18512692. WATER QUALITY DETECTION SYSTEM simplified abstract (Huawei Technologies Co., Ltd.)
Contents
WATER QUALITY DETECTION SYSTEM
Organization Name
Inventor(s)
WATER QUALITY DETECTION SYSTEM - A simplified explanation of the abstract
This abstract first appeared for US patent application 18512692 titled 'WATER QUALITY DETECTION SYSTEM
Simplified Explanation
The abstract describes a water quality detection system that uses a light source, a spectrometer, and a data processor to analyze fluorescence from a water sample.
- Light source emits excitation light pulse trains of different wavelengths to the water sample.
- Spectrometer receives the fluorescence and outputs a fluorescence spectrum.
- Data processor analyzes the fluorescence spectrum to obtain a three-dimensional fluorescence spectrum, identifying the water sample and obtaining parameters based on it.
Potential Applications
This technology can be used in environmental monitoring, water treatment facilities, and research laboratories to quickly and accurately assess water quality.
Problems Solved
This system solves the problem of time-consuming and labor-intensive water quality testing by providing a fast and efficient method for analyzing water samples.
Benefits
The benefits of this technology include real-time monitoring, accurate detection of contaminants, and the ability to quickly identify and address water quality issues.
Potential Commercial Applications
Water Quality Monitoring System for Environmental Agencies and Water Treatment Plants - Optimizing water quality testing processes for efficient and reliable monitoring.
Original Abstract Submitted
A water quality detection system including a light source, a spectrometer, and a data processor is disclosed, and relates to the technical field of detection systems. The light source emits excitation light pulse trains of different wavelengths to a to-be-detected water sample contained in a sample cell, where the excitation light pulse trains of different wavelengths may be emitted in a time-division manner, to excite the to-be-detected water sample, thereby generating fluorescence separately corresponding to the excitation light pulse trains of different wavelengths. The spectrometer receives the fluorescence and output a fluorescence spectrum based on the fluorescence. The data processor obtains, based on the fluorescence spectrum output by the spectrometer, a three-dimensional fluorescence spectrum including an excitation wavelength, a fluorescence wavelength, and a fluorescence intensity, identifies the to-be-detected water sample and obtains a parameter of the to-be-detected water sample based on the three-dimensional fluorescence spectrum.
