High Precision And Stability RS485 Lazer Water Tubidity Electrode For Treated Water

High Precision and Stability RS485 lazer Water Tubidity electrode for treated water​

 
Daruifuno's laser flow-through low turbidity sensor OLTU601 with display screen is a sensor with an integrated display screen. It uses laser flow-through technology to measure turbidity or the concentration of suspended particles in liquids, and can directly display the measurement results. OLTU601 sensors typically include a built-in display that displays measurement values, units, and other relevant information, allowing users to obtain measurement results directly without the need for additional equipment or steps.

The working principle of the laser flow-through low turbidity sensor OLTU601 is based on the principle of laser light source and light scattering. The sensor illuminates a liquid sample with a laser light source, and when suspended particles or particles are present, they scatter the laser beam. A light receiver built into the sensor receives and detects scattered light, the intensity of which is proportional to the concentration of suspended particles in the liquid.

The laser flow-through low turbidity sensor OLTU601 has higher sensitivity and accuracy than traditional turbidity sensors. Due to the characteristics of the laser beam, this sensor can make accurate measurements at much lower turbidity levels. At the same time, the built-in display screen makes the measurement results intuitive and convenient for operation and data collection.

Technical Parameters

User manual of OLTU60:

OLTU600 Low turbidity sensor user manual.pdf

Features

• The flow turbidity sensor shoots the 660nm laser vertically downwards into the water. The light is scattered by suspended particles in the water sample, and the scattered light at 90°with the incident angle is received by the silicon photocell receiver immersed in the water sample, and 90° is calculated.

• Compact miniaturized design, small installation space
• 660nm laser light source with high resolution and fast response
• Optional viewing window and automatic emptying system reduce maintenance effort
• Low injection flow requirements, reducing the amount of waste generated in the measurement
• Internal storage of calibration data, support offline calibration, on-site plug and play
• Flow cell type turbidity probe

Advantage

• Digital low turbidity sensors offer numerous advantages, including:

  High Precision and Stability: Digital low turbidity sensors utilize digital technology for measurement and data processing, ensuring higher precision and stability, thus providing accurate measurement results.

• Real-time Monitoring and Data Logging: Digital sensors can monitor turbidity levels in real-time and log data for subsequent analysis and processing. This capability is crucial for timely detection of changes and real-time control.

• Flexibility and Programmability: Digital sensors typically offer programmability, allowing customization according to specific application needs for different measurement ranges, sensitivity levels, and sampling frequencies.

• Strong Interference Resistance: Digital sensors often exhibit strong resistance to interference, maintaining stable performance in complex environmental conditions and reducing the impact of external interference on measurement results.

• Ease of Integration and Use: Digital sensors usually feature standardized interfaces and communication protocols, facilitating integration with other devices and systems. Moreover, they often come with user-friendly interfaces for easy installation and operation.

• Cost and Resource Savings: Digital sensors typically have lower maintenance costs and longer lifespans. Additionally, they can reduce downtime through remote monitoring and fault diagnosis, thus saving costs and resources.

• In summary, digital low turbidity sensors offer significant advantages in precision, stability, real-time capabilities, flexibility, and cost-effectiveness, making them suitable for various applications requiring measurement and monitoring of turbidity levels.

Low turbidity sensors are often used in environments where high sensitivity and accuracy are required. Some of these applications include:

• Drinking Water and Wastewater Treatment: In drinking water and wastewater treatment plants, low turbidity sensors are used to monitor the concentration of suspended particles and contaminants in water to ensure that water quality meets relevant standards.
• Pharmaceutical industry: In the pharmaceutical process, low turbidity sensors are used to monitor tiny particles and impurities in pharmaceutical solutions or injections to ensure product quality and purity.
• Winemaking industry: In the winemaking process, low turbidity sensors are used to monitor the concentration of microorganisms and suspended particles in the fermentation broth to ensure the quality and stability of wine products.
• Food Processing: During food processing, low turbidity sensors are used to monitor the concentration of suspended particles and impurities in food to ensure food safety and quality.
• Semiconductor Manufacturing: In the semiconductor manufacturing process, low turbidity sensors are used to monitor tiny particles and impurities in ultrapure water and chemical solutions to ensure the accuracy and stability of the chip manufacturing process.
• Biomedical Research: In biomedical research, low turbidity sensors are used to monitor the concentration and purity of cells, proteins, and other biomolecules in biological samples to support scientific experiments and diagnostic applications.