Table of Contents
Principles of Conductivity Measurement in Analyzers
Conductivity analyzers are essential tools used in various industries to measure the electrical conductivity of a solution. This measurement provides valuable information about the concentration of ions present in the solution, which can be used to monitor and control processes in industries such as water treatment, chemical manufacturing, and pharmaceutical production. Understanding how conductivity analyzers work is crucial for ensuring accurate and reliable measurements.
At the heart of a conductivity analyzer is a conductivity cell, which consists of two electrodes separated by a small gap filled with the solution to be measured. When an alternating current is applied to the electrodes, ions in the solution move towards the electrodes, creating an electrical current. The conductivity of the solution is directly proportional to the electrical current generated, allowing the analyzer to calculate the conductivity of the solution.
To ensure accurate measurements, conductivity analyzers are equipped with temperature compensation mechanisms. The conductivity of a solution is highly dependent on temperature, as the mobility of ions increases with temperature. By measuring the temperature of the solution and adjusting the conductivity measurement accordingly, temperature compensation ensures that the analyzer provides accurate readings regardless of variations in temperature.
In addition to temperature compensation, conductivity analyzers may also be equipped with automatic calibration features to maintain accuracy over time. Calibration involves comparing the analyzer’s readings to known standards and adjusting the calibration settings as needed. Automatic calibration simplifies this process by periodically calibrating the analyzer without the need for manual intervention, ensuring that the measurements remain accurate and reliable.
Another important feature of conductivity analyzers is the ability to measure a wide range of conductivity values. Different solutions may have vastly different conductivity Levels, ranging from highly conductive solutions such as acids and salts to low-conductivity solutions such as pure water. Analyzers must be able to accurately measure this wide range of conductivity values to provide meaningful data for process control and monitoring.
To further enhance the accuracy of conductivity measurements, analyzers may also be equipped with multiple measurement Ranges and adjustable sensitivity settings. This allows the analyzer to adapt to different types of solutions and provide precise measurements even in challenging conditions. By selecting the appropriate measurement range and sensitivity settings, operators can ensure that the analyzer delivers accurate results for a wide range of applications.
In conclusion, conductivity analyzers play a crucial role in monitoring and controlling processes in various industries by providing accurate measurements of the electrical conductivity of solutions. By understanding how conductivity analyzers work and the principles behind conductivity measurement, operators can ensure that their analyzers deliver reliable and consistent results. Features such as temperature compensation, automatic calibration, and adjustable sensitivity settings further enhance the accuracy and versatility of conductivity analyzers, making them indispensable tools for quality control and process optimization.
Understanding the Technology Behind Conductivity Analyzers
Conductivity analyzers are essential tools used in various industries to measure the electrical conductivity of a solution. This measurement provides valuable information about the concentration of ions present in the solution, which can be used to monitor and control processes in industries such as water treatment, chemical manufacturing, and pharmaceutical production. Understanding how conductivity analyzers work is crucial for ensuring accurate and reliable measurements.
At the heart of a conductivity analyzer is a pair of electrodes that are immersed in the solution being tested. These electrodes are typically made of a conductive material such as Stainless Steel or graphite. When an electric current is applied to the electrodes, ions in the solution carry the current, allowing it to flow between the electrodes. The conductivity of the solution is directly proportional to the number of ions present, as well as their mobility.
To measure conductivity, the analyzer applies a known voltage across the electrodes and measures the resulting current. The conductivity of the solution is then calculated using Ohm’s Law, which states that the current flowing through a conductor is equal to the voltage divided by the resistance. In the case of a conductivity analyzer, the resistance is a function of the distance between the electrodes, the surface area of the electrodes, and the conductivity of the solution.
| Model | CIT-8800 Inductive Conductivity/Concentration Oline Controller |
| Concentration | 1.NaOH:(0~15)% or(25~50)%; 2.HNO3:(0~25)% or(36~82)%; 3.User-defined concentration curves |
| Conductivity | (500~2,000,000)uS/cm |
| TDS | (250~1,000,000)ppm |
| Temp. | (0~120)\\\\\\\\\\\\\\\\u00b0C |
| Resolution | Conductivity: 0.01uS/cm; Concentration: 0.01%; TDS:0.01ppm, Temp.: 0.1\\\\\\\\\\\\\\\\u2103 |
| Accuracy | Conductivity: (500~1000)uS/cm +/-10uS/cm; (1~2000)mS/cm+/-1.0% |
| TDS: 1.5 level, Temp.: +/-0.5\\\\\\\\\\\\\\\\u2103 | |
| Temp. compensation | Range: (0~120)\\\\\\\\\\\\\\\\u00b0C; element: Pt1000 |
| Communication port | RS485.Modbus RTU protocol |
| Analog output | Two channels isolated/ transportable (4-20)mA, Instrument / Transmitter for selection |
| Control Output | Triple channels semiconductor photoelectric switch, Programmable Switch, pulse and frequency |
| Working Environment | Temp.(0~50)\\\\\\\\\\\\\\\\u2103; relative humidity <95%RH (non-condensing) |
| Storage Environment | Temp.(-20~60)\\\\\\\\\\\\\\\\u2103;Relative Humidity \\\\\\\\\\\\\\\\u226485%RH (none condensation) |
| Power Supply | DC 24V+15% |
| Protection Level | IP65 (with rear cover) |
| Dimension | 96mmx96mmx94mm(HxWxD) |
| Hole Size | 9lmmx91mm(HxW) |
One of the key components of a conductivity analyzer is the conductivity cell, which houses the electrodes and allows for the measurement of conductivity. The design of the conductivity cell can vary depending on the application, with options such as flow-through cells, dip cells, and submersion cells available. Flow-through cells are commonly used in continuous monitoring applications, while dip cells are used for spot measurements in open tanks or vessels.
In addition to the conductivity cell, conductivity analyzers also include a measurement circuit that processes the signals from the electrodes and calculates the conductivity of the solution. This circuit typically includes a signal conditioner, which amplifies and Filters the signals from the electrodes, as well as a microprocessor that performs the necessary calculations. The analyzer may also include a display unit that shows the conductivity reading in real-time.
To ensure accurate measurements, conductivity analyzers must be calibrated regularly using standard solutions with known conductivity values. This calibration process allows the analyzer to account for any variations in the electrodes or measurement circuit, ensuring that the readings are accurate and reliable. In addition to calibration, conductivity analyzers may also require regular maintenance to clean the electrodes and ensure proper functioning.
Overall, conductivity analyzers play a crucial role in monitoring and controlling processes in various industries by providing real-time measurements of conductivity. By understanding how conductivity analyzers work and the technology behind them, operators can ensure that their processes run smoothly and efficiently. With advancements in technology, conductivity analyzers continue to evolve, offering improved accuracy, reliability, and ease of use for a wide range of applications.
