Development of inhaled portable methane detector based on TDLAS technique

Abstract

Abstract: In order to meet the requirement for detecting the methane（CH4） leakage in the daily maintenance of the network of gas pipelines in cities, an inhaled portable CH4 detector based on tunable diode laser absorption spectroscopy(TDLAS) technique has been developed, whose weight is only 1.4 kg and volume is 22 cm ? 10 cm ? 10 cm. The instrument uses a distributed feedback laser whose central wavelength is 1654 nm as the light source as well as integrating an optical multi-pass cell whose physical basic length is 8.5 cm and effective optical path is 2.25 m. The system based on STM32F405 generates a stable modulation laser by controlling laser, and acquires the absorption signal by the signal acquisition and process unit, then a digital lock-in amplifier is used to extract the second harmonic component in the signal to get the concentration of gas. Calibration and stability tests of the detector are carried out. Results show that there is a good linear relationship between the amplitudes of second harmonic signal and gas concentrations. The measurement accuracy of system is ±3.05% and the minimum detectable limit is 0.88 ppm. The precision and portability of the instrument meet the requirements of actual measurement.

Key words: spectroscopy, tunable diode laser, absorption spectroscopy, methane

LIU Jie1,2, DONG Yang1,2, GU Mingsi1,2, CHEN Jiajin1, TAN Tu1, GAO Xiaoming1. Development of inhaled portable methane detector based on TDLAS technique[J]. Chinese Journal of Quantum Electronics.

References

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