CN117233752A - Road underground disease body water content calculation and analysis method based on radar nondestructive detection - Google Patents

Abstract

The application discloses a method for calculating and analyzing the water content of an underground disease body of a road based on radar nondestructive detection, which belongs to the field of roads and is used for solving the problem that the current method for detecting the water content of the underground disease body of the road by using the radar nondestructive detection method does not consider factors such as historical diseases of the road, road environment and the like, and a historical monitoring module analyzes the historical condition of the road; the road monitoring module monitors the road condition of the road corresponding to the road number; the factor influence module analyzes influence factors of roads corresponding to the road numbers; the method comprises the steps of utilizing a calculation setting module to intelligently set the calculation grade of the water content of the road underground disease body, utilizing a data acquisition module to acquire the water content of the road underground disease body according to the calculation times, adding, summing and averaging the acquired water contents for multiple times, and then sending the water content to a user terminal, wherein the user terminal checks the water content of the road underground disease body corresponding to the road number.

Description

Road underground disease body water content calculation and analysis method based on radar nondestructive detection

Technical Field

The application belongs to the field of roads, relates to a road underground disease body water content calculating technology, and in particular relates to a road underground disease body water content calculating and analyzing method based on radar nondestructive detection.

Background

Roads refer to highways, urban roads, and places where social motor vehicles are allowed to pass although in unit jurisdictions, including squares, public parks, and the like for public traffic. Roads are the infrastructure for passing various trackless vehicles and pedestrians in word sense; according to the use characteristics, the road is divided into a highway, an urban road, a rural road, a factory and mine road, a forestry road, an examination road, a competition road, an automobile test road, a workshop channel, a school road and the like, and the ancient China also has a post road. In addition, it refers to the way to achieve a certain goal, the way things develop and change.

When the radar nondestructive detection method is used for detecting the water content of the road underground disease body, the factors such as historical diseases of the road, the environment of the area where the road is located and the like are not combined in actual operation, so that the differential detection of the water content of the road underground disease body cannot be realized;

therefore, a method for calculating and analyzing the water content of the road underground disease body based on radar nondestructive detection is provided.

Disclosure of Invention

Aiming at the defects existing in the prior art, the application aims to provide a method for calculating and analyzing the water content of underground road disease bodies based on radar nondestructive detection.

The technical problems to be solved by the application are as follows:

how to realize the differential detection of the water content of the road underground disease body based on multiple factors.

The aim of the application can be achieved by the following technical scheme:

the method for calculating and analyzing the water content of the road underground disease body based on radar nondestructive testing comprises the following steps:

step S100, a user terminal inputs a road number and sends the road number to a storage module, the storage module sends corresponding historical monitoring information to a historical monitoring module according to the road number, the historical condition of the road is analyzed through the historical monitoring module to obtain the number of historical underground disease bodies of the road, then the coverage area of each historical underground disease body in the road is obtained, the coverage area of each historical underground disease body is added and summed and divided by the number of the historical underground disease bodies to obtain the coverage average area of the underground disease body in the road, the underground depth and the duration of each historical underground disease body in the road are obtained in the same way, the underground average depth and the duration of each historical underground disease body in the road are obtained through calculation, the historical monitoring value of the road is calculated, the historical monitoring value of the road is fed back to a server by the historical monitoring module, and the historical monitoring value of the road is sent to a calculation setting module by the server;

step S200, collecting real-time flow data of a road corresponding to a road number and real-time road data of an area where the road is located through a data collecting module, and sending the real-time flow data and the real-time road data to a server, wherein the server sends the real-time flow data and the real-time road data to a road monitoring module;

step S300, a road monitoring module monitors road conditions of roads corresponding to road numbers, acquires traffic flow and traffic flow of the previous week, adds and sums the traffic flow of the previous week to obtain average value to obtain daily traffic flow of the roads, then acquires rainfall and temperature value of the previous week in the area where the roads are located, adds and sums the rainfall of the previous week to obtain average value to obtain daily rainfall of the area where the roads are located, adds and sums the temperature value of the previous week to obtain daily temperature value of the area where the roads are located, compares the daily rainfall to obtain rainfall influence coefficient of the area where the roads are located by utilizing the daily rainfall to calculate road monitoring value of the roads, and the road monitoring module feeds the road monitoring value of the roads back to a server;

step S400, the storage module sends underground construction information to the server according to the road numbers, the server sends the underground construction information to the factor influencing module, the factor influencing module analyzes the influence factors of the roads corresponding to the road numbers, the embedded lengths of all embedded pipelines in the roads are obtained, the embedded lengths of all embedded pipelines are added and summed to obtain an embedded total length value, then the embedded depths of all embedded pipelines in the roads are obtained, the minimum value of the embedded depths is obtained by comparing the embedded depths of all embedded pipelines to be used as the embedded depth value of the roads, finally the pipeline diameters of all embedded pipelines in the roads are obtained, the maximum value of the pipeline diameters is obtained by comparing the pipeline diameters of all embedded pipelines to be used as the pipeline diameter value of the roads, the embedded monitoring value of the roads is calculated, the embedded monitoring value of the roads is fed back to the server by the factor influencing module, and the embedded monitoring value of the roads is sent to the calculation setting module by the server;

step S500, intelligently setting the calculation grade of the water content of the road underground disease body by using a calculation setting module, obtaining a historical monitoring value, a road monitoring value and a buried monitoring value of the road, calculating a calculation requirement value of the road, comparing the calculation requirement value with a calculation requirement threshold value, judging the calculation grade of the water content of the road underground disease body, feeding back the calculation grade of the water content of the road underground disease body to a server by using the calculation setting module, setting the calculation times of the water content of the road underground disease body by using the server according to the calculation grade, and transmitting the calculation times of the water content of the road underground disease body to a data acquisition module by using the server;

and S600, the data acquisition module is used for acquiring the water content of the underground disease body of the road according to the calculated times, feeding back the water content acquired for multiple times to the server, adding, summing and averaging the water content acquired for multiple times by the server, and then sending the water content to the user terminal, wherein the user terminal checks the water content of the underground disease body in the road corresponding to the road number.

Further, the method relates to a server, wherein the server is connected with a data acquisition module, a calculation setting module, a factor influence module, a user terminal, a storage module, a history monitoring module and a road monitoring module;

the user terminal is used for inputting the road number and sending the road number to the storage module; the storage module is used for storing the history monitoring information of different roads and sending the corresponding history monitoring information to the history monitoring module according to the road numbers;

the history monitoring module is used for analyzing the history condition of the road, and the obtained history monitoring value of the road is sent to the calculation setting module through the server; the data acquisition module is used for acquiring real-time flow data of the road corresponding to the road number and real-time road data of the area where the road is located and transmitting the real-time flow data and the real-time road data to the road monitoring module through the server;

the road monitoring module is used for monitoring the road condition of the road corresponding to the road number, and the obtained road monitoring value of the road is sent to the calculation setting module through the server;

the storage module is also used for storing underground construction information of different roads and sending the underground construction information to the factor influence module through the server according to road numbers; the factor influence module is used for analyzing influence factors of the road corresponding to the road number, and obtaining a buried monitoring value of the road and sending the buried monitoring value to the calculation setting module;

the calculation setting module is used for intelligently setting the calculation grade of the water content of the road underground disease body, obtaining the calculation grade of the water content of the road underground disease body, feeding back the calculation grade to the server, setting the calculation times of the water content of the road underground disease body according to the calculation grade by the server, and sending the calculation times to the data acquisition module;

the data acquisition module is used for acquiring the water content of the underground disease body of the road according to the calculated times, and feeding the water content acquired for multiple times back to the server, wherein the server adds, sums and averages the water content acquired for multiple times and then sends the water content to the user terminal, and the user terminal is used for checking the water content of the underground disease body in the road corresponding to the road number.

Further, the historical monitoring information is the number of historical underground disease bodies in the road, and the coverage area, underground depth and duration of each historical underground disease body;

the real-time flow data are the traffic flow and the traffic flow of people in the week before the road;

the real-time road data is the rainfall and temperature value of the week before the area where the road is located;

the underground construction information is the buried length, buried depth and pipeline diameter of the buried pipeline in the road.

Further, the analysis process of the history monitoring module is specifically as follows:

acquiring the number of the historical underground disease bodies in the road, and recording the number of the historical underground disease bodies in the road as the number of the historical underground disease bodies;

then, obtaining the coverage area of each historical underground disease body in the road, and obtaining the coverage average area of the underground disease bodies in the road by adding and summing the coverage area of each historical underground disease body and dividing the sum by the number of the historical underground disease bodies;

similarly, the underground depth and the duration of each historical underground disease body in the road are obtained, and the underground average depth and the duration of the underground disease bodies in the road are obtained through calculation;

and calculating a historical monitoring value of the road.

Further, the monitoring process of the road monitoring module is specifically as follows:

obtaining the traffic flow and the traffic flow of the previous week of the road, adding and summing the traffic flows of the previous week to obtain the daily traffic flow of the road,

similarly, the people flow of the previous week is added, summed and averaged to obtain the daily people flow of the road;

then, the rainfall and the temperature value of the previous week of the area where the road is located are obtained, the average value is obtained by adding and summing the rainfall of the previous week to obtain the daily rainfall of the area where the road is located, and the daily temperature value of the area where the road is located is obtained by adding and summing the temperature value of the previous week to obtain the average value;

comparing the daily rainfall with the daily temperature value to obtain a rainfall influence coefficient of the area where the road is located;

and calculating a road monitoring value of the road.

Further, the analysis process of the factor influencing module is specifically as follows:

acquiring the buried lengths of all buried pipelines in a road, and adding and summing the buried lengths of all buried pipelines to obtain a buried total length value;

obtaining the burying depths of all the burying pipelines in the road, and comparing the burying depths of all the burying pipelines to obtain the minimum value of the burying depths as the burying depth value of the road;

finally, obtaining the pipeline diameters of all buried pipelines in the road, and comparing the pipeline diameters of all buried pipelines to obtain the maximum value of the pipeline diameters as the pipeline diameter value of the road;

and calculating the embedded monitoring value of the road.

Further, the working process of the calculation setting module is specifically as follows:

acquiring a historical monitoring value, a road monitoring value and a buried monitoring value of a road;

calculating a calculation requirement value of the road;

the calculation requirement value is compared with the calculation requirement threshold value, and the calculation grade of the water content of the road underground disease body is judged to be a third calculation grade, a second calculation grade or a first calculation grade.

Further, the first calculation level is higher than the second calculation level, which is higher than the third calculation level.

Further, the setting process of the calculation times specifically includes:

if the first calculation level is the first calculation level, the calculation times of the water content of the road underground disease body are Y3 times;

if the road surface disease body water content is the second calculation grade, the calculation times of the road surface disease body water content are Y2 times;

if the third calculation level is the third calculation level, the calculation times of the water content of the road underground disease body are Y1 times; wherein Y1, Y2 and Y3 are all positive integers of fixed values, and Y1 is less than Y2 and less than Y3.

Compared with the prior art, the application has the beneficial effects that:

the method comprises the steps of detecting road monitoring values of roads, sending the road monitoring values to a calculation setting module, analyzing influence factors of the roads corresponding to road numbers by utilizing a factor influence module, sending the obtained embedded monitoring values of the roads to the calculation setting module, intelligently setting the calculation grades of the water content of the underground disease bodies of the roads by combining the historical monitoring values, the road detecting values and the embedded monitoring values to obtain the calculation grades of the water content of the underground disease bodies of the roads, setting the calculation times of the water content of the underground disease bodies of the roads according to the calculation grades, adding and summing the water content of the underground disease bodies of the roads for a plurality of times according to the calculation times, and sending the sum average value to a user terminal.

Drawings

The present application is further described below with reference to the accompanying drawings for the convenience of understanding by those skilled in the art.

FIG. 1 is a workflow diagram of the present application;

fig. 2 is an overall system block diagram of the present application.

Detailed Description

The technical solutions of the present application will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present application, not all embodiments. 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.

Referring to fig. 1, the method for calculating and analyzing the water content of the road underground disease based on the radar nondestructive test specifically comprises the following steps:

step S100, a user terminal inputs a road number and sends the road number to a storage module, the storage module sends corresponding historical monitoring information to a historical monitoring module according to the road number, the historical condition of the road is analyzed through the historical monitoring module to obtain the number of historical underground disease bodies of the road, then the coverage area of each historical underground disease body in the road is obtained, the coverage area of each historical underground disease body is added and summed and divided by the number of the historical underground disease bodies to obtain the coverage average area of the underground disease body in the road, the underground depth and the duration of each historical underground disease body in the road are obtained in the same way, the underground average depth and the duration of each historical underground disease body in the road are obtained through calculation, the historical monitoring value of the road is calculated, the historical monitoring value of the road is fed back to a server by the historical monitoring module, and the historical monitoring value of the road is sent to a calculation setting module by the server;

step S200, collecting real-time flow data of a road corresponding to a road number and real-time road data of an area where the road is located through a data collecting module, and sending the real-time flow data and the real-time road data to a server, wherein the server sends the real-time flow data and the real-time road data to a road monitoring module;

step S300, a road monitoring module monitors road conditions of roads corresponding to road numbers, acquires traffic flow and traffic flow of the previous week, adds and sums the traffic flow of the previous week to obtain average value to obtain daily traffic flow of the roads, then acquires rainfall and temperature value of the previous week in the area where the roads are located, adds and sums the rainfall of the previous week to obtain average value to obtain daily rainfall of the area where the roads are located, adds and sums the temperature value of the previous week to obtain daily temperature value of the area where the roads are located, compares the daily rainfall to obtain rainfall influence coefficient of the area where the roads are located by utilizing the daily rainfall to calculate road monitoring value of the roads, and the road monitoring module feeds the road monitoring value of the roads back to a server;

step S400, the storage module sends underground construction information to the server according to the road numbers, the server sends the underground construction information to the factor influencing module, the factor influencing module analyzes the influence factors of the roads corresponding to the road numbers, the embedded lengths of all embedded pipelines in the roads are obtained, the embedded lengths of all embedded pipelines are added and summed to obtain an embedded total length value, then the embedded depths of all embedded pipelines in the roads are obtained, the minimum value of the embedded depths is obtained by comparing the embedded depths of all embedded pipelines to be used as the embedded depth value of the roads, finally the pipeline diameters of all embedded pipelines in the roads are obtained, the maximum value of the pipeline diameters is obtained by comparing the pipeline diameters of all embedded pipelines to be used as the pipeline diameter value of the roads, the embedded monitoring value of the roads is calculated, the embedded monitoring value of the roads is fed back to the server by the factor influencing module, and the embedded monitoring value of the roads is sent to the calculation setting module by the server;

step S500, intelligently setting the calculation grade of the water content of the road underground disease body by using a calculation setting module, obtaining a historical monitoring value, a road monitoring value and a buried monitoring value of the road, calculating a calculation requirement value of the road, comparing the calculation requirement value with a calculation requirement threshold value, judging the calculation grade of the water content of the road underground disease body, feeding back the calculation grade of the water content of the road underground disease body to a server by using the calculation setting module, setting the calculation times of the water content of the road underground disease body by using the server according to the calculation grade, and transmitting the calculation times of the water content of the road underground disease body to a data acquisition module by using the server;

step S600, the data acquisition module is used for acquiring the water content of the underground disease body of the road according to the calculated times, and feeding back the water content acquired for multiple times to the server, the server adds, sums and averages the water content acquired for multiple times and then sends the water content to the user terminal, and the user terminal checks the water content of the underground disease body in the road corresponding to the road number;

specifically, as shown in fig. 2, the method for calculating and analyzing the water content of the underground disease body of the road involves a server, wherein the server is connected with a data acquisition module, a calculation setting module, a factor influence module, a user terminal, a storage module, a history monitoring module and a road monitoring module;

the user terminal is used for registering a login server after personnel input personal information and sending the personal information to the server, wherein the personal information is the name, the mobile phone number, the identity card number and the like of the personnel;

in this embodiment, the user terminal is configured to input a road number, and send the road number to a storage module, where the storage module is a related device including a cloud storage, yun Pan, and the like; the storage module is used for storing the history monitoring information of different roads and sending the corresponding history monitoring information to the history monitoring module according to the road numbers;

the method for detecting the road disease bodies mainly comprises a radar nondestructive detection method;

the history monitoring module is used for analyzing the history condition of the road, and the analysis process is specifically as follows:

acquiring the number of the historical underground disease bodies in the road, and recording the number of the historical underground disease bodies in the road as the number of the historical underground disease bodies BS;

then, obtaining the coverage area of each historical underground disease body in the road, and obtaining the coverage average area FM of the underground disease bodies in the road by adding and summing the coverage area of each historical underground disease body and dividing the sum by the number of the historical underground disease bodies;

similarly, the underground depth and the duration of each historical underground disease body in the road are obtained, and the underground average depth SD and the duration CT of the underground disease bodies in the road are obtained through calculation;

the history monitoring value LJ of the road is calculated by the formula LJ= (BS×a1+FM×a2++ CT×a3)/(SD×a4); wherein a1, a2, a3 and a4 are all proportionality coefficients with fixed values, and the values of a1, a2, a3 and a4 are all larger than zero;

the history monitoring module feeds back the history monitoring value LJ of the road to the server, and the server sends the history monitoring value LJ of the road to the calculation setting module;

the data acquisition module is used for acquiring real-time flow data of a road corresponding to the road number and real-time road data of an area where the road is located, and transmitting the real-time flow data and the real-time road data to the server, and the server transmits the real-time flow data and the real-time road data to the road monitoring module;

the real-time flow data is the traffic flow, the people flow and the like of the week before the road; the real-time road data is rainfall, temperature value and the like of the previous week of the area where the road is located;

in practice, the data acquisition module is a flowmeter, a rain gauge, a sensor assembly and the like which are arranged in the road corresponding to the road number, the flowmeter can record the traffic flow and the people flow, the rain gauge can count the rainfall of the area where the road is located, and the sensor assembly can acquire the temperature value of the area where the road is located;

the road monitoring module is used for monitoring the road condition of the road corresponding to the road number, and the monitoring process is specifically as follows:

obtaining the traffic flow and the traffic flow of the previous week of the road, adding and summing the traffic flows of the previous week to obtain the average value of the traffic flows of the road to obtain the daily traffic flow RCL of the road,

similarly, the people flow of the previous week is added, summed and averaged to obtain the daily people flow RRL of the road;

then, the rainfall and the temperature value of the previous week of the area where the road is located are obtained, the average value is obtained by adding and summing the rainfall of the previous week to obtain the daily rainfall of the area where the road is located, and the daily temperature value of the area where the road is located is obtained by adding and summing the temperature value of the previous week to obtain the average value;

comparing the daily rainfall with the daily temperature value to obtain a rainfall influence coefficient YX of the area where the road is located;

calculating a road monitoring value DJ of the road through a formula DJ= (RCL+RRL) multiplied by YX;

it can be understood that the daily traffic flow, the daily traffic flow and the rainfall influence coefficient are in direct proportion to the road monitoring value, namely the larger the value of the daily traffic flow, the daily traffic flow and the rainfall influence coefficient is, the larger the value of the road monitoring value is;

the road monitoring module feeds back a road monitoring value DJ of the road to the server, and the server sends the road monitoring value DJ of the road to the calculation setting module;

the storage module is also used for storing underground construction information of different roads, sending the underground construction information to the server according to road numbers, and sending the underground construction information to the factor influence module by the server;

the underground construction information is the buried length, the buried depth and the pipeline diameter of a buried pipeline in the road, wherein the buried pipeline comprises a sewer pipeline, a gas pipeline, an electric pipeline and the like in the road;

the factor influence module is used for analyzing influence factors of roads corresponding to the road numbers, and the analysis process is specifically as follows:

acquiring the buried lengths of all buried pipelines in a road, adding and summing the buried lengths of all buried pipelines to obtain a buried total length value, and recording the buried total length value as MC;

acquiring the burying depths of all the burying pipelines in the road, and comparing the burying depths of all the burying pipelines to obtain a minimum value of the burying depths as a burying depth value MS of the road;

finally, obtaining the pipeline diameters of all buried pipelines in the road, and comparing the pipeline diameters of all buried pipelines to obtain the maximum value of the pipeline diameters as a pipeline diameter value GZ of the road;

calculating to obtain a buried monitoring value MJ of the road through a formula MJ= (MC+GZ)/MS;

the factor influence module feeds back the embedded monitoring value MJ of the road to the server, and the server sends the embedded monitoring value MJ of the road to the calculation setting module;

the calculation setting module is used for intelligently setting the calculation grade of the water content of the road underground disease body, and the working process is specifically as follows:

acquiring the historical monitoring value LJ, the road monitoring value DJ and the embedded monitoring value MJ of the road obtained by calculation;

calculating to obtain a calculation requirement value JY of the road through a formula JY=LJ×b1+DJ×b2+MJ×b3; wherein b1, b2 and b3 are all proportional coefficients with fixed values, and the values of b1, b2 and b3 are all larger than zero;

if JY is less than X1, the calculation grade of the water content of the road underground disease body is a third calculation grade;

if X1 is less than or equal to JY and less than X2, the calculation grade of the water content of the road underground disease body is a second calculation grade;

if X2 is less than or equal to JY; the calculated grade of the water content of the road underground disease body is the first calculated grade; wherein X1 and X2 are calculation requirement thresholds with fixed values, and X1 is less than X2;

it should be explained that the first calculation level is higher than the second calculation level, which is higher than the third calculation level;

the calculation setting module feeds back the calculation grade of the water content of the road underground disease body to the server, and the server sets the calculation times of the water content of the road underground disease body according to the calculation grade, specifically:

if the first calculation level is the first calculation level, the calculation times of the water content of the road underground disease body are Y3 times;

if the road surface disease body water content is the second calculation grade, the calculation times of the road surface disease body water content are Y2 times;

if the third calculation level is the third calculation level, the calculation times of the water content of the road underground disease body are Y1 times; wherein Y1, Y2 and Y3 are all positive integers with fixed values, and Y1 is more than Y2 and less than Y3;

the server sends the calculated times of the water content of the road underground disease body to the data acquisition module, the data acquisition module is used for acquiring the water content of the road underground disease body according to the calculated times and feeding back the water content acquired for multiple times to the server, the server adds, sums and averages the water content acquired for multiple times and then sends the water content to the user terminal, and the user terminal is used for checking the water content of the underground disease body in the road corresponding to the road number;

in the concrete implementation, the acquisition of the water content of the road underground disease body can adopt a seismic imaging method, a ground penetrating radar method and high-density resistivity;

in the implementation, the detection method of the road disease body adopts radar nondestructive detection;

in the application, if a corresponding calculation formula appears, the calculation formulas are all dimensionality-removed and numerical calculation, and the weight coefficient, the proportion coefficient and other coefficients in the formulas are set to be a result value obtained by quantizing each parameter, so long as the proportion relation between the parameter and the result value is not influenced.

The preferred embodiments of the application disclosed above are intended only to assist in the explanation of the application. The preferred embodiments are not intended to be exhaustive or to limit the application to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the application and the practical application, to thereby enable others skilled in the art to best understand and utilize the application. The application is limited only by the claims and the full scope and equivalents thereof.

Claims (9)

1. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive test is characterized by comprising the following steps of:

step S100, a user terminal inputs a road number, a storage module sends corresponding history monitoring information to a history monitoring module according to the road number, the history monitoring module analyzes the history condition of the road, and a history monitoring value of the road is obtained and sent to a calculation setting module;

step S200, the data acquisition module acquires real-time flow data of a road corresponding to the road number and real-time road data of an area where the road is located, and the real-time flow data and the real-time road data are sent to the road monitoring module;

step S300, a road monitoring module monitors the road condition of the road corresponding to the road number, and the obtained road monitoring value of the road is sent to a calculation setting module;

step S400, the storage module further sends the underground construction information to the factor influence module according to the road number, and the factor influence module analyzes influence factors of the road corresponding to the road number, so that an embedded monitoring value of the road is obtained and sent to the calculation setting module;

step S500, intelligently setting the calculation grade of the water content of the road underground disease body by using a calculation setting module to obtain the calculation grade of the water content of the road underground disease body, and setting the calculation times of the water content of the road underground disease body according to the calculation grade and sending the calculation times to a data acquisition module;

and S600, the data acquisition module acquires the water content of the underground disease body of the road according to the calculated times, and the water content acquired for multiple times is added, summed and averaged and then sent to the user terminal, and the user terminal checks the water content of the underground disease body in the road corresponding to the road number.

2. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive testing according to claim 1, wherein the method is characterized by comprising a server, wherein the server is connected with a data acquisition module, a calculation setting module, a factor influence module, a user terminal, a storage module, a history monitoring module and a road monitoring module;

the user terminal is used for inputting the road number and sending the road number to the storage module;

the storage module is used for storing the history monitoring information of different roads and sending the corresponding history monitoring information to the history monitoring module according to the road numbers;

the history monitoring module is used for analyzing the history condition of the road, obtaining a history monitoring value of the road and sending the history monitoring value to the calculation setting module through the server;

the data acquisition module is used for acquiring real-time flow data of the road corresponding to the road number and real-time road data of the area where the road is located and sending the real-time flow data and the real-time road data to the road monitoring module through the server;

the road monitoring module is used for monitoring the road condition of the road corresponding to the road number, and the obtained road monitoring value of the road is sent to the calculation setting module through the server;

the storage module is also used for storing underground construction information of different roads and sending the underground construction information to the factor influence module through the server according to road numbers;

the factor influence module is used for analyzing influence factors of the road corresponding to the road number to obtain a buried monitoring value of the road, and transmitting the buried monitoring value to the calculation setting module;

the calculation setting module is used for intelligently setting the calculation level of the water content of the road underground disease body, obtaining the calculation level of the water content of the road underground disease body, feeding back to the server, setting the calculation times of the water content of the road underground disease body according to the calculation level by the server, and sending the calculation times to the data acquisition module;

the data acquisition module is used for acquiring the water content of the road underground disease body according to the calculated times, feeding the water content acquired for multiple times back to the server, adding, summing and averaging the water content acquired for multiple times by the server, and then sending the water content to the user terminal;

and the user terminal is used for checking the water content of the underground disease body in the road corresponding to the road number.

3. The method for calculating and analyzing the water content of the underground disease body of the road based on the radar nondestructive test according to claim 2, wherein the historical monitoring information is the number of the underground disease bodies in the road, and the coverage area, the underground depth and the duration of each underground disease body;

the real-time flow data are the traffic flow and the traffic flow of people in the week before the road;

the real-time road data is the rainfall and temperature value of the week before the area where the road is located;

the underground construction information is the buried length, buried depth and pipeline diameter of the buried pipeline in the road.

4. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive testing according to claim 2, wherein the analysis process of the history monitoring module is specifically as follows:

acquiring the number of the historical underground disease bodies in the road, and recording the number of the historical underground disease bodies in the road as the number of the historical underground disease bodies;

then, obtaining the coverage area of each historical underground disease body in the road, and obtaining the coverage average area of the underground disease bodies in the road by adding and summing the coverage area of each historical underground disease body and dividing the sum by the number of the historical underground disease bodies;

similarly, the underground depth and the duration of each historical underground disease body in the road are obtained, and the underground average depth and the duration of the underground disease bodies in the road are obtained through calculation;

and calculating a historical monitoring value of the road.

5. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive testing according to claim 2, wherein the monitoring process of the road monitoring module is specifically as follows:

obtaining the traffic flow and the traffic flow of the previous week of the road, adding and summing the traffic flows of the previous week to obtain the daily traffic flow of the road,

similarly, the people flow of the previous week is added, summed and averaged to obtain the daily people flow of the road;

then obtaining the rainfall and temperature value of the previous week of the area where the road is located, adding and summing the rainfall of the previous week to obtain the average value to obtain the daily rainfall of the area where the road is located, and obtaining the daily temperature value of the area where the road is located by the same method;

comparing the daily rainfall with the daily temperature value to obtain a rainfall influence coefficient of the area where the road is located;

and calculating a road monitoring value of the road.

6. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive testing according to claim 2, wherein the analysis process of the factor influence module is specifically as follows:

acquiring the buried lengths of all buried pipelines in a road, and adding and summing the buried lengths of all buried pipelines to obtain a buried total length value;

obtaining the burying depths of all the burying pipelines in the road, and comparing the burying depths of all the burying pipelines to obtain the minimum value of the burying depths as the burying depth value of the road;

finally, obtaining the pipeline diameters of all buried pipelines in the road, and comparing the pipeline diameters of all buried pipelines to obtain the maximum value of the pipeline diameters as the pipeline diameter value of the road;

and calculating the embedded monitoring value of the road.

7. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive testing according to claim 2, wherein the working process of the calculation setting module is specifically as follows:

acquiring a historical monitoring value, a road monitoring value and a buried monitoring value of a road;

calculating a calculation requirement value of the road;

the calculation requirement value is compared with the calculation requirement threshold value, and the calculation grade of the water content of the road underground disease body is judged to be a third calculation grade, a second calculation grade or a first calculation grade.

8. The method for calculating and analyzing the water content of the road underground disease body based on the radar non-destructive inspection according to claim 7, wherein the first calculation level is higher than the second calculation level, and the second calculation level is higher than the third calculation level.

9. The method for calculating and analyzing the water content of the road underground disease body based on the radar nondestructive testing according to claim 7, wherein the setting process of the calculation times is specifically as follows:

if the first calculation level is the first calculation level, the calculation times of the water content of the road underground disease body are Y3 times;

if the road surface disease body water content is the second calculation grade, the calculation times of the road surface disease body water content are Y2 times;

if the third calculation level is the third calculation level, the calculation times of the water content of the road underground disease body are Y1 times; wherein Y1, Y2 and Y3 are all positive integers of fixed values, and Y1 is less than Y2 and less than Y3.