CN112069464B - Building curtain wall engineering acceptance detection management system based on big data - Google Patents

Building curtain wall engineering acceptance detection management system based on big data Download PDF

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CN112069464B
CN112069464B CN202010924748.6A CN202010924748A CN112069464B CN 112069464 B CN112069464 B CN 112069464B CN 202010924748 A CN202010924748 A CN 202010924748A CN 112069464 B CN112069464 B CN 112069464B
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范玲珍
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Ningbo Puhua Construction Engineering Co.,Ltd.
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Abstract

The invention discloses a building curtain wall engineering acceptance detection management system based on big data, which comprises a region division module, a detection point arrangement module, a quality parameter detection module, a quality parameter analysis module, a wind power generation module, a qualified quality detection module, a qualified quality analysis module, an analysis server, a display terminal and a storage database, wherein the region division module is used for dividing a building curtain wall into a plurality of regions; the invention analyzes whether the quality of the building curtain walls of each subregion is preliminarily qualified or not by detecting the numerical values of the quality parameters of the building curtain walls of each subregion, applies pressure to the building curtain walls of each subregion with preliminarily qualified quality by different wind power, detects the numerical values of the quality parameters of the building curtain walls of each subregion with different wind power, calculates the comprehensive influence coefficient of the quality of the building curtain walls of each subregion with wind power application, judges whether the quality of the building curtain walls of each subregion with wind power application is finally qualified or not, and maintains or replaces the building curtain walls of each subregion with finally unqualified quality, thereby ensuring the life and property safety of people.

Description

Building curtain wall engineering acceptance detection management system based on big data
Technical Field
The invention relates to the field of constructional engineering quality detection, in particular to a big data-based construction curtain wall engineering acceptance detection management system.
Background
At present, curtain walls become new worldwide trends and are widely applied to building design, the concise and transparent appearance decoration effect of the curtain walls provides a technical strength and a time interest concept for people, so that the curtain walls become important landmark contents for modern city development, meanwhile, the building curtain wall engineering is a special social product, the required quality is high, and how to improve the quality of the building curtain walls becomes the content of attention required by people.
However, the existing building curtain wall quality detection technology generally has some defects, the traditional building curtain wall quality detection mainly adopts manual detection, the monitoring level of the manual visual inspection monitoring method is low, the reliability is not high, and the quality of the building curtain wall cannot be detected by means of manual experience, so that whether the quality of the building curtain wall is qualified or not cannot be accurately judged, huge loss is brought to economy of people, meanwhile, the traditional detection technology can only detect the quality of the building curtain wall stressed by natural wind power, uncertainty exists, the building curtain wall falls off due to overlarge wind power, traffic accidents are easily caused, and huge physical and mental damage is brought to people.
Disclosure of Invention
The invention aims to provide a building curtain wall engineering acceptance detection management system based on big data, which is characterized in that detection points are arranged on each divided sub-area through a detection point arrangement module, the quality parameter values of the building curtain walls of each sub-area are detected, whether the quality of the building curtain walls of each sub-area is preliminarily qualified or not is analyzed, the building curtain walls of each sub-area with preliminarily qualified quality are pressed by different wind power, the comparison difference value of the quality parameter values of the building curtain walls of each sub-area with different wind power pressing is detected and analyzed, the quality comprehensive influence coefficient of the building curtain walls of each sub-area with wind power pressing is calculated, whether the quality of the building curtain walls of each sub-area with wind power pressing is finally qualified or not is judged by comparison, and the building curtain walls of each sub-area with finally unqualified quality are maintained or replaced.
The purpose of the invention can be realized by the following technical scheme:
a building curtain wall project acceptance detection management system based on big data comprises a region division module, a detection point arrangement module, a quality parameter detection module, a quality parameter analysis module, a wind power generation module, a qualified quality detection module, a qualified quality analysis module, an analysis server, a display terminal and a storage database;
the analysis server is respectively connected with the quality parameter analysis module, the qualified quality analysis module, the wind power generation module, the display terminal and the storage database, the storage database is respectively connected with the region division module, the quality parameter analysis module and the qualified quality analysis module, the quality parameter detection module is respectively connected with the detection point arrangement module and the quality parameter analysis module, and the qualified quality detection module is respectively connected with the wind power generation module and the qualified quality analysis module;
the area dividing module is used for dividing a building curtain wall area to be checked and accepted, dividing the building curtain wall area into a plurality of sub-areas with the same area according to a gridding equal dividing mode, numbering the plurality of divided sub-areas sequentially from left to right and from top to bottom according to a set sequence, wherein the numbers are respectively 1,2, a.
The detection point distribution module is used for distributing detection points for all sub-areas of the building curtain wall to be checked and accepted, distributing the detection points for all the sub-areas in a uniformly distributed mode, enabling all the detection points to correspond to all the sub-areas one by one, and sending the detection points distributed for all the sub-areas to the quality parameter detection module;
the quality parameter detection module is used for receiving the detection points distributed in each subarea and sent by the detection point distribution module, detecting the quality of the building curtain wall of each received subarea, detecting the flatness, the verticality, the levelness and the crack area in the quality parameters of the building curtain wall of each subarea, and forming a numerical value set W of each quality parameter of the building curtain wall of each subareanR(w1R,w2R,...,wiR,...,wiR),wiR represents the quality parameter value of the building curtain wall of the ith sub-region, R is R1, R2, R3, R4 and R1 represent the flatness in the quality parameter of the building curtain wall, R2 represents the verticality in the quality parameter of the building curtain wall, R3 represents the levelness in the quality parameter of the building curtain wall, R4 represents the crack area in the quality parameter of the building curtain wall, and the quality parameter value sets of the building curtain walls of the sub-regions are sent to the quality parameter analysis module;
the quality parameter analysis module is used for receiving the quality parameter value sets of the building curtain walls of the sub-areas sent by the quality parameter detection module, extracting the standard flatness range, the standard verticality range, the standard levelness range and the standard crack area range in the building curtain wall quality parameters stored in the storage database, comparing the quality parameter values of the building curtain walls of the sub-areas with different wind pressures with the standard value range of the building curtain wall quality parameters with the corresponding wind pressures, if the quality parameter values of the building curtain walls of the sub-areas are all in the standard value range of the corresponding building curtain wall quality parameters, the quality of the building curtain walls of the sub-areas is preliminarily qualified, and if the quality parameter values of the building curtain walls of the sub-areas are out of the standard value range of the corresponding building curtain wall quality parameters, the quality of the building curtain walls of the sub-areas is preliminarily unqualified, counting the number of the subareas corresponding to the building curtain wall with the preliminarily qualified quality and the number of the subareas corresponding to the building curtain wall with the preliminarily unqualified quality, and sending the number of the subareas corresponding to the building curtain wall with the preliminarily qualified quality and the number of the subareas corresponding to the building curtain wall with the preliminarily unqualified quality to an analysis server;
the analysis server is used for receiving the subregion number corresponding to the building curtain wall with the preliminarily qualified quality and the subregion number corresponding to the building curtain wall with the preliminarily unqualified quality sent by the quality parameter analysis module to form each subregion set W 'with the preliminarily qualified building curtain wall quality'm(w′1,w′2,...,w′j,...,w′m),m≤n,w′jThe subareas with the preliminarily qualified quality of the jth building curtain wall are represented, all the subareas with the preliminarily qualified quality of the building curtain wall are collectively sent to the wind power generation module, and meanwhile, the subarea numbers corresponding to the building curtain wall with the preliminarily unqualified quality are sent to the display terminal;
the wind power generation module comprises a wind power generation device, wherein the wind power generation device can realize semicircular amplitude rotation and can generate wind power with different wind power grades, each wind power grade is primary wind power, secondary wind power, tertiary wind power and quaternary wind power, the wind power grades are used for receiving each subregion set with preliminarily qualified quality of the building curtain wall sent by the analysis server, the wind power generation device generates wind power with different wind power grades of each direction angle and applies pressure to each subregion building curtain wall with preliminarily qualified quality, and each subregion with preliminarily qualified quality of the building curtain wall with pressure applied by different wind power is sent to the qualified quality detection module;
the qualified quality detection module is used for receiving different wind pressure exerted by the wind power generation moduleAnd (3) in each subarea with preliminarily qualified building curtain wall quality, detecting the building curtain wall quality of each subarea detection point pressed by received different wind power, detecting the flatness, the verticality, the levelness and the crack area in the building curtain wall quality parameters of each subarea pressed by different wind power, and forming a quality parameter value set W 'of the building curtain wall of each subarea pressed by different wind power'mR(w′1R,w′2R,...,w′jR,...,w′mR),m≤n,w′jRExpressing the value of the quality parameter of the jth sub-area building curtain wall corresponding to the wind pressure of the wind power grade corresponding to the theta direction angle, wherein f is f1,f2,f3,f4;f1,f2,f3,f4Respectively expressed as primary wind, secondary wind, tertiary wind and quaternary wind, theta ═ theta12,...,θk,...,θx,0≤θkThe quality parameter values of the building curtain walls of the sub-areas pressed by different wind power are collected and sent to a qualified quality analysis module;
the qualified quality analysis module is used for receiving each quality parameter value set of each sub-area building curtain wall subjected to different wind pressure sent by the qualified quality detection module, extracting a standard flatness range, a standard verticality range, a standard levelness range and a standard crack area range in the building curtain wall quality parameters subjected to different wind pressure stored in the storage database, comparing each quality parameter value of each sub-area building curtain wall subjected to different wind pressure with the standard value range of the building curtain wall quality parameter subjected to corresponding wind pressure, and obtaining a comparison difference value set delta W 'of each quality parameter value of each sub-area building curtain wall subjected to different wind pressure'mR(Δw′1R,Δw′2R,...,Δw′jR,...,Δw′mR),m≤n,Δw′jRThe R quality parameter value of the jth sub-area building curtain wall expressed as the wind pressure of the fth wind power grade corresponding to the theta direction angle and the corresponding valueThe comparison difference value between the standard value ranges of the building curtain wall quality parameters exerted by the wind power is obtained, and the comparison difference value sets of the quality parameter values of the building curtain walls of the sub-areas exerted by the different wind powers are sent to the analysis server;
the analysis server is used for receiving the comparison difference value set of the numerical values of the quality parameters of the building curtain walls of the sub-areas with different wind pressures sent by the qualified quality analysis module, calculating the comprehensive influence coefficient of the quality of the building curtain walls of the sub-areas with the wind pressures, extracting and storing the standard comprehensive influence coefficient of the building curtain walls stored in the database, comparing the comprehensive influence coefficient of the quality of the building curtain walls of the sub-areas with the stored standard comprehensive influence coefficient of the building curtain walls, if the comprehensive influence coefficient of the quality of the building curtain walls of a certain sub-area with the wind pressures is less than or equal to the standard comprehensive influence coefficient of the quality of the building curtain walls, the quality of the building curtain walls of the sub-area is finally qualified, if the comprehensive influence coefficient of the quality of the building curtain walls of a certain sub-area with the wind pressures is greater than the standard comprehensive influence coefficient of the, counting the number of each subarea corresponding to the building curtain wall with the final unqualified quality, and sending the number of each subarea corresponding to the building curtain wall with the final unqualified quality to a display terminal;
the display terminal is used for receiving the subregion number corresponding to the building curtain wall with preliminary unqualified quality and the subregion number corresponding to the building curtain wall with final unqualified quality sent by the analysis server, displaying the received subregion numbers, and maintaining or replacing the subregion corresponding to the building curtain wall with unqualified quality by related personnel according to the display;
the storage database is used for receiving the serial numbers of the plurality of sub-areas sent by the area dividing module, storing a standard flatness range, a standard verticality range, a standard levelness range and a standard crack area range in the quality parameters of the building curtain wall, simultaneously storing the standard flatness range, the standard verticality range, the standard levelness range and the standard crack area range in the quality parameters of the building curtain wall pressed by different wind powers, and simultaneously storing the standard flatness range, the standard verticality range, the standard levelness range and the standard crack area range of each quality parameter in the building curtain wallQuasi-mass influence coefficient, each quasi-mass influence coefficient is lambdaR1、λR2、λR3、λR4,λR1R2R3R4Respectively expressing standard quality influence coefficients of flatness, verticality, levelness and crack area in the quality parameters of the building curtain wall in sequence, and storing the standard quality comprehensive influence coefficient of the building curtain wall;
furthermore, the quality parameter detection module comprises a flatness detection unit, a verticality detection unit, a levelness detection unit and a crack area detection unit, wherein the flatness detection unit is a flatness detector and is used for detecting the flatness in the quality parameters of the building curtain walls of the sub-areas, the verticality detection unit is a theodolite and is used for detecting the verticality in the quality parameters of the building curtain walls of the sub-areas, the levelness detection unit is a level and is used for detecting the levelness in the quality parameters of the building curtain walls of the sub-areas, and the crack area detection unit is an x-ray detector and is used for acquiring crack images of the quality of the building curtain walls of the sub-areas and acquiring the crack areas in the quality parameters of the building curtain walls of the;
furthermore, the wind power generation device comprises a semi-cylindrical base, a lifter and a wind power generator, wherein an angle scale is arranged on the top surface of the semi-cylindrical base, a groove is formed in the middle of the semi-cylindrical base, a motor is arranged in the groove, the output end of the motor is fixedly connected with a connecting rod, an indicating needle is arranged in the middle of the connecting rod, the other end of the connecting rod is fixedly connected with the lifter, and the other end of the lifter is connected with the wind power generator;
further, the calculation formula of the comprehensive influence coefficient of the quality of the building curtain wall of each subarea stressed by wind power is as follows
Figure GDA0002966886640000061
,ξjThe quality comprehensive influence coefficient, lambda, of the jth sub-area building curtain wall expressed as wind pressureR=λR1R2R3R4,R=R1,R2,R3,R4,Δw′jRRth of jth sub-regional building curtain wall expressed as wind pressure of fth wind power class corresponding to theta direction angleThe comparison difference value between the quality parameter value and the standard value range of the building curtain wall quality parameter pressed by the corresponding wind power, wherein theta is theta12,...,θk,...,θx,0≤θk≤180°,f=f1,f2,f3,f4,w′maxRAnd w'minRRespectively representing the maximum value and the minimum value, w, of a standard numerical range of a first quality parameter in the building curtain wall pressed by different wind powersiR is expressed as the numerical value of the quality parameter, w, of the building curtain wall of the ith sub-areamaxR and wminAnd R is respectively expressed as the maximum value and the minimum value of the standard numerical range of the quality parameter of the building curtain wall.
Has the advantages that:
(1) the invention provides a building curtain wall project acceptance detection management system based on big data, which can lay detection points on each divided sub-area through a detection point laying module, detect each quality parameter value of the building curtain wall of each sub-area, thus reducing labor cost, improving reliability of detection data, simultaneously analyzing whether the quality of the building curtain wall of each sub-area is preliminarily qualified, improving the accuracy of the quality of the building curtain wall, avoiding confusion of personnel, applying pressure of different wind power to the building curtain wall of each sub-area with preliminarily qualified quality, detecting each quality parameter value of the building curtain wall of each sub-area with different wind power pressure, avoiding the falling problem of the building curtain wall, thereby reducing the occurrence rate of traffic accidents, ensuring physical and mental health of people, and simultaneously analyzing each quality parameter value comparison difference value of the building curtain walls of each sub-area with different wind power pressure, and reliable reference data are provided for later-stage calculation of the comprehensive influence coefficient of the quality of the building curtain wall of each subarea subjected to wind pressure application.
(2) According to the invention, the comprehensive influence coefficient of the quality of the building curtain wall of each subarea subjected to wind pressure is comprehensively calculated by the analysis server, whether the quality of the building curtain wall of each subarea subjected to wind pressure is finally qualified or not is judged by comparison, the serial number of each subarea corresponding to the building curtain wall with the finally unqualified quality is displayed, and related personnel maintain or replace the building curtain wall of the corresponding subarea according to the display, so that the safety sense is brought to people, and the life and property safety of people is ensured.
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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 view of the present invention;
FIG. 2 is a schematic view of a wind generating device in a wind generating module according to the present invention;
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 building curtain wall project acceptance inspection management system based on big data comprises a region division module, a detection point arrangement module, a quality parameter detection module, a quality parameter analysis module, a wind power generation module, a qualified quality detection module, a qualified quality analysis module, an analysis server, a display terminal and a storage database;
the analysis server is respectively connected with the quality parameter analysis module, the qualified quality analysis module, the wind power generation module, the display terminal and the storage database, the storage database is respectively connected with the region division module, the quality parameter analysis module and the qualified quality analysis module, the quality parameter detection module is respectively connected with the detection point arrangement module and the quality parameter analysis module, and the qualified quality detection module is respectively connected with the wind power generation module and the qualified quality analysis module.
The area dividing module is used for dividing a building curtain wall area to be checked and accepted, dividing the building curtain wall area into a plurality of sub-areas with the same area according to a gridding equal dividing mode, numbering the plurality of divided sub-areas sequentially from left to right and from top to bottom according to a set sequence, wherein the numbers are respectively 1,2, a.
The detection point distribution module is used for distributing detection points for all sub-areas of the building curtain wall to be checked and accepted, distributing the detection points for all the sub-areas in a uniformly distributed mode, enabling all the detection points to correspond to all the sub-areas one by one, and sending the detection points distributed for all the sub-areas to the quality parameter detection module;
the quality parameter detection module comprises a flatness detection unit, a verticality detection unit, a levelness detection unit and a crack area detection unit, and is used for receiving detection points distributed on each subregion sent by the detection point distribution module and detecting the quality of the building curtain wall of each subregion, wherein the flatness detection unit is a flatness detector and is used for detecting the flatness in the quality parameters of the building curtain wall of each subregion, the verticality detection unit is a theodolite and is used for detecting the verticality in the quality parameters of the building curtain wall of each subregion, the levelness detection unit is a gradienter and is used for detecting the levelness in the quality parameters of the building curtain wall of each subregion, the crack area detection unit is an x-ray detector and is used for acquiring crack images of the quality of the building curtain wall of each subregion and obtaining the crack area in the quality parameters of the building curtain wall of each subregion, therefore, the labor cost is reduced, the reliability of the detection data is improved, the quality parameter values of the building curtain walls of the sub-areas are counted, and the quality parameter value set W of the building curtain walls of the sub-areas is formednR(w1R,w2R,...,wiR,...,wiR),wiR is represented as the quality parameter value of the ith sub-area building curtain wall, R is R1, R2, R3, R4 and R1 are represented as the flatness in the quality parameter of the building curtain wall, R2 is represented as the verticality in the quality parameter of the building curtain wall, R3 is represented as the levelness in the quality parameter of the building curtain wall, R4 is represented as the crack area in the quality parameter of the building curtain wall, and the quality parameter value sets of the building curtain walls of all the sub-areas are sent to the quality parameter value setsAn analysis module;
the quality parameter analysis module is used for receiving the quality parameter value sets of the building curtain walls of the sub-areas sent by the quality parameter detection module, extracting the standard flatness range, the standard verticality range, the standard levelness range and the standard crack area range in the building curtain wall quality parameters stored in the storage database, comparing the received quality parameter values of the building curtain walls of the sub-areas with the standard value ranges of the corresponding building curtain wall quality parameters, if the quality parameter values of the building curtain walls of a certain sub-area are all in the standard value ranges of the corresponding building curtain wall quality parameters, indicating that the quality of the building curtain walls of the area is initially qualified, if the quality parameter values of the building curtain walls of a certain sub-area are outside the standard value ranges of the corresponding building curtain wall quality parameters, indicating that the quality of the building curtain walls of the area is initially unqualified, the subregion serial number that the preliminary qualified building curtain of statistics quality corresponds and the subregion serial number that the preliminary unqualified building curtain of quality corresponds can improve the precision to the building curtain quality, avoids personnel's confusion, sends the subregion serial number that the preliminary qualified building curtain of quality corresponds and the subregion serial number that the preliminary unqualified building curtain of quality corresponds to analysis server.
The analysis server is used for receiving the subregion number corresponding to the building curtain wall with the preliminarily qualified quality and the subregion number corresponding to the building curtain wall with the preliminarily unqualified quality sent by the quality parameter analysis module to form each subregion set W 'with the preliminarily qualified building curtain wall quality'm(w′1,w′2,...,w′j,...,w′m),m≤n,w′jAnd the sub-regions are expressed as the sub-regions with the quality preliminarily qualified of the jth building curtain wall, the sub-regions with the quality preliminarily qualified of the building curtain wall are integrated and sent to the wind power generation module, and meanwhile, the sub-region numbers corresponding to the building curtain wall with the quality preliminarily unqualified are sent to the display terminal.
The wind power generation module comprises a wind power generation device, wherein the wind power generation device comprises a semi-cylindrical base, a lifter and a wind power generator, an angle scale is arranged on the top surface of the semi-cylindrical base, a groove is formed in the middle of the semi-cylindrical base, a motor is arranged in the groove, the output end of the motor is fixedly connected with a connecting rod, an indicating needle is arranged in the middle of the connecting rod, the other end of the connecting rod is fixedly connected with the lifter, the other end of the lifter is connected with the wind power generator, the wind power generation device can rotate in a semi-circular range and can generate wind power with different wind power grades, each wind power grade is respectively primary wind power, secondary wind power, tertiary wind power and quaternary wind power, the wind power generation module is used for receiving all sub-area sets with preliminarily qualified building curtain wall quality sent by an analysis server, wind power with different, sending each sub-area with preliminarily qualified quality of the building curtain wall pressed by different wind power to a qualified quality detection module;
the qualified quality detection module is used for receiving all sub-regions with preliminarily qualified building curtain wall quality exerted by different wind power sent by the wind power generation module, detecting the building curtain wall quality at all sub-region detection points exerted by different wind power, detecting the flatness, the perpendicularity, the levelness and the crack area in the building curtain wall quality parameters of all the sub-regions exerted by different wind power, and avoiding the problem of falling off of the building curtain wall, thereby reducing the occurrence rate of traffic accidents, ensuring the physical and mental health of people, and forming a quality parameter value set W 'of all the building curtain walls of all the sub-regions exerted by different wind power'mR(w′1R,w′2R,...,w′jR,...,w′mR),m≤n,w′jRExpressing the value of the quality parameter of the jth sub-area building curtain wall corresponding to the wind pressure of the wind power grade corresponding to the theta direction angle, wherein f is f1,f2,f3,f4,f1,f2,f3,f4Respectively expressed as primary wind, secondary wind, tertiary wind and quaternary wind, theta ═ theta12,...,θk,...,θx,0≤θkThe quality parameter values of the building curtain walls of the sub-areas pressed by different wind power are collected and sent to a qualified quality analysis module;
the qualified quality analysis module is used for receiving each quality parameter value set of each sub-area building curtain wall subjected to different wind pressure sent by the qualified quality detection module, extracting a standard flatness range, a standard verticality range, a standard levelness range and a standard crack area range in the building curtain wall quality parameters subjected to different wind pressure stored in the storage database, comparing each quality parameter value of each sub-area building curtain wall subjected to different wind pressure with the standard value range of the building curtain wall quality parameter subjected to corresponding wind pressure, and obtaining a comparison difference value set delta W 'of each quality parameter value of each sub-area building curtain wall subjected to different wind pressure'mR(Δw′1R,Δw′2R,...,Δw′jR,...,Δw′mR),m≤n,Δw′jRThe comparison difference value between the R-th quality parameter value of the jth sub-area building curtain wall which is expressed as the wind pressure of the fth wind power level corresponding to the theta direction angle and the standard value range of the quality parameter of the building curtain wall which is expressed as the wind pressure corresponding to the wind power level provides reliable reference data for calculating the comprehensive quality influence coefficient of each sub-area building curtain wall which is subjected to wind pressure in the later period, and the comparison difference value set of each quality parameter value of each sub-area building curtain wall which is subjected to different wind pressure is sent to the analysis server;
the analysis server is used for receiving the comparison difference value set of the quality parameter values of the building curtain walls of the sub-areas pressed by different wind power sent by the qualified quality analysis module, calculating the comprehensive influence coefficient of the quality of the building curtain walls of the sub-areas pressed by the wind power, and the calculation formula of the comprehensive influence coefficient of the quality of the building curtain walls of the sub-areas pressed by the wind power is
Figure GDA0002966886640000111
,ξjThe quality comprehensive influence coefficient, lambda, of the jth sub-area building curtain wall expressed as wind pressureR=λR1R2R3R4,R=R1,R2,R3,R4,Δw′jRJ-th wind pressure expressed as f-th wind class corresponding to theta direction angleThe comparison difference value between the R-th quality parameter value of the sub-area building curtain wall and the standard value range of the building curtain wall quality parameter pressed by the corresponding wind power, wherein theta is theta12,...,θk,...,θx,0≤θk≤180°,f=f1,f2,f3,f4,w′maxRAnd w'minRRespectively representing the maximum value and the minimum value, w, of the standard numerical range of the quality parameters of the building curtain wall pressed by different wind powersiR is expressed as the quality parameter value, w, of the building curtain wall of the ith sub-areamaxR and wminR is respectively expressed as the maximum value and the minimum value of the standard numerical range of the building curtain wall quality parameters, the standard quality comprehensive influence coefficient of the building curtain wall stored in the storage database is extracted, the quality comprehensive influence coefficient of the building curtain wall of each subarea exerted by wind power is compared with the stored standard quality comprehensive influence coefficient of the building curtain wall, if the quality comprehensive influence coefficient of the building curtain wall of a certain subarea exerted by the wind power is smaller than or equal to the standard quality comprehensive influence coefficient of the building curtain wall, the quality of the building curtain wall of the subarea is finally qualified, if the quality comprehensive influence coefficient of the building curtain wall of a certain subarea exerted by the wind power is larger than the standard quality comprehensive influence coefficient of the building curtain wall, the quality of the building curtain wall of the subarea is finally unqualified, the numbers of the subareas corresponding to the building curtain walls with the unqualified quality are counted, and the numbers of the.
The display terminal is used for receiving the subregion serial numbers corresponding to the building curtain wall with the preliminary unqualified quality and the subregion serial numbers corresponding to the building curtain wall with the final unqualified quality sent by the analysis server, displaying the received subregion serial numbers, and maintaining or replacing the subregions corresponding to the building curtain wall with the unqualified quality according to the display by related personnel, thereby bringing a sense of safety to people and ensuring the safety of lives and properties of people.
The storage database is used for receiving the serial numbers of the sub-areas sent by the area dividing module and storing the standard flatness range and the standard in the quality parameters of the building curtain wallThe standard quality influence coefficients of all quality parameters in the building curtain wall are stored, and are respectively lambdaR1、λR2、λR3、λR4,λR1R2R3R4And sequentially and respectively representing the standard quality influence coefficients of the flatness, the verticality, the levelness and the crack area in the quality parameters of the building curtain wall, and storing the standard quality comprehensive influence coefficient of the building curtain wall.
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 (3)

1. The utility model provides a building curtain wall engineering acceptance inspection management system based on big data which characterized in that: the system comprises a region division module, a detection point arrangement module, a quality parameter detection module, a quality parameter analysis module, a wind power generation module, a qualified quality detection module, a qualified quality analysis module, an analysis server, a display terminal and a storage database;
the analysis server is respectively connected with the quality parameter analysis module, the qualified quality analysis module, the wind power generation module, the display terminal and the storage database, the storage database is respectively connected with the region division module, the quality parameter analysis module and the qualified quality analysis module, the quality parameter detection module is respectively connected with the detection point arrangement module and the quality parameter analysis module, and the qualified quality detection module is respectively connected with the wind power generation module and the qualified quality analysis module;
the area dividing module is used for dividing a building curtain wall area to be checked and accepted, dividing the building curtain wall area into a plurality of sub-areas with the same area according to a gridding equal dividing mode, numbering the plurality of divided sub-areas sequentially from left to right and from top to bottom according to a set sequence, wherein the numbers are respectively 1,2, a.
The detection point distribution module is used for distributing detection points for all sub-areas of the building curtain wall to be checked and accepted, distributing the detection points for all the sub-areas in a uniformly distributed mode, enabling all the detection points to correspond to all the sub-areas one by one, and sending the detection points distributed for all the sub-areas to the quality parameter detection module;
the quality parameter detection module is used for receiving the detection points distributed in each subarea and sent by the detection point distribution module, detecting the quality of the building curtain wall of each received subarea, detecting the flatness, the verticality, the levelness and the crack area in the quality parameters of the building curtain wall of each subarea, and forming a numerical value set W of each quality parameter of the building curtain wall of each subareanR(w1R,w2R,...,wiR,...,wiR),wiR represents the quality parameter value of the building curtain wall of the ith sub-region, R is R1, R2, R3, R4 and R1 represent the flatness in the quality parameter of the building curtain wall, R2 represents the verticality in the quality parameter of the building curtain wall, R3 represents the levelness in the quality parameter of the building curtain wall, R4 represents the crack area in the quality parameter of the building curtain wall, and the quality parameter value sets of the building curtain walls of the sub-regions are sent to the quality parameter analysis module;
the quality parameter analysis module is used for receiving the quality parameter value sets of the building curtain walls of the sub-areas sent by the quality parameter detection module, extracting the standard flatness range, the standard verticality range, the standard levelness range and the standard crack area range in the building curtain wall quality parameters stored in the storage database, comparing the received quality parameter values of the building curtain walls of the sub-areas with the standard value ranges of the corresponding building curtain wall quality parameters, if the quality parameter values of the building curtain walls of a certain sub-area are all in the standard value ranges of the corresponding building curtain wall quality parameters, indicating that the quality of the building curtain walls of the area is initially qualified, if the quality parameter values of the building curtain walls of a certain sub-area are outside the standard value ranges of the corresponding building curtain wall quality parameters, indicating that the quality of the building curtain walls of the area is initially unqualified, counting the number of the subareas corresponding to the building curtain wall with the preliminarily qualified quality and the number of the subareas corresponding to the building curtain wall with the preliminarily unqualified quality, and sending the number of the subareas corresponding to the building curtain wall with the preliminarily qualified quality and the number of the subareas corresponding to the building curtain wall with the preliminarily unqualified quality to an analysis server;
the analysis server is used for receiving the subregion number corresponding to the building curtain wall with the preliminarily qualified quality and the subregion number corresponding to the building curtain wall with the preliminarily unqualified quality sent by the quality parameter analysis module to form each subregion set W 'with the preliminarily qualified building curtain wall quality'm(w′1,w′2,...,w′j,...,w′m),m≤n,w′jThe subareas with the preliminarily qualified quality of the jth building curtain wall are represented, all the subareas with the preliminarily qualified quality of the building curtain wall are collectively sent to the wind power generation module, and meanwhile, the subarea numbers corresponding to the building curtain wall with the preliminarily unqualified quality are sent to the display terminal;
the wind power generation module comprises a wind power generation device, wherein the wind power generation device can realize semicircular amplitude rotation and can generate wind power with different wind power grades, each wind power grade is primary wind power, secondary wind power, tertiary wind power and quaternary wind power, the wind power grades are used for receiving each subregion set with preliminarily qualified quality of the building curtain wall sent by the analysis server, the wind power generation device generates wind power with different wind power grades of each direction angle and applies pressure to each subregion building curtain wall with preliminarily qualified quality, and each subregion with preliminarily qualified quality of the building curtain wall with pressure applied by different wind power is sent to the qualified quality detection module;
the qualified quality detection module is used for receiving all sub-regions with preliminarily qualified building curtain wall quality exerted by different wind power sent by the wind power generation module, detecting the building curtain wall quality of all sub-region detection points exerted by different wind power, detecting the flatness, the verticality, the levelness and the crack area in the building curtain wall quality parameters of all sub-regions exerted by different wind power, and constructingQuality parameter value sets W 'of building curtain walls of sub-areas stressed by different wind power'mR(w′1R,w′2R,...,w′jR,...,w′mR),m≤n,w′jRExpressing the value of the quality parameter of the jth sub-area building curtain wall corresponding to the wind pressure of the wind power grade corresponding to the theta direction angle, wherein f is f1,f2,f3,f4;f1,f2,f3,f4Respectively expressed as primary wind, secondary wind, tertiary wind and quaternary wind, theta ═ theta12,...,θk,...,θx,0≤θkThe quality parameter values of the building curtain walls of the sub-areas pressed by different wind power are collected and sent to a qualified quality analysis module;
the qualified quality analysis module is used for receiving each quality parameter value set of each sub-area building curtain wall subjected to different wind pressure sent by the qualified quality detection module, extracting a standard flatness range, a standard verticality range, a standard levelness range and a standard crack area range in the building curtain wall quality parameters subjected to different wind pressure stored in the storage database, comparing each quality parameter value of each sub-area building curtain wall subjected to different wind pressure with the standard value range of the building curtain wall quality parameter subjected to corresponding wind pressure, and obtaining a comparison difference value set delta W 'of each quality parameter value of each sub-area building curtain wall subjected to different wind pressure'mR(Δw′1R,Δw′2R,...,Δw′jR,...,Δw′mR),m≤n,Δw′jRThe comparison difference value between the R-th quality parameter value of the jth sub-area building curtain wall which is expressed as the wind pressure of the fth wind power level corresponding to the theta direction angle and the standard value range of the quality parameter of the building curtain wall which is expressed as the corresponding wind pressure is sent to the analysis server;
the analysis server is used for receiving the comparison difference value set of the numerical values of the quality parameters of the building curtain walls of the sub-areas with different wind pressures sent by the qualified quality analysis module, calculating the comprehensive influence coefficient of the quality of the building curtain walls of the sub-areas with the wind pressures, extracting and storing the standard comprehensive influence coefficient of the building curtain walls stored in the database, comparing the comprehensive influence coefficient of the quality of the building curtain walls of the sub-areas with the stored standard comprehensive influence coefficient of the building curtain walls, if the comprehensive influence coefficient of the quality of the building curtain walls of a certain sub-area with the wind pressures is less than or equal to the standard comprehensive influence coefficient of the quality of the building curtain walls, the quality of the building curtain walls of the sub-area is finally qualified, if the comprehensive influence coefficient of the quality of the building curtain walls of a certain sub-area with the wind pressures is greater than the standard comprehensive influence coefficient of the, counting the number of each subarea corresponding to the building curtain wall with the final unqualified quality, and sending the number of each subarea corresponding to the building curtain wall with the final unqualified quality to a display terminal;
the display terminal is used for receiving the subregion number corresponding to the building curtain wall with preliminary unqualified quality and the subregion number corresponding to the building curtain wall with final unqualified quality sent by the analysis server, displaying the received subregion numbers, and maintaining or replacing the subregion corresponding to the building curtain wall with unqualified quality by related personnel according to the display;
the storage database is used for receiving the serial numbers of the plurality of sub-areas sent by the area dividing module, storing a standard flatness range, a standard verticality range, a standard levelness range and a standard crack area range in the quality parameters of the building curtain wall, simultaneously storing the standard flatness range, the standard verticality range, the standard levelness range and the standard crack area range in the quality parameters of the building curtain wall pressed by different wind powers, and simultaneously storing standard quality influence coefficients of the quality parameters in the building curtain wall, wherein the standard quality influence coefficients are lambda respectivelyR1、λR2、λR3、λR4,λR1R2R3R4Respectively expressed as the flatness and the verticality in the quality parameters of the building curtain wall in sequenceStandard quality influence coefficients of levelness and crack area, and storing the standard quality comprehensive influence coefficient of the building curtain wall;
the calculation formula of the quality comprehensive influence coefficient of the building curtain wall of each subarea stressed by wind power is
Figure FDA0002966886630000041
ξjThe quality comprehensive influence coefficient, lambda, of the jth sub-area building curtain wall expressed as wind pressureR=λR1,λR2,λR3,λR4,R=R1,R2,R3,R4,Δw′jRExpressing the comparison difference between the R-th quality parameter value of the jth sub-area building curtain wall pressed by the wind power of the f-th wind power level corresponding to the theta direction angle and the standard value range of the quality parameter of the building curtain wall pressed by the corresponding wind power, wherein theta is theta12,...,θk,...,θx,0≤θk≤180°,f=f1,f2,f3,f4,w′maxRAnd w'minRRespectively representing the maximum value and the minimum value, w, of the standard numerical range of the quality parameters of the building curtain wall pressed by different wind powersiR is expressed as the quality parameter value, w, of the building curtain wall of the ith sub-areamaxR and wminAnd R is respectively expressed as the maximum value and the minimum value of the standard numerical range of the quality parameter of the building curtain wall.
2. The building curtain wall engineering acceptance detection management system based on big data according to claim 1, characterized in that: the quality parameter detection module comprises a flatness detection unit, a verticality detection unit, a levelness detection unit and a crack area detection unit, wherein the flatness detection unit is a flatness detector and is used for detecting the flatness in the quality parameters of the building curtain walls of the sub-areas, the verticality detection unit is a theodolite and is used for detecting the verticality in the quality parameters of the building curtain walls of the sub-areas, the levelness detection unit is a gradienter and is used for detecting the levelness in the quality parameters of the building curtain walls of the sub-areas, and the crack area detection unit is an x-ray detector and is used for acquiring crack images of the quality of the curtain walls of the sub-areas of the building curtain walls of the sub-areas and acquiring the.
3. The building curtain wall engineering acceptance detection management system based on big data according to claim 1, characterized in that: the wind power generation device comprises a semi-cylindrical base, a lifter and a wind power generator, wherein an angle scale is arranged on the top surface of the semi-cylindrical base, a groove is formed in the middle of the semi-cylindrical base, a motor is arranged in the groove, an output end of the motor is fixedly connected with a connecting rod, an indicating needle is arranged in the middle of the connecting rod, the other end of the connecting rod is fixedly connected with the lifter, and the other end of the lifter is connected with the wind power.
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