction process are divided according to the weather category grades to form a construction weather category grade set C_i(c_i1,c_i2,...,c_ip,...,c_iq)，c_ip is expressed as the weather category grade in the construction process of the pth project which is not constructed in the ith project, and the constructed construction weather category grade set is respectively sent to the cloud server;

the human resource management module receives the unfinished project set sent by the data preprocessing module, extracts the project which is not built in each project in the unfinished project set, obtains human resources required by the project which is not built in each project, and forms a project human resource set A_i(a_i1,a_i2,...,a_ip,...,a_iq)，a_ip represents a human resource value allocated to the pth project which is not built in the ith project, and the formed project human resource set is sent to the cloud server;

the material resource management module receives the project completion set sent by the data preprocessing module, extracts the constructed projects in each project in the project completion set, acquires the material resource amount required by each project constructed in each project, and forms a project material resource set B_i(b_i1,b_i2,...,b_ij,...,b_ik)，b_ij represents the material resource amount required by the jth completed project in the ith project, receives the unfinished project set sent by the data preprocessing module, extracts the material resource amount required by the unfinished projects in each project in the unfinished project set, and forms an unfinished project material resource set D_i(d_i1,d_i2,...,d_ip,...,d_iq)，d_ip is expressed as the material resource amount of the pth unfinished project in the ith project, and the formed finished project material resource set and unfinished project material resource set are sent to the cloud server;

the cloud server receives the project-completed material resource set sent by the material resource management module, extracts the material resource quantity required by each project built and completed in each sub project in the project-completed material resource set, extracts the planned construction cost of each sub project stored in the database, and counts the weight of each project built and completed in each sub project according to the planned construction cost of each sub project and the material resource quantity input by each project built and completed in each sub project to form a project-completed weight set w_i(w_i1,w_i2,...,w_ij,...,w_ik)，w_ij represents the weight of the jth constructed project in the ith project, receives the unfinished project material resource set sent by the material resource management module, extracts the material resource quantity required by each project which is not constructed in each project in the unfinished project material resource set, and calculates the weight of each project which is not constructed in each project according to the material resource quantity input by each project which is not constructed in each project to form an unfinished project weight set w'_i(w′_i1,w′_i2,...,w′_ip,...,w′_iq)，w′_ip represents the weight of the jth constructed project in the ith project;

the cloud server receives the construction weather category grade set sent by the weather obtaining module, extracts weather category grades in the construction process of unfinished project items in each branch project in the weather category grade set, extracts construction progress influence coefficients corresponding to different weather category grades stored in the database, compares the weather category grades of the project items which are not finished in each branch project in the construction process with the construction progress influence coefficients corresponding to different weather category grades to form a construction progress influence coefficient set C'_i(c′_i1,c′_i2,...,c′_ie,...,c′_if)，c′_ie represents the e-th unfinished project in the ith projectThe construction progress influence coefficient;

the cloud server receives the project human resource collection sent by the human resource management module, extracts human resource values allocated in each project which is not built in each project in the project human resource collection, extracts the manpower yield quota stored in the database, calculates the plan completion ratio of each project which is not built in each project in combination with the planned construction building volume of each project in each project, records the plan completion ratio of each project which is built in each project as 1, and sends the plan completion ratio of each project which is not built in each project and the plan completion ratio of each project which is built in each project to the construction progress sub-project module;

the cloud server calculates the construction progress of the total project according to the calculated weight of each constructed project and the calculated weight of each project which is not constructed in each project, the plan completion ratio of each project which is not completed in each project, the influence coefficient of the construction progress of each project which is not constructed in each project, and sends the calculated construction progress of the total project to the construction progress sharing module;

and the construction progress sharing module receives and respectively displays the plan completion ratio of each project which is not constructed and completed in each project, the total project construction progress and the plan completion ratio of each project which is constructed and completed in each project, which are sent by the cloud server.

2. The cloud platform for sharing, scheduling and managing construction progress data of the building engineering based on the cloud computing is characterized by comprising the following components in parts by weight: and each project in each project is constructed simultaneously in the construction process.

3. The cloud platform for sharing, scheduling and managing construction progress data of the building engineering based on the cloud computing is characterized by comprising the following components in parts by weight: the weather category grades are light rain, medium rain, heavy rain, light snow, medium snow, heavy snow, light fog, heavy fog, sunny day, cloudy day and cloudy day respectively.

4. The cloud platform for sharing, scheduling and managing construction progress data of building engineering based on cloud computing as claimed in claim 3, wherein: the vehicle speed influence coefficients corresponding to light rain, medium rain and heavy rain are delta 1 < delta 2 < delta 3 in sequence, the vehicle speed influence coefficients corresponding to small snow, medium snow and heavy snow are lambda 1 < lambda 2 < lambda 3 in sequence, the vehicle speed influence coefficients corresponding to light fog, heavy fog and heavy fog are xi 1 < xi 2 < xi 3 in sequence, and the construction progress influence coefficients corresponding to sunny days, cloudy days and cloudy days are 0.

5. The cloud platform for sharing, scheduling and managing construction progress data of the building engineering based on the cloud computing is characterized by comprising the following components in parts by weight: the weight calculation mode of the constructed project in each project is that

b_ij is the amount of material resources needed in the jth completed project in the ith project, G_iThe planned construction cost of the ith branch project is expressed, and the weight calculation mode of the project which is not constructed and is completed in each branch project is

d_iAnd p represents the material resource amount of the p-th unfinished project in the ith project.

6. The cloud platform for sharing, scheduling and managing construction progress data of the building engineering based on the cloud computing is characterized by comprising the following components in parts by weight: the plan completion ratio of each project which is not built in each project is calculated in the way that

a_ip represents the human resources provided for the p th project which is not built in the ith projectValue, R is expressed as yield in human ration, V_ipExpressed as the planned construction building volume of the p th unfinished project in the ith project.

7. The cloud platform for sharing, scheduling and managing construction progress data of the building engineering based on the cloud computing is characterized by comprising the following components in parts by weight: the construction progress calculation mode of the total project is

c′_iAnd e is expressed as a construction progress influence coefficient of the e th unfinished project in the ith project.

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