CN117029775A

CN117029775A - Intelligent monitoring method and device for building quality, electronic equipment and medium

Info

Publication number: CN117029775A
Application number: CN202310999881.1A
Authority: CN
Inventors: 蒋佳纯; 蒋新生; 林桂庆; 胡辉伦; 石建华
Original assignee: Guangzhou New Town Architectural Design Institute Co ltd
Current assignee: Guangzhou New Town Architectural Design Institute Co ltd
Priority date: 2023-08-09
Filing date: 2023-08-09
Publication date: 2023-11-10

Abstract

The application relates to the field of building quality monitoring, in particular to an intelligent building quality monitoring method, an intelligent building quality monitoring device, electronic equipment and a medium. The method comprises the following steps: acquiring floor information of a building, and determining deformation information of the building based on the floor information; based on the deformation information, determining deformation score information corresponding to the deformation information; if the deformation score information exceeds the preset score information, generating first early warning information and acquiring inclination information of the building; and if the inclination information exceeds the preset inclination information, generating second early warning information and prompting. The application can intelligently monitor the quality of the building and improve the accuracy of building monitoring.

Description

Intelligent monitoring method and device for building quality, electronic equipment and medium

Technical Field

The application relates to the field of building quality monitoring, in particular to an intelligent building quality monitoring method, an intelligent building quality monitoring device, electronic equipment and a medium.

Background

With the continuous development of social economy, urban and rural construction and construction engineering are larger and larger in scale and better in construction quality, high-rise buildings and manmade buildings are different day by day, but are influenced by natural factors and human factors, the buildings are damaged to different degrees, if the buildings are not monitored in place, the event of collapse and casualties of the buildings can be caused along with the time, and huge losses are caused for the state and people and property.

The traditional building quality monitoring method mainly adopts a manual monitoring mode, technicians need to acquire inclination data of a building under the influence of wind power, and then the acquired data are analyzed and processed to further confirm whether the building meets quality requirements.

However, the conventional building quality monitoring method needs to have great requirements on engineering experience of technicians, and when the building is subjected to inclination detection under the influence of wind power, great inconvenience is caused to the technicians, and accuracy of detection data is greatly affected.

Disclosure of Invention

In order to improve the accuracy of building quality monitoring, the application provides an intelligent building quality monitoring method, an intelligent building quality monitoring device, electronic equipment and a medium.

In a first aspect, the present application provides an intelligent building quality monitoring method, which adopts the following technical scheme:

acquiring floor information of a building, and determining deformation information of the building based on the floor information;

based on the deformation information, determining deformation score information corresponding to the deformation information;

if the deformation score information exceeds the preset score information, generating first early warning information and acquiring inclination information of the building;

And if the inclination information exceeds the preset inclination information, generating second early warning information and prompting.

By adopting the technical scheme, floor information of the current building is obtained, height grade information of the current building, namely, low-rise building, middle-rise building and high-rise building is determined, deformation information corresponding to the floors is determined to be obtained based on the floor information, in order to intuitively reflect deformation conditions of the current building, the deformation information is analyzed and calculated, further, the deformation value information is converted, the deformation value information is compared with preset value information, if the current deformation value information exceeds the preset value information, the quality of the current building is indicated to have a damage problem, therefore, first early warning information is generated, inclination information of the building is obtained, namely, displacement deviation information of the building caused by wind force at present is obtained, then the inclination information is compared with the preset inclination information, if the inclination information of the current building exceeds the preset inclination information, the current building is indicated to generate larger displacement inclination due to the influence of wind force, further serious building safety accidents are caused, and finally second early warning information is generated and prompt is carried out; thereby improving the monitoring accuracy while reducing the difficulty of monitoring the mass of the building.

In one possible implementation manner, the deformation information includes a plurality of sub-deformation information, and the determining the deformation information of the building based on the floor information includes:

acquiring height information corresponding to the floor information, splitting the floor information according to the height information, and determining a plurality of sub-floor information;

determining a plurality of sub-floor monitoring areas based on the plurality of sub-floor information;

determining deviation information corresponding to each of the plurality of sub-floor monitoring areas, and determining a plurality of sub-deformation information based on the deviation information;

and summarizing the plurality of sub-deformation information and determining the deformation information.

By adopting the technical scheme, the height information corresponding to the floor information is acquired, and as the lower area of the building is shielded by houses or plants, the damage degree and the damage rate of the lower area are reduced to a certain extent compared with those of the upper area, so that the floor information is subjected to layering processing according to the height information to determine a plurality of sub-floor information, and then the sub-floor monitoring area corresponding to each sub-floor information is determined based on each sub-floor information; determining deviation information corresponding to each of the plurality of sub-floor monitoring areas based on monitoring equipment arranged in each of the sub-floor monitoring areas, determining sub-deformation information corresponding to each of the sub-floor monitoring areas based on the deviation information, and finally summarizing all the obtained sub-deformation information to determine deformation information; therefore, the arrangement of the monitoring equipment is reasonably arranged by layering the buildings, so that the monitoring data is more comprehensive.

In one possible implementation manner, the determining deviation information corresponding to each of the plurality of sub-floor monitoring areas includes:

obtaining damage range information corresponding to each of the plurality of sub-floor monitoring areas;

comparing the damage range information with preset damage range information respectively;

if any damage range information exceeds the preset damage range information, carrying out difference value calculation on any damage range information and the preset damage range information, and determining deviation information.

By adopting the technical scheme, the damage range information corresponding to each of the plurality of sub-floor monitoring areas is acquired, and as the bearing pressure of each structural node in the building is different, the deformation or damage difficulty is different, the determined damage range information is respectively compared with the preset damage range information, the slight damage range information is removed, if any damage range information exceeds the preset damage range information, the current sub-floor monitoring area is proved to have serious damage or deformation, the difference value calculation is carried out on any damage range information and the preset damage range information, and the deviation information is determined; therefore, a part of slightly damaged data is removed, and deformation degree information is obtained through calculation of data of the monitoring equipment.

In one possible implementation manner, determining deformation score information corresponding to the deformation information based on the deformation information includes:

acquiring weight information corresponding to each of the plurality of sub-floor monitoring areas;

multiplying the plurality of sub-deformation information with corresponding weight information respectively to determine the plurality of sub-deformation score information;

and carrying out addition calculation on the plurality of sub-deformation score information to determine the deformation score information.

After the deformation information of the building is determined by adopting the technical scheme, because the damage difficulty of each building and the influence degree of external factors on different areas of the building are different, the weight information of each sub-floor monitoring area of the building is determined based on historical data analysis, then the sub-deformation information corresponding to each sub-floor monitoring area is multiplied by the weight information to determine the sub-deformation score information corresponding to each sub-floor monitoring area, and then the sub-deformation score information corresponding to each sub-floor monitoring area is all added to determine the deformation score information of the current building; therefore, the deformation of each building is converted into specific score information, and the damage degree of the current building is clearly and intuitively represented.

In one possible implementation manner, the acquiring the inclination information of the building includes:

taking the ground as a preset base point, and acquiring sensor coordinate information of a current building;

if the sensor coordinate information is inconsistent with the preset sensor coordinate information, extracting three-dimensional coordinate information in the sensor coordinate information;

and calculating the three-dimensional coordinate information through a preset rule, and determining inclination information.

By adopting the technical scheme, in order to acquire the coordinate information, the ground is set as a preset base point, the inclination degree of the building due to the influence of wind force is reduced because of a shielding object in the lower area of the building, the real inclination information of the building cannot be reflected, the coordinate information of a sensor corresponding to the highest point of the current building is acquired, if the coordinate information of the current sensor is inconsistent with the coordinate information of the preset sensor, the current sensor is indicated to have position deviation due to the influence of wind force, the three-dimensional coordinate information in the coordinate information of the sensor is extracted, and the three-dimensional coordinate information is calculated through a preset rule to determine the inclination information; therefore, the deformation damage degree of the building is monitored, and the inclination information of the building under the influence of wind power is monitored, so that the monitoring is more comprehensive.

In one possible implementation manner, the calculating the three-dimensional coordinate information through a preset rule to determine tilt information includes:

performing arctangent function calculation on the three-dimensional coordinate information to determine angle information;

calculating a difference value between preset angle information and the angle information, and determining inclination angle information;

comparing the inclination angle information with preset inclination angle information;

and if the inclination angle information exceeds the preset inclination angle information, determining the inclination angle information as the inclination information.

By adopting the technical scheme, after the three-dimensional coordinate information is determined, the three-dimensional coordinate information is subjected to arctangent function calculation to determine the angle information of the current building, and the calculated angle information is the included angle information of the current building and the ground, so that the angle information is subjected to difference value calculation with the preset angle information to determine the inclination angle information of the building, and then the inclination angle information is compared with the preset inclination angle information, if the inclination angle information exceeds the preset inclination angle information, the current building is influenced by wind power, larger angle deviation is generated, and the possibility of accidents exists, so that the inclination angle information is determined as the inclination information, and the inclination information of the building is calculated, so that the subsequent comparison is convenient.

In one possible implementation manner, if the inclination information exceeds the preset inclination information, generating second early warning information and prompting, and then further including:

acquiring wind power grade information corresponding to current inclination information;

based on historical data analysis, determining the corresponding relation between the wind power grade information and the inclination information;

acquiring a forecast value of wind power grade information of an environment where a building is located in a next monitoring period;

based on the corresponding relation and the forecast value, determining forecast inclination information corresponding to the forecast value;

and if the predicted inclination information exceeds the preset inclination information, generating third early warning information and prompting.

By adopting the technical scheme, wind power grade information corresponding to the current inclination information is obtained, a database is constructed by continuously recording the wind power grade and the inclination information of the actual situation, then, based on historical data analysis, the corresponding relation between the wind power grade information and the inclination information is determined, the corresponding relation indicates how much inclination information is caused by the wind power grade degree, the forecast value of the wind power grade information of the environment where the building is located in the next monitoring period is obtained, based on the corresponding relation, the forecast inclination information corresponding to the forecast value of the wind power grade information in the next monitoring period is determined, then, the preset inclination information is compared with the forecast inclination information, if the forecast inclination information exceeds the preset inclination information, the fact that the current building has a trend of having a larger inclination degree is indicated, and third early warning information is generated and is prompted; therefore, whether the building can bear the wind power of the next level is predicted, the risk pre-judgment is increased, and the quality safety of the building is further protected.

In a second aspect, the application provides an intelligent building quality monitoring device, which adopts the following technical scheme:

an intelligent building quality monitoring device, comprising: the system comprises a deformation information determining module, a deformation score information determining module, a first early warning module and a second early warning module, wherein,

the deformation information determining module is used for acquiring floor information of the building and determining deformation information of the building based on the floor information;

the deformation score information determining module is used for determining deformation score information corresponding to the deformation information based on the deformation information;

the first early warning module is used for generating first early warning information and acquiring inclination information of a building if the deformation score information exceeds preset score information;

and the second early warning module is used for generating and prompting second early warning information if the inclination information exceeds preset inclination information.

By adopting the technical scheme, the deformation information determining module obtains the floor information of the current building, determines the height grade information of the current building, namely the low-rise building, the middle-rise building and the high-rise building, determines to obtain the deformation information corresponding to the floor based on the floor information, and in order to intuitively reflect the quality condition of the deformation information, the deformation information determining module analyzes and calculates the deformation information to further convert the deformation value information, and then the first early warning module compares the deformation value information with the preset value information, and if the current deformation value information exceeds the preset value information, the quality of the current building has a damage problem, so that the first early warning information is generated and the inclination information of the building is obtained, namely the displacement deviation information of the building, caused by the current wind force influence, of the building is obtained; the second early warning module compares the inclination information with preset inclination information, if the inclination information of the current building exceeds the preset inclination information, the current building is indicated to generate larger displacement inclination due to the influence of wind power, so that more serious building safety accidents are caused, and finally second early warning information is generated and prompted; thereby improving the monitoring accuracy while reducing the difficulty of monitoring the mass of the building.

In one possible implementation manner, the deformation information determining module includes: a sub-floor information determining unit, a monitoring area determining unit, a sub-deformation information determining unit and a deformation information determining unit, wherein,

the sub-floor information determining unit is used for acquiring the height information corresponding to the floor information, splitting the floor information according to the height information and determining a plurality of sub-floor information;

a monitoring area determining unit configured to determine a plurality of sub-floor monitoring areas based on the plurality of sub-floor information;

the sub-deformation information determining unit is used for determining deviation information corresponding to each of the plurality of sub-floor monitoring areas and determining a plurality of sub-deformation information based on the deviation information;

and the deformation information determining unit is used for summarizing the plurality of sub-deformation information and determining the deformation information.

In a possible implementation manner, the sub-deformation information determining unit is specifically configured to:

In one possible implementation manner, the intelligent monitoring device for building quality includes: a weight information acquisition module, a sub-score information determination module and a score information determination module, wherein,

the weight information acquisition module is used for acquiring weight information corresponding to each of the plurality of sub-floor monitoring areas;

the sub-score information determining module is used for multiplying the plurality of sub-deformation information with corresponding weight information respectively to determine the plurality of sub-deformation score information;

and the score information determining module is used for carrying out addition calculation on the plurality of sub-deformation score information and determining the deformation score information.

In one possible implementation manner, the second early warning module includes: a coordinate information determining unit, an extracting unit, and a tilt information determining unit, wherein,

the coordinate information determining unit is used for obtaining the sensor coordinate information of the current building by taking the ground as a preset base point;

the extraction unit is used for extracting three-dimensional coordinate information in the sensor coordinate information if the sensor coordinate information is inconsistent with preset sensor coordinate information;

and the inclination information determining unit is used for calculating the three-dimensional coordinate information through a preset rule and determining inclination information.

In a possible implementation manner, the extracting unit is specifically configured to:

In one possible implementation manner, the intelligent building quality monitoring device further comprises: the system comprises a grade information acquisition module, a corresponding relation determination module, a forecast value determination module, a forecast inclination information determination module and a third early warning module, wherein,

the grade information acquisition module is used for acquiring wind power grade information corresponding to the current inclination information;

the corresponding relation determining module is used for determining the corresponding relation between the wind power grade information and the inclination information based on historical data analysis;

the forecast value determining module is used for obtaining the forecast value of the wind power grade information of the environment where the building is located in the next monitoring period;

the prediction inclination information determining module is used for determining prediction inclination information corresponding to the forecast value based on the corresponding relation and the forecast value;

And the third early warning module is used for generating and prompting third early warning information if the predicted inclination information exceeds the preset inclination information.

In a third aspect, the present application provides an electronic device, which adopts the following technical scheme:

an electronic device, the electronic device comprising:

at least one processor;

a memory;

at least one application program, wherein the at least one application program is stored in the memory and configured to be executed by the at least one processor, the at least one application program configured to: and executing the intelligent monitoring method for the building quality.

In a fourth aspect, the present application provides a computer readable storage medium, which adopts the following technical scheme:

a computer-readable storage medium, comprising: a computer program is stored that can be loaded by a processor and that performs the intelligent monitoring method of building quality described above.

In summary, the application has the following beneficial technical effects:

firstly, floor information of a current building is obtained, height grade information of the current building, namely a low-rise building, a middle-rise building and a high-rise building is determined, quality information corresponding to the obtained floors is determined based on the floor information, in order to intuitively reflect quality conditions of the quality information, the quality information is analyzed and calculated and then converted into quality score information, the quality score information is compared with preset score information, if the current quality score information exceeds the preset score information, the quality of the current building is indicated to have a damage problem, and therefore first early warning information is generated and inclination information of the building is obtained, namely displacement deviation information of the building, caused by the influence of wind power, of the building at present; comparing the inclination information with preset inclination information, if the inclination information of the current building exceeds the preset inclination information, indicating that the current building is inclined by large displacement due to the influence of wind power, further causing more serious building safety accidents, and finally generating second early warning information and prompting; thereby improving the monitoring accuracy while reducing the difficulty of monitoring the mass of the building.

Drawings

FIG. 1 is a flow chart of an intelligent monitoring method for building quality according to an embodiment of the application;

FIG. 2 is a block schematic diagram of an intelligent building quality monitoring device according to an embodiment of the present application;

fig. 3 is a schematic diagram of an electronic device according to an embodiment of the application.

Detailed Description

The application is described in further detail below with reference to fig. 1-3.

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present application more apparent, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments of the present application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

The embodiment of the application provides an intelligent monitoring method for building quality, which is executed by electronic equipment, wherein the electronic equipment can be a server or terminal equipment, and the server can be an independent physical server, a server cluster or distributed equipment formed by a plurality of physical servers, or a cloud server for providing cloud computing service. The terminal device may be a smart phone, a tablet computer, a notebook computer, a desktop computer, etc., but is not limited thereto, and the terminal device and the server may be directly or indirectly connected through a wired or wireless communication manner, which is not limited herein.

Referring to fig. 1, the method includes: step S101, step S102, step S103, and step S104, wherein:

s101, acquiring floor information of a building, and determining deformation information of the building based on the floor information.

In the embodiment of the application, the deformation information represents deformation or damage degree information of the current building.

Specifically, when quality monitoring needs to be performed on a certain building, the electronic equipment scans the building, analyzes floor information of the building, determines grade information of the building, wherein the grade information comprises a low-rise building, a middle-rise building and a high-rise building, different grades of buildings correspond to different layering modes, and then obtains sensor information installed on the building based on the floor information, thereby determining deformation or damage degree information, namely deformation information, of the building, caused by the influence of external factors, and further obtaining the damaged or deformed degree of the current building.

It should be noted that, the data collection frequency of the sensor may be according to the frequency of each week, or may be according to the frequency of every two weeks, where the collection frequency is not specifically limited, and may be set according to the condition of the current monitored building, if the terrain where the current building is located is lower, the disaster frequency is correspondingly increased, so that the collection frequency may be appropriately shortened to ensure the timeliness of the monitoring.

S102, determining deformation score information corresponding to the deformation information based on the deformation information.

Specifically, after the deformation information is determined, the electronic equipment determines each piece of sub-deformation information in the deformation information, calculates each piece of sub-deformation information and corresponding weight information, then obtains each piece of sub-deformation score information, and finally determines the deformation score information, wherein the deformation score information can reflect the current quality safety degree of the building and is presented in a specific numerical value; thereby being beneficial to the technicians to clearly and intuitively and basically know the general condition of the current building material quality safety.

And S103, if the deformation score information exceeds the preset score information, generating first early warning information and acquiring inclination information of the building.

Specifically, after the electronic device determines the deformation score information, the electronic device judges the current deformation score information, if the current deformation score information does not exceed the preset score information, the electronic device indicates that the current building is damaged or deformed although the damage or deformation occurs, but the damage or deformation degree is slight and belongs to the damage in the normal degree, so the electronic device does not respond at all, if the current deformation information exceeds the preset score information, the electronic device indicates that the current building is damaged or deformed greatly and possibly causes serious quality safety accidents of the building, so the electronic device generates the first early warning information of 'the current building is problematic, please timely process and withhold', and feeds back to the terminal to prompt, meanwhile, the electronic device acquires the inclination angle of the building because the deformation of the building to a certain extent, and accordingly early warning is performed in time by monitoring the deformation or damage degree of the building, and accidents are prevented.

And S104, if the inclination information exceeds the preset inclination information, generating second early warning information and prompting.

Specifically, the situation that the building is inclined under the influence of larger wind power can occur due to deformation damage and the like of the building, and if the situation that the building is inclined is more serious under the influence of larger wind power, the electronic equipment monitors the inclination information of the building while monitoring the deformation or damage degree, then compares the inclination information with preset inclination information, if the current inclination information does not exceed the preset inclination information, the current wind power grade is lower, and the damage of the building does not cause larger inclination to the building, the electronic equipment does not respond to the situation, and if the current inclination information exceeds the preset inclination information, the current building is greatly influenced by wind power, or the damage of the building is aggravated, so that the building is greatly inclined, the quality safety accident is possibly caused, the electronic equipment generates a second early warning information of' the current building is abnormal, and the second early warning information is timely processed and is withered and fed back to the terminal for display; therefore, a judging mechanism is established aiming at the inclined condition of the building, and the monitoring comprehensiveness is improved.

The embodiment of the application provides an intelligent monitoring method for building quality, when the quality of a certain building is required to be monitored, electronic equipment firstly scans the building, analyzes floor information of the building, determines the grade information of the building, wherein the grade information comprises a low-rise building, a middle-rise building and a high-rise building, the buildings of different grades correspond to different layering modes, and then the electronic equipment acquires sensor information installed on the building based on the floor information, and determines deformation information of the building; the electronic equipment determines each piece of sub-deformation information in the deformation information, calculates each piece of sub-deformation information and corresponding weight information, then obtains each piece of sub-deformation score information, and finally determines the deformation score information, wherein the deformation score information can reflect the quality safety degree of the current building and is presented in a specific numerical value; the electronic equipment judges the current deformation score information, if the current deformation score information does not exceed the preset score information, the current building is damaged or deformed, but the damage or deformation degree is slight and belongs to damage in normal degree, so the electronic equipment does not respond at all, if the current deformation information exceeds the preset score information, the current building is greatly damaged or deformed, serious quality safety accidents can be caused to the building, the electronic equipment generates first early warning information of ' the current building is problematic, please timely process and thank you ' and monitors the inclination information of the building, then compares the inclination information with preset inclination information, if the current inclination information does not exceed the preset inclination information, the current wind power grade is lower, and the damage of the building does not cause great inclination to the building, the electronic equipment does not respond at all to the situation, if the current inclination information exceeds the preset inclination information, the current building is greatly influenced by wind power, or the building is greatly inclined due to the damage of the building, the quality safety accidents can be caused, the current building is possibly inclined, the first early warning information is timely processed, and the current inclination information is fed back to a second early warning information is timely processed, and the abnormal and the ' the inclination information is fast-withered; thereby improving the monitoring accuracy while reducing the difficulty of monitoring the mass of the building.

In step S101, deformation information of the building is determined based on the floor information, and specifically includes: acquiring height information corresponding to the floor information, splitting the floor information according to the height information, and determining a plurality of sub-floor information; determining a plurality of sub-floor monitoring areas based on the plurality of sub-floor information; determining deviation information corresponding to each of the plurality of sub-floor monitoring areas, and determining a plurality of sub-deformation information based on the deviation information; and summarizing the plurality of sub-deformation information to determine deformation information.

In an embodiment of the present application, the deformation information includes a plurality of sub-deformation information.

Specifically, the electronic device calculates the height information of the current building based on the floor information of the current building, because the influence degree of external factors is inconsistent in different height areas of the building, and then performs layering processing on the floor information of the current building according to the calculated height information to obtain a plurality of sub-floor information, because the design of the building is various, the plane of the same layer of building can contain a plurality of sub-floor information, each plane can be set as a monitoring area, the electronic device determines a plurality of sub-floor monitoring areas based on the plurality of sub-floor information, and because the detection area of the sensor is limited, the sensor is reasonably arranged based on the plane area of each monitoring area, and the arrangement shape of the plurality of sensors can be triangle or pentagon; the electronic equipment determines deviation information corresponding to each of the plurality of sub-floor monitoring areas, determines sub-deformation information corresponding to each of the sub-floor monitoring areas based on each of the deviation information, gathers the plurality of sub-deformation information, and finally determines deformation information; therefore, the arrangement of the monitoring equipment is reasonably arranged by layering the buildings, so that the monitoring data is more comprehensive.

It should be noted that the sub-floor information may be one layer of the total number of layers of the current building, or may be multiple layers of the total number of layers of the current building.

Further, determining deviation information corresponding to each of the plurality of sub-floor monitoring areas specifically includes: obtaining damage range information corresponding to each of the plurality of sub-floor monitoring areas; comparing the damage range information with preset damage range information respectively; if any damage range information exceeds the preset damage range information, carrying out difference value calculation on any damage range information and the preset damage range information, and determining deviation information.

Specifically, the electronic device extracts corresponding sensor data of each of the plurality of sub-floor monitoring areas, wherein the sensor data comprises damage degree information data, namely damage range information, of damage or deformation in the current sub-floor monitoring area, and as the damage degree of each sub-floor monitoring area is different and a high layer is more easily damaged than a low layer, the electronic device traverses the plurality of damage range information, and compares the plurality of damage range information with preset damage range information respectively; if any damaged range information exceeds the preset damaged range information, the fact that the sub-floor monitoring area corresponding to the any damaged range information generates deformation which can affect the quality safety of the building is shown, and the influence degree is relatively high is shown, so that the electronic equipment calculates the difference value between the any damaged range information and the preset damaged range information, and the deformation degree information, namely deviation information, of the current building is determined; therefore, a part of slightly damaged data is removed, and deformation degree information is obtained through calculation of data of the monitoring equipment.

In step S102, deformation score information corresponding to the deformation information is determined based on the deformation information, which specifically includes: acquiring weight information corresponding to each of the plurality of sub-floor monitoring areas; multiplying the plurality of sub-deformation information with corresponding weight information respectively to determine a plurality of sub-deformation score information; and carrying out addition calculation on the plurality of sub-deformation score information to determine the deformation score information.

Specifically, the electronic equipment acquires historical data of a current building, determines details of each piece of sub-floor information of the current building, determines weight information of each piece of sub-floor information based on the details of each piece of sub-floor information of the building, then performs multiplication operation on sub-deformation information corresponding to each sub-floor monitoring area and weight information corresponding to the sub-deformation information, determines sub-deformation score information corresponding to each sub-floor monitoring area, and then adds the sub-deformation score information corresponding to a plurality of sub-floor monitoring areas to determine deformation score information of the whole building, wherein the deformation score information is obtained by converting quality judgment standards of the building into reasonable score information; thereby clearly and intuitively representing the damage degree of the current building.

In step S104, the obtaining of the inclination information of the building specifically includes: taking the ground as a preset base point, and acquiring sensor coordinate information of a current building; if the sensor coordinate information is inconsistent with the preset sensor coordinate information, extracting three-dimensional coordinate information in the sensor coordinate information; and calculating the three-dimensional coordinate information through a preset rule, and determining the inclination information.

In the embodiment of the application, the preset sensor coordinate information represents the sensor coordinate information of any sensor under the influence of wind power, and the preset sensor coordinate information is not a specific value.

Specifically, in order to obtain the coordinate information of the sensor more accurately, setting the ground as a preset base point, because a shelter exists in the lower area of the building, the wind speed of the lower area of the building is reduced, so that monitoring the inclination information of the lower area of the building has no substantial meaning, the inclination information of the real building cannot be reflected, the coordinate information of the sensor corresponding to the highest point of the current building is obtained, if the coordinate information of the sensor is inconsistent with the coordinate information of the preset sensor, the sensor is indicated to have vertical offset due to the influence of wind force, the electronic equipment extracts the three-dimensional coordinate information contained in the coordinate information of the current sensor, and then calculates the three-dimensional coordinate information through preset rules to determine the inclination information of the current building; therefore, the deformation damage degree of the building is monitored, and the inclination information of the building under the influence of wind power is monitored, so that the monitoring is more comprehensive.

It should be noted that, the selection of the coordinate information of the sensor is based on different wind directions, that is, different wind directions, and the coordinate information of the sensor may also be different, for example, when the wind direction is from west to east, the electronic device preferentially obtains the coordinate information corresponding to the sensor closest to west at the highest point of the building.

Further, calculating the three-dimensional coordinate information through a preset rule, and determining inclination information, wherein the method specifically comprises the following steps: performing arctangent function calculation on the three-dimensional coordinate information to determine angle information; calculating the difference value between preset angle information and angle information, and determining inclination angle information; comparing the inclination angle information with preset inclination angle information; and if the inclination angle information exceeds the preset inclination angle information, determining the inclination angle information as inclination information.

In the embodiment of the application, the preset angle information defaults to ninety degrees.

Specifically, when the building is subjected to elevation deviation, the electronic equipment fixes the abscissa of three-dimensional coordinate information in the wind pressure direction to establish a three-dimensional coordinate system, and then the electronic equipment performs arctangent function calculation on the abscissa information and the vertical coordinate information in the extracted three-dimensional coordinate information to determine the angle information of the current building; for example, if the current wind direction is west, calculating coordinate information of the current sensor with the west direction as an abscissa, for example, the abscissa information is 50 meters, the ordinate information is 87 meters, and calculating to obtain angle information of the current building and the horizontal ground by using an arctan function, wherein the angle information is arctan (87/50) =60 degrees; because the angle information is the angle information of the included angle between the current building and the horizontal ground, the difference value between the preset angle information and the angle information is calculated to determine the inclination angle information of the building, the inclination angle information is the angle deviation information of the building under the influence of wind power, then the electronic equipment compares the inclination angle information with the preset inclination angle information, if the inclination angle information does not exceed the preset inclination angle information, the current building is less influenced by wind power, slight swing is generated, the safety accident of the building is not caused, and the electronic equipment does not respond to the situation and continues to monitor; if the inclination angle information exceeds the preset inclination angle information, the current building is indicated to be greatly displaced and deviated due to the influence of wind power, and therefore the electronic equipment determines the inclination angle information as inclination information; thereby facilitating the subsequent comparison.

Further, if the inclination information exceeds the preset inclination information, generating second early warning information and prompting, and then further comprising: acquiring wind power grade information corresponding to current inclination information; based on historical data analysis, determining the corresponding relation between wind power grade information and inclination information; acquiring a forecast value of wind power grade information of an environment where a building is located in a next monitoring period; based on the corresponding relation and the forecast value, determining forecast inclination information corresponding to the forecast value; if the predicted inclination information exceeds the preset inclination information, third early warning information is generated and prompted.

Specifically, the electronic equipment acquires wind power grade information obtained by monitoring a sensor corresponding to current inclination information while generating second early warning information, and stores the wind power grade information and the inclination information in a database, and then the electronic equipment determines the corresponding relation between the wind power grade information and the inclination information, namely, how much value of the wind power grade information can generate the inclination information of how much value based on historical data analysis; the electronic equipment acquires a forecast value of wind power grade information of the environment where the current building is located in a next monitoring period; based on the corresponding relation between the wind power grade information and the inclination information, determining the predicted inclination information corresponding to the forecast value of the wind power grade information in a future period of time, and then comparing the predicted inclination information with preset inclination information, if the predicted inclination information does not exceed the preset inclination information, the building is indicated not to bear serious wind disasters in the future period of time, so that the electronic equipment does not perform early warning, if the predicted inclination information exceeds the preset inclination information, the predicted inclination information of the electronic equipment indicates that the current building possibly has inclination accidents, so that the electronic equipment generates third early warning information of 'the current building possibly has foreseeable inclination risks, please timely process and thank you' and feeds back to the terminal for prompting; therefore, whether the building can bear the wind power of the next level is predicted, the risk pre-judgment is increased, and the quality safety of the building is further protected.

It should be noted that, the reminding mode of the first warning information, the second warning information and the third warning information may be a text warning prompt or a voice warning prompt, and the application is not limited specifically.

The intelligent monitoring device 20 for building quality may specifically include: a deformation information determination module 201, a deformation score information determination module 202, a first pre-warning module 203, and a second pre-warning module 204, wherein,

the deformation information determining module 201 is configured to obtain floor information of a building, and determine deformation information of the building based on the floor information;

the deformation score information determining module 202 is configured to determine deformation score information corresponding to the deformation information based on the deformation information;

the first early warning module 203 is configured to generate first early warning information and obtain inclination information of the building if the deformation score information exceeds the preset score information;

the second early warning module 204 is configured to generate and prompt second early warning information if the inclination information exceeds the preset inclination information.

In one possible implementation manner of the embodiment of the present application, the deformation information determining module 201 includes: a sub-floor information determining unit, a monitoring area determining unit, a sub-deformation information determining unit and a deformation information determining unit, wherein,

The sub-floor information determining unit is used for acquiring height information corresponding to the floor information, splitting the floor information according to the height information and determining a plurality of sub-floor information;

In one possible implementation manner of the embodiment of the present application, the sub-deformation information determining unit is specifically configured to:

An intelligent monitoring device 20 for building quality according to one possible implementation of the embodiment of the present application includes: a weight information acquisition module, a sub-score information determination module and a score information determination module, wherein,

the sub-value information determining module is used for multiplying the plurality of sub-deformation information with the corresponding weight information respectively to determine a plurality of sub-deformation value information;

and the score information determining module is used for carrying out addition calculation on the plurality of sub-deformation score information and determining deformation score information.

In one possible implementation manner of the embodiment of the present application, the second early warning module 204 includes: a coordinate information determining unit, an extracting unit, and a tilt information determining unit, wherein,

the extraction unit is used for extracting three-dimensional coordinate information in the sensor coordinate information if the sensor coordinate information is inconsistent with the preset sensor coordinate information;

One possible implementation manner of the embodiment of the present application, the extraction unit is specifically configured to:

Calculating the difference value between preset angle information and angle information, and determining inclination angle information;

and if the inclination angle information exceeds the preset inclination angle information, determining the inclination angle information as inclination information.

In one possible implementation manner of the embodiment of the present application, the intelligent monitoring device 20 for building quality further includes: the system comprises a grade information acquisition module, a corresponding relation determination module, a forecast value determination module, a forecast inclination information determination module and a third early warning module, wherein,

It will be clear to those skilled in the art that, for convenience and brevity of description, specific working procedures of the above-described systems, apparatuses and units may refer to corresponding procedures in the foregoing method embodiments, and are not repeated herein.

The embodiment of the present application also describes an electronic device from the perspective of a physical device, as shown in fig. 3, and the electronic device 30 shown in fig. 3 includes: a processor 301 and a memory 303. Wherein the processor 301 is coupled to the memory 303, such as via a bus 302. Optionally, the electronic device 30 may also include a transceiver 304. It should be noted that, in practical applications, the transceiver 304 is not limited to one, and the structure of the electronic device 30 is not limited to the embodiment of the present application.

The processor 301 may be a CPU (Central Processing Unit ), general purpose processor, DSP (Digital Signal Processor, data signal processor), ASIC (Application Specific Integrated Circuit ), FPGA (Field Programmable Gate Array, field programmable gate array) or other programmable logic device, transistor logic device, hardware components, or any combination thereof. Which may implement or perform the various exemplary logic blocks, modules and circuits described in connection with this disclosure. Processor 301 may also be a combination that implements computing functionality, e.g., comprising one or more microprocessor combinations, a combination of a DSP and a microprocessor, etc.

Bus 302 may include a path to transfer information between the components. Bus 302 may be a PCI (Peripheral Component Interconnect, peripheral component interconnect Standard) bus or an EISA (Extended Industry Standard Architecture ) bus, or the like. Bus 302 may be divided into an address bus, a data bus, a control bus, and the like. For ease of illustration, only one thick line is shown in fig. 3, but not only one bus or one type of bus.

The Memory 303 may be, but is not limited to, a ROM (Read Only Memory) or other type of static storage device that can store static information and instructions, a RAM (Random Access Memory ) or other type of dynamic storage device that can store information and instructions, an EEPROM (Electrically Erasable Programmable Read Only Memory ), a CD-ROM (Compact Disc Read Only Memory, compact disc Read Only Memory) or other optical disk storage, optical disk storage (including compact discs, laser discs, optical discs, digital versatile discs, blu-ray discs, etc.), magnetic disk storage media or other magnetic storage devices, or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer.

The memory 303 is used for storing application program codes for executing the inventive arrangements and is controlled to be executed by the processor 301. The processor 301 is configured to execute the application code stored in the memory 303 to implement what is shown in the foregoing method embodiments.

Among them, electronic devices include, but are not limited to: mobile terminals such as mobile phones, notebook computers, digital broadcast receivers, PDAs (personal digital assistants), PADs (tablet computers), PMPs (portable multimedia players), in-vehicle terminals (e.g., in-vehicle navigation terminals), and the like, and stationary terminals such as digital TVs, desktop computers, and the like. But may also be a server or the like. The electronic device shown in fig. 3 is only an example and should not be construed as limiting the functionality and scope of use of the embodiments of the application.

It should be understood that, although the steps in the flowcharts of the figures are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited in order and may be performed in other orders, unless explicitly stated herein. Moreover, at least some of the steps in the flowcharts of the figures may include a plurality of sub-steps or stages that are not necessarily performed at the same time, but may be performed at different times, the order of their execution not necessarily being sequential, but may be performed in turn or alternately with other steps or at least a portion of the other steps or stages.

The foregoing is only a partial embodiment of the present application, and it should be noted that it will be apparent to those skilled in the art that modifications and adaptations can be made without departing from the principles of the present application, and such modifications and adaptations should and are intended to be comprehended within the scope of the present application.

Claims

1. An intelligent monitoring method for building quality is characterized by comprising the following steps:

2. The intelligent monitoring method of building quality according to claim 1, wherein the deformation information comprises a plurality of pieces of sub-deformation information, and the determining the deformation information of the building based on the floor information comprises:

3. The intelligent monitoring method for building quality according to claim 2, wherein determining deviation information corresponding to each of the plurality of sub-floor monitoring areas comprises:

4. The intelligent monitoring method of building quality according to claim 2, wherein determining deformation score information corresponding to the deformation information based on the deformation information comprises:

5. The intelligent monitoring method for building quality according to claim 1, wherein the acquiring the inclination information of the building comprises:

6. The intelligent monitoring method for building quality according to claim 5, wherein the calculating the three-dimensional coordinate information by a preset rule to determine the inclination information comprises:

7. The intelligent monitoring method of building quality according to claim 1, wherein if the inclination information exceeds a preset inclination information, generating second early warning information and prompting, and further comprising:

8. An intelligent building quality monitoring device, which is characterized by comprising:

9. An electronic device, comprising:

at least one processor;

a memory;

at least one application program, wherein the at least one application program is stored in the memory and configured to be executed by the at least one processor, the at least one application program configured to: an intelligent monitoring method of building quality according to any one of claims 1 to 7.

10. A computer readable storage medium having stored thereon a computer program, characterized in that the computer program, when executed in a computer, causes the computer to perform an intelligent monitoring method of building quality according to any of claims 1-7.