What kinds of O2 gas analyzer we can provide ?
Our oxygen analyzers come in a variety of models and technologies. We can supply electrochemical-based oxygen analyzers that are suitable for intermittent or continuous measurements, featuring high accuracy, fast response times, low power consumption and a long life span. For applications that require higher accuracy and stability readings over wide ranges of temperature and pressure, we offer paramagnetic-based oxygen analyzers. Zirconia oxygen analyzers are ideal for applications that require accurate and reliable measurements over long periods of time in extreme temperature environments, while tunable diode laser absorption spectroscopy (TDLAS) is an emerging technology which has the advantage of being highly selective to a single target gas. No matter your application, we have the right oxygen analyzer to suit your needs.
☑ Zirconia Oxgen analyzer
☑ ECD Oxgen gas analyzer
☑ Paramagnetic analyzer
☑ TDL Oxgen gas analyzer
What is an Oxygen Analyzer Applications ?
An oxygen analyzer is an instrument used to measure the concentration of oxygen in gas or liquid samples. Oxygen analyzers are essential for a variety of applications
☑ Monitoring the health and safety
☑ Controlling production processes
☑ Environmental applications.
☑ ECD O2 gas analyzer
An electrochemical gas analyzer is a device used to accurately detect the concentration of gases in the air. It works on the basic principle of an electrochemical reaction, where electrons are exchanged between two substances and ions are produced as a result. This process is known as oxidation-reduction (or redox) reaction. The gas analyzer measures the electrical current generated from the reaction and converts it into a concentration value.The main advantages of electrochemical gas analyzers are their small size, fast detection speed, and direct and continuous on-site monitoring capabilities. This makes them ideal for applications such as industrial process control, environmental monitoring, and safety systems.
☑ Zirconia analyzer
Generally used for flue emission or combustion control, the sampling probe can withstand high temperature and corrosion, and the installation method is direct insertion or extraction. It has the characteristics of simple structure, good stability, high sensitivity, fast etc response. The output signal is convenient for signal transmission and processing, and the accuracy is relatively high. Disadvantages:The measurement is easily affected by temperature, and the measurement gas is single
☑ Paramagnetic analyzer
Advantages: fast response, high measurement accuracy, often used for precise process control. Disadvantages: Paramagnetic oxygen has high requirements on the instrument environment and cannot be subjected to vibration. In harsh working conditions, a pretreatment device must be installed. Application technology: process control,
☑ TDL O2 gas analyzer
The Laser O2 gas analyzer is a powerful tool for measuring the amount of oxygen in the air. It offers fast response and high accuracy, ensuring that users get reliable readings quickly and accurately. Additionally, this device requires minimal maintenance, making it an ideal choice for those who need consistent results with minimal effort.
Measuring carbon dioxide (CO2) is important for understanding the role it plays in the environment and its effect on climate change. CO2 is a major component of Earth’s atmosphere, and it traps heat like a blanket, causing global temperatures to rise. Too m uch CO2 can lead to drastic changes in our weather patterns and ecosystems, so monitoring its levels is essential for predicting future climate conditions. Additionally, measuring CO2 can help us better understand our impact on the environment and make informed decisions about how to reduce emissions and slow down down down down down global warming. By analyzing CO2 data over time, we can develop strategies to mitigate the effects of climate change and ensure a sustainable future.
Before industrialization, the global average annual atmospheric carbon dioxide concentration was 278ppm (1ppm is one part per million). In 2012, the global annual average atmospheric carbon dioxide concentration was 393.1ppm. By April 2014 , the monthly average carbon dioxide concentration in the northern hemisphere atmosphere exceeded 400ppm for the first time. . 2. Global climate warming, the continuous aggravation of the atmospheric greenhouse effect leads to global climate warming, resulting in a series of global climate problems that cannot be predicted by today’s science. According to the International Climate Change Economics Report, if human beings maintain the current way of life, by 2100, there will be a 50% chance that the global average temperature will rise by 4°C.
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