CN113408034A

CN113408034A - Engineering construction intelligent cloud management platform based on BIM building three-dimensional model technology

Info

Publication number: CN113408034A
Application number: CN202110785086.3A
Authority: CN
Inventors: 郭魁
Original assignee: Guizhou Yusheng Engineering Construction Consulting Co ltd
Current assignee: Guizhou Yusheng Engineering Construction Consulting Co ltd
Priority date: 2021-07-12
Filing date: 2021-07-12
Publication date: 2021-09-17
Anticipated expiration: 2041-07-12
Also published as: CN113408034B

Abstract

The invention discloses an engineering construction intelligent cloud management platform based on a BIM (building information modeling) building three-dimensional model technology, which comprises a component number acquisition module, a component information acquisition module, a construction site image acquisition module, an information integration module, a production component information acquisition module, a production component prefabricated hole basic information acquisition module, a data processing and analysis module and a remote control terminal, wherein the construction engineering intelligent cloud management platform based on the BI M building three-dimensional model technology comprehensively analyzes and manages the purchasing of the building engineering components, the information corresponding to each purchased production component and the basic information corresponding to each prefabricated hole of each production component, solves the problem that the construction material purchasing process is not managed by the existing construction engineering management method, effectively avoids waste caused by material field processing and pollution of processing materials to the construction area environment, the standardization and the controllability of a construction site are realized.

Description

Engineering construction intelligent cloud management platform based on BIM building three-dimensional model technology

Technical Field

The invention belongs to the technical field of engineering construction management, and relates to an engineering construction intelligent cloud management platform based on a BIM building three-dimensional model technology.

Background

With the rapid development of economy, the construction industry has also been steadily promoted. Under the large background that the number of the building projects is continuously increased and the project scale is continuously enlarged, the requirements on the construction quality of the building projects are higher and higher, and the construction of the building projects needs to be managed in order to guarantee the construction quality of the building projects.

The existing building engineering construction management method mainly focuses on managing construction quality, construction progress and the like in the construction process of each building engineering, and does not manage corresponding required materials before construction, so the existing building engineering construction management method has certain disadvantages.

Disclosure of Invention

In view of the above, in order to solve the problems in the background art, an engineering construction intelligent cloud management platform based on a BIM building three-dimensional model technology is proposed for quality detection before procurement and use of fabricated building components, so as to realize intelligent management of the building engineering construction components;

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

the invention provides an engineering construction intelligent cloud management platform based on a BIM building three-dimensional model technology, wherein a data processing and analyzing module is respectively connected with a component information acquisition module, a production component prefabricated hole basic information acquisition module and a remote control terminal;

the component quantity acquisition module is used for acquiring the quantity of components corresponding to the building, further acquiring the quantity of the components corresponding to the building BIM according to the BIM corresponding to the building, marking the components as model components, further numbering each model component in the building BIM according to a preset sequence, and sequentially marking the model components as 1,2,... i,. n;

the component information acquisition module is used for acquiring information corresponding to each model component in the building BIM three-dimensional model, wherein the model component information comprises basic information corresponding to the model component, size information corresponding to the model component and prefabricated hole information corresponding to the model component;

the construction site image acquisition module is used for acquiring images of a construction site corresponding to the building, and then scanning and shooting the construction site corresponding to the building by using a three-dimensional laser scanner carried by an unmanned aerial vehicle, so as to obtain a three-dimensional image corresponding to the construction site of the building;

the information integration module is used for integrating information of each model component of the building and a three-dimensional image corresponding to the construction site of the building, and further generating an assembly video corresponding to the component corresponding to each model component of the building through a third-party website;

the production component information acquisition module is used for acquiring information corresponding to the building production components, further acquiring the quantity of the production components provided by a building component supplier, numbering the production components according to the numbering sequence of each model component, and sequentially marking the production components as 1 ', 2',. i ',. n';

the production component prefabricated hole basic information acquisition module is used for acquiring basic information corresponding to each prefabricated hole of each production component of the building, and then numbering the prefabricated holes corresponding to each production component according to a preset sequence, wherein the number of the prefabricated holes is sequentially marked as 1,2,. j,. m;

the data processing and analyzing module is used for analyzing and processing the information corresponding to each production component and the basic information of each production component prefabricated hole.

Preferably, the basic information corresponding to the model component comprises a model componentThe model corresponding to the model component, the installation position corresponding to the model component and the flatness corresponding to the model component, the size information corresponding to the model component comprises the length, the width and the thickness corresponding to the model component, the prefabricated hole information corresponding to the model component comprises the number of prefabricated holes corresponding to the model component, the length, the width and the depth corresponding to each prefabricated hole of the model component and the position information corresponding to each prefabricated hole of the model component, and then each model component information set J is constructed_w(J_w1,J_w2,...J_wi,...J_wn)，J_wi represents w-th information corresponding to the ith model component of the building, w represents construction information, and w is a1, a2, a3, a1, a2 and a3 respectively represent basic information corresponding to the model component, size information corresponding to the model component and prefabricated hole information corresponding to the model component.

Preferably, the production component includes basic information corresponding to the production component and size information corresponding to the production component, where the basic information corresponding to the production component includes a model corresponding to the production component and a flatness corresponding to the production component, and the size information corresponding to the production component includes a length, a width and a thickness corresponding to the production component, so as to construct each production component information set S_e(S_e1′,S_e2′,...S_ei′，...S_en′),S_ei 'indicates the e-th information corresponding to the i' th production component provided by the building supplier, e indicates the production component information, and e-b 1, b2, b1 and b2 indicate the production component basic information and the production component size information, respectively.

Preferably, the basic information of the prefabricated holes of the production component comprises the length, width, depth and position corresponding to each prefabricated hole of the production component, and further, a basic information set Y of each prefabricated hole of each production component is constructed_z ^d′(Y_z ^d′1,Y_z ^d′2,...Y_z ^d′j,...Y_z ^d′m)，Y_z ^d′j represents the z th basic information corresponding to the jth prefabricated hole of the d' th production component provided by the building supplier, z represents the basic information of the prefabricated hole of the production component, and z represents the length and the width of the prefabricated hole of the production component respectivelyDegree, depth and position.

Preferably, the data processing and analyzing module is configured to analyze and process the basic information corresponding to each production component, compare the basic information corresponding to each production component with the basic information corresponding to each model component, and further count that the basic information of each production component conforms to the influence coefficient.

Preferably, the data processing and analyzing module is configured to analyze and process the size information corresponding to each production component, compare the size information corresponding to each production component with the size information corresponding to each model component, and count the comprehensive coincidence influence coefficient of the size information of each production component.

Preferably, the data processing and analyzing module is configured to perform comprehensive analysis and processing on information corresponding to each production component, and further count the comprehensive coincidence influence coefficient of each production component information according to the counted basic information coincidence influence coefficient and the calculated dimensional information coincidence influence coefficient of each production component.

Preferably, the data processing and analyzing module is configured to analyze and process basic information corresponding to each prefabricated hole of each production component, further compare the basic information corresponding to each prefabricated hole of each production component with the prefabricated hole information corresponding to each model component, and count the comprehensive coincidence influence coefficient of the basic information of each prefabricated hole of each production component.

Preferably, the data processing and analyzing module is further configured to perform comprehensive analysis and processing on information corresponding to each production component and basic information corresponding to each prefabricated hole of each production component, further count that the comprehensive production quality of each production component conforms to the influence coefficient according to the counted comprehensive conformity influence coefficient of each production component information and the comprehensive conformity influence coefficient of each production component prefabricated hole, compare the comprehensive production quality conformity influence coefficient of each production component with a preset production quality conformity influence coefficient corresponding to a rework component, if the comprehensive production quality conformity influence coefficient corresponding to a certain production component is greater than the production quality conformity influence coefficient corresponding to the rework component, mark the component as a rework component, and count the number of the rework component and the number corresponding to each rework component.

Preferably, the remote control terminal is used for sending information, wherein the information sending comprises production information sending and rework information sending.

The invention has the beneficial effects that:

(1) according to the intelligent cloud management platform for engineering construction based on the BIM building three-dimensional model technology, the member information acquisition module, the production member information acquisition module and the production member prefabricated hole basic information acquisition module are combined with the data processing and analysis module to comprehensively analyze and manage the purchasing of the building engineering member, the information corresponding to each purchased production member and the basic information corresponding to each prefabricated hole of each production member, the problem that the construction material purchasing process is not managed in the existing building engineering construction management method is solved, waste caused by material field processing and pollution of processing materials to the construction area environment are effectively avoided, the standardization and the controllability of a construction field are realized, and meanwhile, the construction progress of the building engineering is effectively guaranteed.

(2) According to the invention, information integration is carried out on each component model of the building and the three-dimensional image corresponding to the construction site of the building in the information integration module, so that the production accuracy of the components of a supplier is effectively improved, and meanwhile, the understanding efficiency of the supplier on the installation of each component can be effectively improved in a video mode, so that the production efficiency and the production quality of the components are greatly improved.

(3) According to the invention, the production information is sent to the component supplier corresponding to the construction project at the remote control terminal, so that the problems of complexity and low purchasing efficiency of the existing component purchasing process are effectively solved, the purchasing efficiency of the component is further greatly improved, meanwhile, the quality problem and the progress problem of the construction project caused by the component problem are avoided by sending the rework information to the component supplier corresponding to the construction project, and the smoothness and the controllability of the construction project are further greatly improved.

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 schematic diagram of the system module connection of the present invention.

Detailed Description

While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.

Referring to fig. 1, an engineering construction intelligent cloud management platform based on a BIM building three-dimensional model technology includes a component number acquisition module, a component information acquisition module, a construction site image acquisition module, an information integration module, a production component information acquisition module, a production component prefabricated hole basic information acquisition module, a data processing and analysis module and a remote control terminal;

the data processing and analyzing module is respectively connected with the component information acquisition module, the production component prefabricated hole basic information acquisition module and the remote control terminal, the component number acquisition module is connected with the component information acquisition module, and the information integration module is respectively connected with the component information acquisition module, the construction site image acquisition module and the remote control terminal;

specifically, the basic information corresponding to the model member includes a model corresponding to the model member, an installation position corresponding to the model member, and a flatness corresponding to the model member, the size information corresponding to the model member includes a length, a width, and a thickness corresponding to the model member, the preformed hole information corresponding to the model member includes the number of preformed holes corresponding to the model member, a length, a width, and a depth corresponding to each preformed hole of the model member, and the position information corresponding to each preformed hole of the model member, thereby constructing each model member information set J_w(J_w1,J_w2,...J_wi,...J_wn)，J_wi represents w-th information corresponding to the ith model component of the building, w represents construction information, and w is a1, a2, a3, a1, a2 and a3 respectively represent basic information corresponding to the model component, size information corresponding to the model component and prefabricated hole information corresponding to the model component.

according to the embodiment of the invention, the information integration module integrates the information of each component model of the building and the three-dimensional image corresponding to the construction site of the building, so that the production accuracy of the components of a supplier is effectively improved, the understanding efficiency of the supplier on the installation of each component can be effectively improved in a video mode, and the production efficiency and the production quality of the components are greatly improved.

specifically, the production component comprises basic information corresponding to the production component and size information corresponding to the production component, wherein the basic information corresponding to the production component comprises a model corresponding to the production component and a flatness corresponding to the production component, the size information corresponding to the production component comprises a length, a width and a thickness corresponding to the production component, and then each production component information set S is constructed_e(S_e1′,S_e2′,...S_ei′，...S_en′),S_ei 'indicates the e-th information corresponding to the i' th production component provided by the building supplier, e indicates the production component information, and e-b 1, b2, b1 and b2 indicate the production component basic information and the production component size information, respectively.

The production component information acquisition module further comprises a plurality of information acquisition units, the laser distance meters in the information acquisition units are used for measuring the length and the width corresponding to each production component, the ultrasonic thickness meters corresponding to the information acquisition units are used for measuring the thickness corresponding to each production component, and meanwhile, the flatness detectors in the information acquisition units are used for detecting the flatness corresponding to each production component.

According to the embodiment of the invention, the information acquisition unit is used for carrying out detailed detection on the dimension information corresponding to each production component, so that the corresponding acquisition efficiency of the dimension information of the production component and the reference of the acquisition result are greatly improved, and a powerful data basis is provided for the subsequent analysis of the dimension information of each production component.

specifically, the basic information of the prefabricated holes of the production component comprises the pairs of the prefabricated holes of the production componentThe length, width, depth and position of the prefabricated holes are determined, and basic information sets Y of the prefabricated holes of the production components are constructed_z ^d′(Y_z ^d′1,Y_z ^d′2,...Y_z ^d′j,...Y_z ^d′m)，Y_z ^d′j represents the z-th basic information corresponding to the jth prefabricated hole of the d' production member provided by the building supplier, z represents the basic information of the prefabricated hole of the production member, and z represents the length, the width, the depth and the position of the prefabricated hole of the production member respectively, wherein the z represents the c1, the c2, the c3, the c4, the c1, the c2, the c3 and the c 4.

The data processing and analyzing module is used for analyzing and processing the information corresponding to each production component and the basic information of each production component prefabricated hole;

specifically, the data processing and analyzing module is used for analyzing and processing the basic information corresponding to each production component, comparing the basic information corresponding to each production component with the basic information corresponding to each model component, and further counting the basic information coincidence influence coefficient of each production component.

The specific analysis process of the basic information of each production component comprises the following steps:

the method comprises the steps of obtaining information sets of each model component and information sets of each production component, further obtaining the model corresponding to each model component and the flatness corresponding to each model component, simultaneously obtaining the model corresponding to each production component and the flatness corresponding to each production component, comparing the model corresponding to each model component with the model corresponding to each production component according to the model corresponding to each model component and the model corresponding to each production component, analyzing the quantity and the flatness corresponding to each model production component if the model corresponding to each model component is consistent with the model corresponding to each production component, recording the production component as an abnormal production component if a model inconsistent with the model component appears in the model of a certain production component, and counting the quantity of the abnormal production components and the model corresponding to the abnormal production component.

The specific analysis process of the number and the flatness corresponding to each type of production component comprises the following steps:

a1, obtaining models corresponding to the model members, comparing the models corresponding to the model members with each other, further counting the number of the models corresponding to the model members in the BIM three-dimensional model, numbering the models corresponding to the model members in the BIM three-dimensional model according to a preset sequence, sequentially marking the models as 1,2, i.e., f, i.q, and marking the models corresponding to the model members in the BIM three-dimensional model as member models;

a2, respectively comparing the model corresponding to each model component with the model corresponding to each production component, and further counting the number of model components corresponding to each component model and the number of production components corresponding to each component model;

a3, comparing the number of the production components corresponding to each model of each component with the number of the model components corresponding to each model of the component, and further counting the number of the production components of each model according with the influence coefficient, wherein the calculation formula is

α_rIndicating that the corresponding number of the r component model production components accords with the influence coefficient, T_r,T′_rRespectively representing the number of production components corresponding to an r-th component model and the number of model components corresponding to the r-th component model, wherein r represents a component model number, and r is 1,2,. f,. q;

a4, obtaining the flatness corresponding to each model component and the flatness corresponding to each production component, comparing the flatness corresponding to each production component with the flatness corresponding to each model component, and further counting the flatness coincidence influence coefficient of each production component, wherein the calculation formula is as follows

β_d′Indicating that the flatness corresponding to the d' th production member corresponds to the influence coefficient, P_d′Denotes the flatness, P ' corresponding to the d ' th production member '_dIndicating the flatness corresponding to the d-th model component, d indicating the model component number, d being 1, 2.. i.. n, d 'indicating the production component number, d' being 1 ', 2.. i.. n';

a5, according to the statistical conformity of the quantity of each type of production component and the flatness of each production component, further, the statistical conformity of the basic information corresponding to each production component is the influence coefficient, and the calculation formula is

δ_d′And (3) indicating that the basic information corresponding to the d' th production component conforms to the influence coefficient, and q indicates the number of the model numbers of the components.

In the embodiment of the invention, the model corresponding to the production component corresponds to the model corresponding to the model component one by one, the number corresponding to the production component corresponds to the number corresponding to the model component one by one, the number of the prefabricated hole corresponding to each production component corresponds to the number of the prefabricated hole corresponding to each model component one by one, and the number of the central point of each prefabricated hole corresponds to the number of each prefabricated hole one by one, namely, in the calculation process of a specific substitution formula, the substitution sequence of the production 1 component number and the model component number is kept consistent, and the corresponding calculation is carried out.

Specifically, the data processing and analyzing module is used for analyzing and processing the size information corresponding to each production component, comparing the size information corresponding to each production component with the size information corresponding to each model component, and then counting the comprehensive coincidence influence coefficient of the size information of each production component.

The specific analysis process of the size information is as follows: according to the obtained information sets of the model components and the information sets of the production components, the length, the width and the thickness corresponding to the construction of the model components and the length, the width and the thickness corresponding to the production components are further obtained, the length, the width and the thickness corresponding to the production components are respectively compared with the length, the width and the thickness corresponding to the model components, the condition that the dimension information of the production components accords with the influence coefficient is further counted, and the calculation formula is that

φ_u ^d′Denotes a coincidence influence coefficient corresponding to the u-th dimensional information of the d' -th production member, s1_d′,s2_d′,s3_d′To representLength, width, thickness, s1 ' corresponding to the d ' th production component '_d,s2′_d,s3′_dThe length, the width and the thickness corresponding to the d-th model component are shown, u represents the size information of the produced component, u is s1, s2, s3, s1, s2 and s3 respectively represent the length, the width and the thickness corresponding to each produced component, the size information of each produced component is calculated according to the statistical coincidence influence coefficient of each size information of each produced component, and further the comprehensive coincidence influence coefficient of each size information of each produced component is calculated, and the calculation formula is that

And showing the comprehensive coincidence influence coefficient corresponding to the dimension information of the d' th production component.

Specifically, the data processing and analyzing module is used for comprehensively analyzing and processing the information corresponding to each production component, and further counting the comprehensive coincidence influence coefficient of each production component information according to the counted basic information coincidence influence coefficient corresponding to each production component and the counted comprehensive coincidence influence coefficient of each production component size information.

The calculation formula of the comprehensive coincidence influence coefficient of the information of each production component is

γ_d′And indicating the comprehensive coincidence influence coefficient corresponding to the d' th production component information.

Specifically, the data processing and analyzing module is used for analyzing and processing the basic information corresponding to each prefabricated hole of each production component, comparing the basic information corresponding to each prefabricated hole of each production component with the prefabricated hole information corresponding to each model component, and counting the comprehensive coincidence influence coefficient of the basic information of each prefabricated hole of each production component.

The process of analyzing and processing the basic information corresponding to each prefabricated hole of each production component comprises the following steps:

b1, acquiring basic information sets of each prefabricated hole of each production component, further acquiring the number of the prefabricated holes of each production component, the length, the width, the depth and the position corresponding to each prefabricated hole of each production component, and acquiring the number of the prefabricated holes corresponding to each model component, the length, the width and the depth corresponding to each prefabricated hole of each model component and the position information corresponding to each prefabricated hole of each model component according to the acquired information sets of each model component;

b2, comparing the number of the prefabricated holes of each production component with the number of the prefabricated holes corresponding to each model component, and counting the number of the prefabricated holes of each production component according with the influence coefficient, wherein the calculation formula is

η_d′Indicating that the number of prefabricated holes corresponding to the d' th production component meets the influence coefficient, R_d′Representing the number of prefabricated holes, R ' corresponding to the d ' production member '_dThe number of the prefabricated holes corresponding to the d model component is shown.

B3, comparing the length, width and depth of each prefabricated hole of each production component with the length, width and depth of each model component, and further counting the size information of each prefabricated hole of each production component according with the influence coefficient, wherein the calculation formula is

μ_k ^d′The method comprises the steps of representing a coincidence influence coefficient corresponding to the z th basic information of the tth prefabricated hole of the d' th production component, wherein t represents the number of the prefabricated holes of each production component, and t is 1,2,. j,. m; z represents basic information of each prefabricated hole of each production component, z is c1, c2, c3, t 'represents a number corresponding to each prefabricated hole of each model component, and t' is 1 ', 2'. multidot.j '. multidot.m', c1_d′ ^t,c2_d′ ^t,c3_d′ ^tRespectively represents the length, width and depth, c1 ' corresponding to the t prefabricated hole of the d ' production member '_d ^t′,c2′_d ^t′,c3′_d ^t′Respectively showing the length, width and depth of the t' prefabricated hole of the d model component, and calculating the sizes of prefabricated holes of the production componentsThe information accords with the influence coefficient, and then the comprehensive coincidence influence coefficient of the size information of each prefabricated hole of each production component is counted, and the calculation formula is

The size information corresponding to the tth prefabricated hole of the d' th production component is comprehensively conformed with the influence coefficient;

b4, according to the position information corresponding to each prefabricated hole of each model component, using the center point corresponding to each prefabricated hole of each model component as a prefabricated hole detection point, numbering each prefabricated detection point of each model component as 1,2, p, k, using the center point corresponding to each model component as a coordinate origin to establish a plane coordinate system of each model component, and further obtaining a plane coordinate Q corresponding to each prefabricated hole detection point of each model component_d ^v(x_d ^v,y_d ^v),Q_d ^vRepresents the corresponding plane coordinate, x, of the ith prefabricated hole detection point of the model component_d ^v,y_d ^vRespectively representing numerical values of a vth prefabricated hole detection point of the d model component in the x-axis direction and the y-axis direction, establishing a plane coordinate system of each production component according to the establishing method of the plane coordinate system of each model component, sequentially numbering prefabricated hole detection points of each production component as 1 ', 2',. p ',. k', and further acquiring plane coordinates Q 'corresponding to the prefabricated hole detection points of each production component'_d′ ^v′(x′_d′ ^v′,y′_d′ ^v′)，Q′_d′ ^v′Representing the plane coordinate, x 'corresponding to the v' th prefabricated hole detection point of the d 'production member'_d′ ^v′,y′_d′ ^v′Respectively representing the values of the detection point of the v 'th prefabricated hole of the d' th production component in the x-axis direction and the y-axis direction;

and the construction of the plane coordinate system of each production component further comprises the steps of scanning each production construction by using a three-dimensional laser scanner, further inputting a three-dimensional image corresponding to each production construction into a BIM (building information modeling) model corresponding to the building, and further establishing the plane coordinate system of each production component according to the establishment method of the plane coordinate system of each model component.

B5, comparing the plane coordinates corresponding to the prefabricated hole detection points of the production components with the plane coordinates corresponding to the prefabricated hole detection points of the model components, and further counting the position coincidence influence coefficients of the prefabricated holes of the production components, wherein the calculation formula is

χ_d′ ^v′Indicating that the position corresponding to the v 'th prefabricated hole detection point of the d' th production component corresponds to the influence coefficient, and indicating the correction coefficient of the prefabricated hole detection point by sigma;

b6, according to the statistical conformity of the number of the prefabricated holes of each production component to the influence coefficient, the comprehensive conformity of the size information of each prefabricated hole of each production component to the influence coefficient and the conformity of the position information of each prefabricated hole of each production component to the influence coefficient, further to calculate the comprehensive conformity of the basic information of each prefabricated hole of each production component to the influence coefficient, the calculation formula is

λ_d′And indicating that the basic information of the prefabricated hole corresponding to the d' production component comprehensively conforms to the influence coefficient.

Specifically, the data processing and analyzing module is further configured to perform comprehensive analysis and processing on information corresponding to each production component and basic information corresponding to each prefabricated hole of each production component, further count that the comprehensive production quality of each production component conforms to the influence coefficient according to the counted comprehensive conformity influence coefficient of each production component information and the comprehensive conformity influence coefficient of each production component prefabricated hole, compare the comprehensive production quality conformity influence coefficient of each production component with the preset production quality conformity influence coefficient corresponding to the rework component, if the comprehensive production quality conformity influence coefficient corresponding to a certain production component is greater than the production quality conformity influence coefficient corresponding to the rework component, mark the component as the rework component, and count the number of the rework component and the number corresponding to each rework component.

The comprehensive production quality of each production component conforms to the calculation formula of the influence coefficient

ξ_d′And (4) representing that the comprehensive production quality corresponding to the d' production component meets the influence coefficient.

The embodiment of the invention comprehensively analyzes and manages the information corresponding to each production component of the building engineering and the basic information corresponding to each prefabricated hole of each production component in the data processing and analyzing module, solves the problem that the construction material purchasing process is not managed in the existing construction management method of the building engineering, effectively avoids waste caused by material field processing and pollution of processing materials to the environment of a construction area, realizes the standardization and controllability of a construction field, and simultaneously effectively ensures the construction progress of the building engineering.

The remote control terminal is used for sending information, wherein the information sending comprises production information sending and rework information sending.

The production information is sent to be used for sending the assembly video corresponding to the component corresponding to each model component of the building and the model corresponding to each model component of the building to the component supplier corresponding to the building engineering;

the rework information sending is used for sending the number of the abnormally produced components, the model number corresponding to the abnormally produced components, the number of the construction rework components and the number corresponding to each rework component to the component supplier corresponding to the construction project;

according to the embodiment of the invention, the production information is sent to the component supplier corresponding to the construction project at the remote control terminal, so that the problems of complexity in the existing component purchasing process and low purchasing efficiency are effectively solved, the purchasing efficiency of the component is further greatly improved, meanwhile, the reworking information is sent to the component supplier corresponding to the construction project, the quality problem and the progress problem of the construction project caused by the component problem are avoided, and the smoothness and the controllability of the construction project are further greatly improved.

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

1. The utility model provides an engineering construction intelligence cloud management platform based on BIM building three-dimensional model technique which characterized in that: the data processing and analyzing module is respectively connected with the component information acquisition module, the production component prefabricated hole basic information acquisition module and the remote control terminal, the component number acquisition module is connected with the component information acquisition module, and the information integration module is respectively connected with the component information acquisition module, the construction site image acquisition module and the remote control terminal;

2. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the basic information corresponding to the model component comprises the model corresponding to the model component, the installation position corresponding to the model component and the flatness corresponding to the model component, the size information corresponding to the model component comprises the length, the width and the thickness corresponding to the model component, the prefabricated hole information corresponding to the model component comprises the number of prefabricated holes corresponding to the model component, the length, the width and the depth corresponding to each prefabricated hole of the model component and the position information corresponding to each prefabricated hole of the model component, and then each model component information set J is constructed_w(J_w1,J_w2,...J_wi,...J_wn)，J_wi represents w-th information corresponding to the ith model component of the building, w represents construction information, and w is a1, a2, a3, a1, a2 and a3 respectively represent basic information corresponding to the model component, size information corresponding to the model component and prefabricated hole information corresponding to the model component.

3. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the production component comprises basic information corresponding to the production component and size information corresponding to the production component, wherein the pair of production componentsThe corresponding basic information comprises the model corresponding to the production component and the flatness corresponding to the production component, the size information corresponding to the production component comprises the length, the width and the thickness corresponding to the production component, and then, an information set S of each production component is constructed_e(S_e1′,S_e2′,...S_ei′，...S_en′),S_ei 'indicates the e-th information corresponding to the i' th production component provided by the building supplier, e indicates the production component information, and e-b 1, b2, b1 and b2 indicate the production component basic information and the production component size information, respectively.

4. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the basic information of the prefabricated holes of the production component comprises the length, width, depth and position corresponding to each prefabricated hole of the production component, and further, a basic information set Y of each prefabricated hole of each production component is constructed_z ^d′(Y_z ^d′1,Y_z ^d′2,...Y_z ^d′j,...Y_z ^d′m)，Y_z ^d′j represents the z-th basic information corresponding to the jth prefabricated hole of the d' production member provided by the building supplier, z represents the basic information of the prefabricated hole of the production member, and z represents the length, the width, the depth and the position of the prefabricated hole of the production member respectively, wherein the z represents the c1, the c2, the c3, the c4, the c1, the c2, the c3 and the c 4.

5. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the data processing and analyzing module is used for analyzing and processing the basic information corresponding to each production component, comparing the basic information corresponding to each production component with the basic information corresponding to each model component, and further counting the basic information of each production component according with the influence coefficient.

6. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the data processing and analyzing module is used for analyzing and processing the size information corresponding to each production component, comparing the size information corresponding to each production component with the size information corresponding to each model component, and further counting the comprehensive coincidence influence coefficient of the size information of each production component.

7. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the data processing and analyzing module is used for comprehensively analyzing and processing the information corresponding to each production component, and further counting the comprehensive coincidence influence coefficient of the information of each production component according to the counted basic information coincidence influence coefficient corresponding to each production component and the counted size information of each production component.

8. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the data processing and analyzing module is used for analyzing and processing the basic information corresponding to each prefabricated hole of each production component, further comparing the basic information corresponding to each prefabricated hole of each production component with the prefabricated hole information corresponding to each model component, and counting the comprehensive coincidence influence coefficient of the basic information of each prefabricated hole of each production component.

9. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the data processing and analyzing module is further used for comprehensively analyzing and processing information corresponding to each production component and basic information corresponding to each prefabricated hole of each production component, comprehensively conforming to influence coefficients according to the counted information of each production component and basic information of each prefabricated hole of each production component, further counting comprehensive production quality conforming to influence coefficients of each production component, comparing the comprehensive production quality conforming to influence coefficients of each production component with preset production quality conforming to influence coefficients corresponding to reworked components, recording a certain production component as a reworked component if the comprehensive production quality conforming to influence coefficient corresponding to the production component is larger than the production quality conforming to influence coefficient corresponding to the reworked component, and counting the number of the reworked components and the number corresponding to each reworked component.

10. The BIM building three-dimensional model technology-based engineering construction intelligent cloud management platform of claim 1, wherein: the remote control terminal is used for sending information, wherein the information sending comprises production information sending and rework information sending.