Trace gas analysis TDLAS technology ppb to ppm measurement Online 19"4U type
Certainly! Here are some additional details on trace gas analysis:
1. Importance of Trace Gas Analysis: Trace gases, even at low concentrations, can have significant impacts on the environment, human health, and industrial processes. They can contribute to air pollution, climate change, and the formation of smog. Trace gas analysis helps researchers and scientists understand the sources, transport, and chemical reactions of these gases, enabling better environmental management, policy-making, and mitigation strategies.
2. Environmental Monitoring: Trace gas analysis is crucial for monitoring and assessing air quality and the impact of pollutants on ecosystems. It helps identify and quantify harmful gases such as nitrogen oxides (NOx), sulfur dioxide (SO2), volatile organic compounds (VOCs), ozone (O3), and particulate matter. By monitoring trace gases, it is possible to evaluate the effectiveness of emission control measures, track pollutant sources, and study the formation of secondary pollutants.
3. Atmospheric Research: Trace gas analysis plays a vital role in atmospheric research and climate studies. Scientists measure and monitor greenhouse gases like carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O), and ozone-depleting substances to understand their concentrations, sources, and the impact on global climate change. This information helps in climate modeling, predicting future climate scenarios, and formulating policies for greenhouse gas reduction.
4. Industrial Processes: Trace gas analysis is utilized in various industrial sectors to ensure compliance with environmental regulations, optimize processes, and improve workplace safety. For instance, in the petrochemical industry, trace gas analysis helps monitor volatile hydrocarbons, sulfur compounds, and other toxic gases emitted during production processes. In the semiconductor industry, trace gas analysis is critical for maintaining cleanrooms and detecting contaminants that could impact the manufacturing process.
5. Instrumentation Advances: Advances in technology have led to the development of more sensitive, selective, and portable trace gas analyzers. Miniaturized gas sensors, microelectromechanical systems (MEMS), and nanotechnology-based sensors have enabled real-time and in-situ measurements of trace gases. Additionally, techniques like cavity-enhanced absorption spectroscopy (CEAS) and quantum cascade lasers (QCL) have improved the detection limits and accuracy of trace gas analysis.
6. Trace Gas Flux Measurements: In addition to concentration measurements, trace gas analysis can be used to estimate the flux or exchange rates of gases between different ecosystems, such as soil-atmosphere or water-atmosphere interfaces. Flux measurements provide insights into biogeochemical cycles, greenhouse gas emissions from natural and anthropogenic sources, and the effectiveness of carbon sequestration strategies.
7. Remote Sensing: Remote sensing techniques, such as satellite-based instruments and ground-based lidar systems, are used for large-scale trace gas monitoring. These techniques provide spatial and temporal information on trace gas distributions, enabling the assessment of regional and global trends, pollutant transport, and the identification of pollution hotspots.
Overall, trace gas analysis is a multidisciplinary field that combines techniques from chemistry, physics, environmental science, and engineering. It continues to advance our understanding of the composition of the atmosphere, the impact of trace gases on the environment and human health, and guides efforts to mitigate pollution and climate change.
Trace gas analyzer TDLAS technology ESE-LASER-U500 model based on the principle of tunable semiconductor laser absorption spectroscopy (TDLAS), laser gas analyzer scans and analyzes the gas absorption lines of specific wavelength, and realizes the gas concentration measurement by combining the digital lock-in amplifier and the advanced technology of long optical path. laser gas analyzer can realize high resolution, high precision, stable and reliable measurement of trace gases, and meet the requirements of process analysis and environmental monitoring.
Features
☑ ppb ultra high sensitivity Spectrum single line scanning, precise lock test wavelength
☑ Automatic compensation of atmospheric temperature, pressure and humidity
| Performance parameters |
| Gas |
Range |
Resolution |
Repeatability |
Linearity |
Drift |
| NH3 |
0-2000ppb |
2ppb |
≤2%FS |
≤2%FS |
≤ ±2%FS |
| CH4 |
0-5000ppb |
5ppb |
≤0.2%FS |
≤1%FS |
≤ ±0.5%FS |
| CO |
0-50ppb |
0.02ppm |
≤2%FS |
≤2%FS |
≤ ±2%FS |
| CO2 |
0-500ppm |
1ppm |
≤1%FS |
≤1%FS |
≤ ±1%FS |
| HCL/HF |
0-2000ppb |
1ppb |
≤2%FS |
≤2%FS |
≤ ±2%FS |
| |
| Warm up time |
30mins |
Digital output |
RS232/485 |
Analog output |
|
| Power supply |
AC100-240V/47-63Hz
120W
|
Relay output |
Load capacity: AC/DC 24V/1A; concentration overrun alarm, transmittance and laser temperature abnormal alarm (customized) |
| Environmental parameters |
| Optical path |
Above 30 meters |
Gas temperature |
<=60℃ |
Gas Pressure |
|
| Sampling flow rate |
1L/min |
Environmental temp |
-10~55℃ |
Environmental pressure |
|
| Size |
5U |
Weight |
10kgs |
Applications
☑ Trace gas measurement
☑ Greenhouse gas measurement
☑ Measurement of gas emission plume diagram
☑ Air quality monitoring
