Water source monitoring and protection
By building a comprehensive monitoring network for the river basin, integrating monitoring data from various aspects such as water quality, water volume, meteorology, and soil, we can comprehensively grasp the dynamic changes of various elements of the water source ecosystem, and then formulate systematic protection strategies to achieve all-round and full-process protection and management of the water source area.
Build a three-dimensional assessment model of "water quality-ecology-risk" and integrate physical and chemical indicators, biodiversity and surrounding risk source data
Hydrodynamic models simulate the 72-hour pollution diffusion trajectory and automatically generate heat maps and disposal plans
Dynamically display key indicators (such as ammonia nitrogen and total phosphorus concentrations) and over-standard alarms (red/orange/yellow three-level warning). Automatically generate daily/weekly newspapers and compare historical data with national standards.
Establish a pollution diffusion model, generate a heat map to assist decision-making, AI algorithms identify abnormal data patterns (such as sudden changes in equipment parameters, excessive water quality), and automatically grade early warning (yellow/orange/red)
Record the discharge permits of enterprises in the protected area, the operating status of pollution control facilities, and law enforcement records (such as online monitoring data of wastewater treatment equipment of a chemical plant).
UAVs automatically patrol route planning, AI identifies garbage dumping, illegal fishing and other behaviors, and generates law enforcement clues.
Combine pollutant fingerprint databases (such as heavy metal profiles) and hydrometeorological data to lock the location of pollution sources (error ≤50 meters).
The random forest algorithm analyzes the flow direction of pollutants and superimposes corporate pollution ledger data to match suspected sources.
Linkage emergency resources (activated carbon release equipment, interception dam location) are dispatched with one click.
A comprehensive evaluation system is built based on biodiversity (benthos, fish populations), vegetation coverage (NDVI index), and water quality indicators.
Generate a "five-color map" of ecological health (red-yellow-green-blue-purple represents degradation to excellent levels).
It can comprehensively understand the ecological status and restoration effect of the water source area and provide scientific basis for subsequent water source area protection and management.
Build a three-dimensional virtual model of the water source area to map the state of the physical world in real time (such as water level changes and pollution spread paths).
Simulate the effects of Incident Response Service under different scenarios (such as heavy rain peaks and chemical leaks).
The LSTM model predicts water quality changes over the next 72 hours.
AI analysis satellite images identify illegal construction and illegal breeding in the protected area.
The online water quality monitoring system uses advanced sensors and measuring instruments, which can accurately measure various water quality parameters and ensure the accuracy and reliability of monitoring data.
Sensing technology has the advantage of large-area simultaneous observation and can obtain large-area water source information in a short time without being limited by geographical conditions.
It can simultaneously measure multiple basic water quality parameters such as pH value, dissolved oxygen, conductivity, temperature, and turbidity, making it easy to quickly understand the overall water quality of the water source.
It is used to detect the content of heavy metal elements such as lead, mercury, cadmium, and chromium in water. Atomic absorption spectrometers, atomic fluorescence spectrometers, etc. can achieve high-precision detection of heavy metals.
Gas chromatographs and liquid chromatographs can conduct qualitative and quantitative analysis of organic pollutants such as pesticide residues, polycyclic aromatic hydrocarbons, and volatile organic compounds in water.
Commonly used are pressure water level gauges, ultrasonic water level gauges, float water level gauges, etc., which can monitor water level changes in water sources in real time and provide data support for water volume assessment and scheduling.
Electromagnetic flowmeters, ultrasonic flowmeters, etc. can be installed on water intakes or water pipelines to accurately measure the water intake and water flow speed of the water source.
It is used to monitor meteorological parameters around the water source area and provide reference for water quality change analysis and water volume prediction.
It is used to monitor the moisture content of the soil around the water source area and understand the changes in soil moisture. It is of great significance for assessing the ecological environment and vegetation growth status of the water source area.
Equipped with high-definition cameras, multi-spectral sensors and other equipment, it can conduct large-scale and high-resolution inspections and monitoring of water sources, promptly discover illegal sewage discharge, illegal construction and other problems, and monitor vegetation coverage, land use changes, etc.
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