We can offer two kinds technologies CH4 gas analyzer From % to ppb CH4 gas measurement
☑ Infrared (IR) technology methane gas analyzer special designed for direct measurement of methane in syngas and natural gas measurement applications.
☑ The tunable diode laser for CH4 measurement is an innovative technology specially designed for medical applications and atmospheric environment trace pollution gas monitoring.
It provides highly accurate and reliable trace CH4 gas measurements with minimal detection limits of 5ppb . This advanced technology allows healthcare professionals to detect extremely low concentrations of methane in patient samples, ensuring the highest levels of accuracy and safety.
Parameters | Data |
Gas | CH4 |
Principle | TDLAS |
Range | 0-5000ppb |
Accuracy | ≤±0.3%FS |
Repeatablility | ≤0.2% FS |
Min Detection Limt | ≤5ppb |
72h Zero Drift | ≤±0.5%FS |
72h Span Drift | ≤±1.0%FS |
(T90) | ≤60s |
Interval Time | 1s |
Why need methane CH4 gas analyzer ?
Methane is the main component of natural gas, biogas. commonly known as gas. It can be used as a fuel and a raw material for the production of hydrogen, carbon black, carbon monoxide, acetylene, hydrocyanic acid and formaldehyde.
Methane is a potent greenhouse gas that can persist in the atmosphere. It is also important to reduce methane emissions and monitor its levels in the atmosphere.
Methane gas (CH4) is the second-most prevalent greenhouse gas in the atmosphere and contributes significantly to climate change. It has a much higher global warming potential than carbon dioxide, with 25 times more long-term impacts on average. As such, it is essential that we measure and monitor methane levels in order to effectively combat climate change. Monitoring methane levels can help us identify sources of emissions and develop strategies to reduce them, thus helping to mitigate the effects of climate change. Additionally, measuring methane concentrations in the atmosphere provides an important indicator of ecosystem health and can inform policy decisions on land use management approaches. By understanding atmospheric trends, we will be able to better protect our environment and ensure a more sustainable future. Measuring methane gas is therefore an important step in protecting our planet and staying ahead of the climate change challenge.
A methane (CH4) gas analyzer is a device used to measure and analyze the concentration of methane gas in a sample or environment. Methane is a potent greenhouse gas and the primary component of natural gas. It is released into the atmosphere through various natural and human activities, including the production and transport of coal, oil, and natural gas, agriculture (livestock and rice cultivation), and the decomposition of organic waste in landfills.
The importance of methane gas analyzers can be summarized as follows:
Climate Change Mitigation: Methane is a powerful greenhouse gas, with a much higher global warming potential than carbon dioxide (CO2) over shorter timeframes. Monitoring and accurately measuring methane concentrations are crucial for assessing its impact on climate change and developing effective mitigation strategies. Methane gas analyzers provide data that helps scientists, policymakers, and environmental agencies understand the sources, trends, and distribution of methane emissions.
Emissions Monitoring: Industries involved in the extraction, processing, and distribution of natural gas, as well as other sectors such as agriculture and waste management, need to monitor and manage their methane emissions. Methane gas analyzers enable real-time monitoring of methane concentrations at various emission sources, helping industries assess their environmental impact, identify leakage points, and implement measures to reduce emissions.
Energy Efficiency: In the energy sector, methane gas analyzers are used to assess the efficiency of combustion processes and ensure optimal operation of equipment such as boilers, furnaces, and gas turbines. By measuring methane concentrations in exhaust gases, analyzers help identify inefficiencies and combustion problems, allowing for adjustments to be made to improve energy efficiency and reduce methane emissions.
Safety and Occupational Health: Methane is highly combustible and poses safety risks in various industrial settings, including mines, oil and gas facilities, and confined spaces. Methane gas analyzers are utilized for monitoring methane levels in these environments to ensure worker safety. If methane concentrations exceed safe thresholds, alarms can be triggered to alert workers and prompt appropriate safety measures.
Landfill Management: In landfill operations, methane is produced during the decomposition of organic waste. Monitoring methane emissions from landfills is crucial to comply with regulations, assess the efficiency of gas collection systems, and evaluate the need for additional control measures. Methane gas analyzers aid in monitoring and managing methane emissions from landfills, enabling operators to optimize gas collection systems and reduce methane release into the atmosphere.
Methane gas analyzers employ various measurement techniques, including infrared absorption spectroscopy, flame ionization detection, and laser-based spectroscopy, to detect and quantify methane concentrations accurately. These analyzers play a vital role in understanding and addressing methane emissions, mitigating climate change, and promoting sustainable practices in various industries and sectors.
Parameters | Data |
Gas | CH4 |
Principle | TDLAS |
Range | 0-5000ppb |
Accuracy | ≤±0.3%FS |
Repeatablility | ≤0.2% FS |
Min Detection Limt | ≤5ppb |
72h Zero Drift | ≤±0.5%FS |
72h Span Drift | ≤±1.0%FS |
(T90) | ≤60s |
Interval Time | 1s |
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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