CN114139380A - Hydraulic engineering safety management system - Google Patents

Abstract

The invention discloses a hydraulic engineering safety management system, which comprises a data acquisition module, a cloud storage module, a data analysis module, a dynamic monitoring module, an alarm module and an adjustment module, wherein the environment analysis module analyzes environmental influence data and human activity data to obtain an influence degree value of environmental and human influence factors on rainfall and sends the influence degree value to the rainwater analysis module, the rainwater analysis module analyzes the rainfall in a divided region to obtain a rainwater analysis result, the water storage analysis module analyzes the rainwater analysis result and comprehensive data to obtain a water storage analysis result, the dynamic monitoring module performs dynamic monitoring analysis according to the data analysis result and real-time monitoring data to obtain a monitoring analysis result and sends the monitoring analysis result to the alarm module, and managers perform emergency flood control measures through the adjustment module according to the alarm result, the timeliness of flood control measures is improved, and the safety management degree is improved.

Description

Hydraulic engineering safety management system

Technical Field

The invention relates to the technical field of engineering management, in particular to a hydraulic engineering safety management system.

Background

The water conservancy project is concerned about the key of the national civilian development and the environmental protection, severe weather environment can bring great pressure to the management of the water conservancy project, such as flood disasters, flood not only threatens the life safety of people, but also causes great economic loss, and flood control is an important task in the water conservancy project; with the development of the digital era, the management of hydraulic engineering tends to be more and more digital, a plurality of hydrodynamic analysis models exist in the prior art, a real-time dynamic analysis model is established by a computer to carry out dynamic exercise and risk prediction on flood disasters, the analysis result of the analysis model is utilized to prevent and treat the flood, for example, the process of analyzing by utilizing the coupling of the one-dimensional hydrodynamic analysis model and the two-dimensional hydrodynamic analysis model overcomes the problems of long analysis time, low analysis efficiency and single module in the analysis process, the simulation results of flood analysis using mathematical models are affected by a number of factors, for example, threshold selection of environmental influence factor influence, selection of an analysis model, and geographic environment influence factors all influence the flood risk prediction result, and it is difficult to utilize the flood risk prediction result to achieve an actual effect in an actual flood control plan; particularly, in case of flood control in inland cities, even considering factors such as water storage capacity, geographical location, seasonal climate, precipitation, etc., when extreme sudden weather conditions such as a very large flood disaster occur, a rapid and effective emergency prevention plan cannot be directly obtained, so that personal and property safety cannot be effectively guaranteed.

Disclosure of Invention

In view of the above situation and overcoming the drawbacks of the prior art, an object of the present invention is to provide a hydraulic engineering safety management system, in which an environment analysis module of a data analysis module considers the influence of environmental impact factors and human activities in the influence on rainfall through comprehensive data analysis, so that the rainfall is more accurately analyzed, a water storage analysis result is obtained by analyzing the water storage capacity of the whole arrangement in each partitioned area through a water storage analysis module, and a monitoring analysis result is obtained by analyzing a data analysis result and real-time monitoring data when a dynamic analysis module performs real-time analysis, so that the management of the rainfall in the partitioned area is improved, the timeliness of responding to flood is greatly improved through the data analysis, and the safe and stable operation of the hydraulic engineering is ensured.

The technical scheme of its solution is, a hydraulic engineering safety management system, including the data acquisition module, cloud storage module, data analysis module, dynamic monitoring module, the alarm module, the adjustment module, data analysis module includes rainwater analysis module, retaining analysis module and environmental analysis module, the data analysis module utilizes the comprehensive data that data acquisition module gathered to establish data analysis module and carry out the analysis and obtain the data analysis result, dynamic monitoring module carries out dynamic monitoring analysis according to data analysis result and real time monitoring data and obtains the monitoring analysis result, and with monitoring analysis result transmission to alarm module, managers carries out urgent flood control measure through the adjustment module according to the alarm result, dynamic monitoring module monitors the progression of flood disasters taking place in the specified area, the system management process is specifically as follows:

(1) the data acquisition module acquires comprehensive data of the divided regions and stores the comprehensive data in the cloud storage module, wherein the comprehensive data comprises environmental impact data, rainfall data, water storage building quality monitoring data and human activity data;

(2) the environment analysis module, the rainwater analysis module and the water storage analysis module analyze by utilizing the comprehensive data to obtain a data analysis result, and send the data analysis result to the dynamic monitoring module and the cloud storage module, the environment analysis module analyzes by utilizing the environment influence data and the human activity data to obtain the influence degree value of the influence factors of the environment and the human on the rainfall, and sends the influence degree value to the rainwater analysis module, the rainwater analysis module analyzes the rainfall in the divided area to obtain a rainwater analysis result, the water storage analysis module analyzes by utilizing the rainwater analysis result and the comprehensive data to obtain a water storage analysis result, and the specific analysis process is as follows:

step 1, the environment analysis module selects N time periods, which are marked as t_i(i ═ 1,2,3 … N), for a period of time t_iThe intensity of the corresponding temperature fluctuations is denoted w_iTime period t_iThe evaporation capacity of the corresponding water vapor is H_iThe environment analysis module extracts time periods t corresponding to M different sub-regions in the divided regions in the storage data of the cloud storage module_iInternal rainfall and is recorded as

Establishing a matrix A corresponding to rainfall in the divided areas as follows:

environmental analysis module using fluctuation intensity w of temperature_iWater vapor evaporation capacity H_iAn environmental impactSolving the influence value of an environmental influence factor on the precipitation by using the parameter value c of the factor and the matrix A

The analytical equation is as follows:

wherein

Showing the influence value of the jth environmental influence factor, and respectively calculating the influence values of the environmental influence factors in the comprehensive data to obtain a set

Selecting K human activity data and L environmental influence factors in the divided region from the cloud storage module, and recording the parameter value corresponding to the human activity as p₁,p₂,p₃…p_KBy using

Value of parameter (p) within₁,p₂,p₃…p_K) Obtaining a parameter change rate matrix Δ P ═ Δ P₁,Δp₂,Δp₃…Δp_K) Using the parameter rate of change matrix Δ P and the set

The corresponding matrix calculates the influence degree value alpha of the environmental influence factors and the human activities on the precipitation, and sends the alpha to the rainwater analysis module, and the calculation equation is as follows:

step 2, the rainwater analysis module calculates error values between the predicted rainfall and the actual rainfall in different time periods, obtains a corresponding matrix B, analyzes the influence degree value alpha, the rainfall data and the matrix B by using a mathematical analysis model to obtain a rainwater analysis result, and sends the rainwater analysis result to the rainwater analysis module, wherein the rainwater analysis result comprises a water storage load value Y brought by the rainfall, and the concrete process is as follows:

wherein, V_iRepresents the average flow velocity u of a river in a divided region corresponding to the ith time period in rainfall data_i(t) represents river water flow over a period of time;

step 3, analyzing the buildings of rivers and reservoirs in the divided regions by a water storage analysis module, analyzing the water storage capacity in the whole divided region by combining water storage load values to obtain water storage data results, and dividing the water storage data results into different grades according to the total water storage capacity in the divided regions, wherein the data analysis results comprise rainwater analysis results, influence degree values and water storage analysis results;

(3) the dynamic monitoring module carries out real-time monitoring by utilizing a data analysis result and real-time monitoring data, the real-time monitoring data comprises monitoring data of rainfall, the dynamic monitoring module firstly carries out data analysis on the real-time monitoring data to obtain a real-time result, then calculates by utilizing a water storage analysis result to obtain a water storage threshold value, finally compares the real-time result with the value of the water storage threshold value, and when the set water storage threshold value is exceeded, the dynamic monitoring module sends a monitoring analysis result to the alarm module.

The dynamic monitoring module carries out real-time monitoring by utilizing the data analysis result and the real-time monitoring data to obtain a monitoring analysis result, and the specific analysis process is as follows:

step one, including intersection water flow q in real-time monitoring data_rkDomestic water consumption Q_roWithin a divided regionWater storage quantity Q of water storage building_rgWater flow at junction Q_kAbsolute values of the amounts of water including inflow and outflow of water;

step two, establishing a decision objective function according to all real-time monitoring data in the divided region, sequencing all buildings with water storage in the divided region, and analyzing, wherein the specific equation is as follows:

Q_rg＝c₃U_rkG_r,

wherein ξ_r、c₁、c₂、c₃All are normal numbers, represent the water inlet coefficient of the intersection and the water storage building, and utilize Q_rk、Q_ro、Q_rgEstablishing a three-dimensional analysis model for data simulation analysis to obtain a water storage risk pressure value;

and 4, comparing the water storage risk pressure value with a water storage threshold value by the dynamic management module, wherein the water storage threshold value is obtained by analyzing according to a water storage analysis result, establishing a target decision function according to a data analysis result, and making a strategy according to the target decision analysis result.

The water storage analysis module analyzes the buildings storing water, analyzes the water storage capacity of the buildings storing water and the data of the buildings per se to obtain the water storage analysis result in the whole divided region, analyzes the decay of the data of all the buildings storing water in the divided region including the building construction data, the building detection data and the building pressure bearing data, and analyzes the corresponding relation between the water storage capacity and the building aging degree.

Due to the adoption of the technical scheme, compared with the prior art, the invention has the following advantages;

the data analysis module of the system comprises a rainwater analysis module, a water storage analysis module and an environment analysis module, wherein the data analysis module obtains a data analysis result through comprehensive analysis of comprehensive data, the change condition of an influence factor influencing rainfall can be mastered through the data analysis result, so that the rainfall is more accurately analyzed, the environment analysis module analyzes the influence degree value of human activity factors and environmental influence factors on the rainfall, the rainwater analysis module analyzes the rainfall by utilizing the influence degree value to obtain a rainwater analysis result, the rainwater analysis result is the influence of the rainfall with abnormal rainfall exceeding a normal range, the water storage analysis module analyzes the water storage quantity in the whole divided area, the safety problem caused by the factor influencing the rainfall and the water storage capacity of the water storage building is comprehensively considered, the consumption degree of the hydraulic structure is obtained through calculation and analysis of the data, the dynamic monitoring module of the system analyzes the data analysis result and the real-time monitoring data again to obtain a monitoring analysis result, and can adopt a flood control plan in time when the rainfall is abnormal according to the monitoring analysis result, so that the timeliness of flood control measures in the water conservancy project is improved.

Drawings

FIG. 1 is an overall block diagram of the system;

FIG. 2 is a block diagram of a data analysis module;

FIG. 3 is an analysis flow diagram of the data analysis module.

Detailed Description

The foregoing and other aspects, features and advantages of the invention will be apparent from the following more particular description of embodiments of the invention, as illustrated in the accompanying drawings in which reference is made to figures 1 to 3. The structural contents mentioned in the following embodiments are all referred to the attached drawings of the specification.

The utility model provides a hydraulic engineering safety management system, including the data acquisition module, cloud storage module, the data analysis module, dynamic monitoring module, the alarm module, the adjustment module, the data analysis module includes rainwater analysis module, retaining analysis module and environmental analysis module, the data analysis module utilizes the comprehensive data of data acquisition module collection to establish data analysis module and carry out the analysis and obtain the data analysis result, dynamic monitoring module carries out dynamic monitoring analysis according to data analysis result and real time monitoring data and obtains monitoring analysis result, and send monitoring analysis result to the alarm module, managers carries out urgent flood control measure through the adjustment module according to the alarm result, dynamic monitoring module monitors the progression of flood disasters emergence in the specified area, system management process specifically as follows:

(1) the data acquisition module acquires comprehensive data of the divided regions and stores the comprehensive data in the cloud storage module, the comprehensive data comprises environmental impact data, rainfall data, water storage building quality monitoring data and human activity data, the comprehensive data also comprises weather data, and the weather data comprises weather prediction data and actual weather data;

(2) the environment analysis module, the rainwater analysis module and the water storage analysis module analyze by utilizing the comprehensive data to obtain a data analysis result, and send the data analysis result to the dynamic monitoring module and the cloud storage module, the environment analysis module analyzes by utilizing the environment influence data and the human activity data to obtain the influence degree value of the influence factors of the environment and the human on the rainfall, and sends the influence degree value to the rainwater analysis module, the rainwater analysis module analyzes the rainfall in the divided area to obtain a rainwater analysis result, the water storage analysis module analyzes by utilizing the rainwater analysis result and the comprehensive data to obtain a water storage analysis result, and the specific analysis process is as follows:

step 1, the environment analysis module selects N time periods, which are marked as t_i(i ═ 1,2,3 … N), for a period of time t_iThe intensity of the corresponding temperature fluctuations is denoted w_iTime period t_iThe evaporation capacity of the corresponding water vapor is H_iThe environment analysis module extracts time periods t corresponding to M different sub-regions in the divided regions in the storage data of the cloud storage module_iInternal rainfall and is recorded as

Establishing a matrix A corresponding to rainfall in the divided areas as follows:

environmental analysis module using fluctuation intensity w of temperature_iWater vapor evaporation capacity H_iSolving the influence value of the environmental influence factor on the precipitation by the parameter value c of the environmental influence factor and the matrix A

The analytical equation is as follows:

wherein

Showing the influence value of the jth environmental influence factor, and respectively calculating the influence values of the environmental influence factors in the comprehensive data to obtain a set

Selecting K human activity data and L environmental influence factors in the divided region from the cloud storage module, and recording the parameter value corresponding to the human activity as p₁,p₂,p₃…p_KBy using

Value of parameter (p) within₁,p₂,p₃…p_K) Obtaining a parameter change rate matrix Δ P ═ Δ P₁,Δp₂,Δp₃…Δp_K) Using the parameter rate of change matrix Δ P and the set

Corresponding matrix computing environmental impact factors andthe degree of influence value alpha of human activities on the precipitation is sent to the rainwater analysis module, and the calculation equation is as follows:

step 2, the rainwater analysis module calculates error values between the predicted rainfall and the actual rainfall in different time periods, obtains a corresponding matrix B, analyzes the influence degree value alpha, the rainfall data and the matrix B by using a mathematical analysis model to obtain a rainwater analysis result, and sends the rainwater analysis result to the rainwater analysis module, wherein the rainwater analysis result comprises a water storage load value Y brought by the rainfall, and the concrete process is as follows:

wherein, V_iRepresents the average flow velocity u of a river in a divided region corresponding to the ith time period in rainfall data_i(t) represents river water flow over a period of time;

step 3, analyzing the buildings of rivers and reservoirs in the divided regions by a water storage analysis module, analyzing the water storage capacity in the whole divided region by combining water storage load values to obtain water storage data results, and dividing the water storage data results into different grades according to the total water storage capacity in the divided regions, wherein the data analysis results comprise rainwater analysis results, influence degree values and water storage analysis results;

(3) the dynamic monitoring module carries out real-time monitoring by utilizing a data analysis result and real-time monitoring data, the real-time monitoring data comprises monitoring data of rainfall, the dynamic monitoring module firstly carries out data analysis on the real-time monitoring data to obtain a real-time result, then calculates by utilizing a water storage analysis result to obtain a water storage threshold value, finally compares the real-time result with the value of the water storage threshold value, and when the set water storage threshold value is exceeded, the dynamic monitoring module sends a monitoring analysis result to the alarm module.

The dynamic monitoring module carries out real-time monitoring by utilizing the data analysis result and the real-time monitoring data to obtain a monitoring analysis result, and the specific analysis process is as follows:

step one, including intersection water flow q in real-time monitoring data_rkDomestic water consumption Q_roWater storage capacity Q of water storage building in divided region_rgWater flow at junction Q_kAbsolute values of the amounts of water including inflow and outflow of water;

step two, establishing a decision objective function according to all real-time monitoring data in the divided region, sequencing all buildings with water storage in the divided region, and analyzing, wherein the specific equation is as follows:

Q_rg＝c₃U_rkG_r,

wherein ξ_r、c₁、c₂、c₃All are normal numbers, represent the water inlet coefficient of the intersection and the water storage building, and utilize Q_rk、Q_ro、Q_rgEstablishing a three-dimensional analysis model for data simulation analysis to obtain a water storage risk pressure value;

and 4, comparing the water storage risk pressure value with a water storage threshold value by the dynamic management module, wherein the water storage threshold value is obtained by analyzing according to a water storage analysis result, establishing a target decision function according to a data analysis result, and making a strategy according to the target decision analysis result.

The water storage analysis module analyzes the buildings storing water, analyzes the water storage capacity of the buildings storing water and the data of the buildings per se to obtain the water storage analysis result in the whole divided region, analyzes the decay of the data of all the buildings storing water in the divided region including the building construction data, the building detection data and the building pressure bearing data, and analyzes the corresponding relation between the water storage capacity and the building aging degree.

The dynamic monitoring module analyzes real-time monitoring data during rainfall to obtain a monitoring analysis result, the dynamic monitoring module sends alarm information according to the monitoring analysis module, managers can adjust the alarm information through the adjusting module according to the alarm result, the cloud storage module stores a flood control emergency plan, and the adjusting module can directly transfer the flood control emergency plan from the cloud storage module to perform flood control measures.

Before the data acquisition module acquires data, the data acquisition module divides the data into sub-regions according to the range of a managed water storage region and the water flow direction, the sub-regions are marked as divided regions, each divided region is subjected to independent water storage capacity analysis, the data acquisition module analyzes generated data in the divided region, the data acquisition module can acquire data in the region and is marked as comprehensive data, the dynamic monitoring module acquires monitoring data when the real-time monitoring data is rainfall, the data acquisition module transmits the acquired comprehensive data to the cloud storage module, and when the data analysis module and the dynamic monitoring module perform analysis, the data acquisition module can be called from the cloud storage module.

When the system is used specifically, the system mainly comprises a data acquisition module, a cloud storage module, a data analysis module, a dynamic monitoring module, an alarm module and an adjustment module, wherein the data analysis module comprises a rainwater analysis module, a water storage analysis module and an environment analysis module, the data analysis module utilizes comprehensive data acquired by the data acquisition module to establish a data analysis model and analyze the data analysis model to obtain a data analysis result, the environment analysis module utilizes environment influence data and human activity data to analyze to obtain influence degree values of influence factors of environment and human on rainfall, and sends the influence degree values to the rainwater analysis module, the rainwater analysis module analyzes the rainfall in a divided area to obtain a rainwater analysis result, the rainwater analysis result reflects the influence of abnormal rainfall on the water storage capacity of the divided area when the rainwater analysis result is abnormal rainfall, and the water storage analysis module utilizes the rainwater analysis result and the comprehensive data to analyze to obtain a water storage analysis result, influence on precipitation by analyzing influence factors, a water storage analysis result is obtained by analyzing the safety degree of a water storage building, comprehensive analysis is carried out on the water storage capacity of a divided region, management of managers is facilitated, a dynamic monitoring module carries out dynamic monitoring analysis according to data analysis results and real-time monitoring data to obtain a monitoring analysis result, the monitoring analysis result is sent to an alarm module, the dynamic monitoring module is used for monitoring the precipitation in real time, safety problems can be found timely through the dynamic monitoring module, adjustment is made timely, emergency flood prevention measures are carried out by the managers through an adjustment module according to the alarm result, the dynamic monitoring module monitors the level of flood disasters in a specified region, and the monitoring on the precipitation and the water storage capacity in a region in hydraulic engineering is greatly improved.

While the invention has been described in further detail with reference to specific embodiments thereof, it is not intended that the invention be limited to the specific embodiments thereof; for those skilled in the art to which the present invention pertains and related technologies, the extension, operation method and data replacement should fall within the protection scope of the present invention based on the technical solution of the present invention.

Claims (5)

1. The utility model provides a hydraulic engineering safety management system, a serial communication port, including the data acquisition module, the cloud storage module, the data analysis module, dynamic monitoring module, the alarm module, the adjustment module, the data analysis module includes rainwater analysis module, retaining analysis module and environmental analysis module, the data analysis module utilizes the comprehensive data of data acquisition module collection to establish data analysis model and carry out the analysis and obtain the data analysis result, dynamic monitoring module carries out dynamic monitoring analysis according to data analysis result and real time monitoring data and obtains the monitoring analysis result, and send the monitoring analysis result to the alarm module, managers carries out urgent flood control measure through the adjustment module according to the alarm result, dynamic monitoring module monitors the progression of flood disasters takes place in the regulation region, the system management process is specifically as follows:

(1) the data acquisition module acquires comprehensive data of the divided regions and stores the comprehensive data in the cloud storage module, wherein the comprehensive data comprises environmental impact data, rainfall data, water storage building quality monitoring data and human activity data;

(2) the environment analysis module, the rainwater analysis module and the water storage analysis module analyze by utilizing the comprehensive data to obtain a data analysis result, and send the data analysis result to the dynamic monitoring module and the cloud storage module, the environment analysis module analyzes by utilizing the environment influence data and the human activity data to obtain the influence degree value of the influence factors of the environment and the human on the rainfall, and sends the influence degree value to the rainwater analysis module, the rainwater analysis module analyzes the rainfall in the divided area to obtain a rainwater analysis result, the water storage analysis module analyzes by utilizing the rainwater analysis result and the comprehensive data to obtain a water storage analysis result, and the specific analysis process is as follows:

step 1, the environment analysis module selects N time periods, which are marked as t_i(i ═ 1,2,3 … N), for a period of time t_iThe intensity of the corresponding temperature fluctuations is denoted w_iTime period t_iThe evaporation capacity of the corresponding water vapor is H_iThe environment analysis module extracts time periods t corresponding to M different sub-regions in the divided regions in the storage data of the cloud storage module_iInternal rainfall and is recorded as

Establishing a matrix A corresponding to rainfall in the divided areas as follows:

environmental analysis module using fluctuation intensity w of temperature_iWater vapor evaporation capacity H_iSolving the influence value of the environmental influence factor on the precipitation by the parameter value c of the environmental influence factor and the matrix A

The analytical equation is as follows:

wherein

Showing the influence value of the jth environmental influence factor, and respectively calculating the influence values of the environmental influence factors in the comprehensive data to obtain a set

Selecting K human activity data and L environmental influence factors in the divided region from the cloud storage module, and recording the parameter value corresponding to the human activity as p₁，p₂，p₃…p_KBy using

Value of parameter (p) within₁，p₂，p₃…p_K) Obtaining a parameter change rate matrix Δ P ═ Δ P₁，Δp₂，Δp₃...Δp_K) Using the parameter rate of change matrix Δ P and the set

The corresponding matrix calculates the influence degree value alpha of the environmental influence factors and the human activities on the precipitation, and sends the alpha to the rainwater analysis module, and the calculation equation is as follows:

step 2, the rainwater analysis module calculates error values between the predicted rainfall and the actual rainfall in different time periods, obtains a corresponding matrix B, analyzes the influence degree value alpha, the rainfall data and the matrix B by using a mathematical analysis model to obtain a rainwater analysis result, and sends the rainwater analysis result to the rainwater analysis module, wherein the rainwater analysis result comprises a water storage load value Y brought by the rainfall, and the concrete process is as follows:

wherein, V_iRepresents the average flow velocity u of a river in a divided region corresponding to the ith time period in rainfall data_i(t) represents river water flow over a period of time;

step 3, analyzing the buildings of rivers and reservoirs in the divided regions by a water storage analysis module, analyzing the water storage capacity in the whole divided region by combining water storage load values to obtain water storage data results, and dividing the water storage data results into different grades according to the total water storage capacity in the divided regions, wherein the data analysis results comprise rainwater analysis results, influence degree values and water storage analysis results;

(3) the dynamic monitoring module carries out real-time monitoring by utilizing a data analysis result and real-time monitoring data, the real-time monitoring data comprises monitoring data of rainfall, the dynamic monitoring module firstly carries out data analysis on the real-time monitoring data to obtain a real-time result, then calculates by utilizing a water storage analysis result to obtain a water storage threshold value, finally compares the real-time result with the value of the water storage threshold value, and when the set water storage threshold value is exceeded, the dynamic monitoring module sends a monitoring analysis result to the alarm module.

2. The hydraulic engineering safety management system according to claim 1, wherein the dynamic monitoring module performs real-time monitoring by using the data analysis result and the real-time monitoring data to obtain a monitoring analysis result, and the specific analysis process is as follows:

step one, including intersection water flow Q in real-time monitoring data_rkDomestic water consumption Q_roWater storage capacity Q of water storage building in divided region_rgWater flow at junction Q_kAbsolute values of the amounts of water including inflow and outflow of water;

step two, establishing a decision objective function according to all real-time monitoring data in the divided region, sequencing all buildings with water storage in the divided region, and analyzing, wherein the specific equation is as follows:

Q_rg＝c₃U_rkG_r，

wherein ξ_r、c₁、c₂、c₃All are normal numbers, represent the water inlet coefficient of the intersection and the water storage building, and utilize Q_rk、Q_ro、Q_rgEstablishing a three-dimensional analysis model for data simulation analysis to obtain a water storage risk pressure value;

and 4, comparing the water storage risk pressure value with a water storage threshold value by the dynamic management module, wherein the water storage threshold value is obtained by analyzing according to a water storage analysis result, establishing a target decision function according to a data analysis result, and making a strategy according to the target decision analysis result.

3. The hydraulic engineering safety management system according to claim 1, wherein the water storage analysis module analyzes a building storing water, analyzes water storage capacity of the building storing water and data of the building itself to obtain a water storage analysis result in the whole divided area, analyzes decay of the data of the building itself including building construction data, building detection data and building pressure bearing data, analyzes correspondence between water storage capacity and building aging degree.

4. The hydraulic engineering safety management system according to claim 1, wherein the dynamic monitoring module analyzes real-time monitoring data during rainfall to obtain a monitoring analysis result, the dynamic monitoring module sends alarm information according to the monitoring analysis module, a manager can adjust the dynamic monitoring module according to the alarm result through an adjusting module, a flood control emergency plan is stored in the cloud storage module, and the adjusting module can directly fetch the flood control emergency plan from the cloud storage module to perform flood control measures.

5. The hydraulic engineering safety management system according to claim 1, wherein before the data acquisition module acquires data, the data acquisition module divides the data into sub-regions according to the range and the water flow direction of the managed water storage region, the sub-regions are divided into divided regions, each divided region is subjected to individual water storage capacity analysis, the data acquisition module analyzes the data generated in the divided region, the data acquisition module can acquire the data in the region and record the data as integrated data, the dynamic monitoring module acquires real-time monitoring data which is monitoring data during rainfall, the data acquisition module transmits the acquired integrated data to the cloud storage module, and when the data analysis module and the dynamic monitoring module perform analysis, the data acquisition module can retrieve the data from the cloud storage module.

Images