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Research on the Radiation Characteristics of Low-Carbon Chemical Flame Infrared Spectrum |
LIU Li-xi, CHEN Lin, CHEN Zhi-li*, TANG Jin, PENG Wu-di, HU Tian-you, WANG Hao-wen |
Environmental Science and Engineering, College of Guilin University of Technology, Guilin 541004, China |
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Abstract Low-carbon chemical fire accidents have a high risk and great harm. Exploring the flame spectrum characteristics of low-carbon chemicals is of great significance in detecting and identifying such fire hazards and pollution. However, domestic and foreign large-scale low-carbon chemical fire accidents produce toxic and harmful sulfur Research on SOX and NOX gases is rare. In this paper, by building an experimental platform for flame spectrum testing in the 1.2~12 μm infrared band, the flame spectrum test of carbon disulfide, 92# gasoline and alcohol at three different combustion scales of 5, 14 and 20 cm is carried out to explore the effect of flame combustion scale on high-temperature flame molecular radiation The influence of the spectrum. As the combustion scale increases, the flame radiation intensity increases, and the characteristic waveband appears to broaden. Analyze the different flame spectrum characteristics of liquefied natural gas (LNG), acrylonitrile, acetonitrile and 95# gasoline in the four typical chemicals at the 5 cm combustion scale. Using Fourier transform infrared spectrometer to measure the different temperatures of the high-temperature blackbody furnace, the flame spectrum signal is radiated calibration, and the accurate radiant calibration coefficient is obtained, thereby obtaining the radiance value emitted by the high-temperature flame molecules. Moreover, compared with the HITRAN database simulated atmospheric pressure 1 atm, temperature 1 300 K single SO2, H2O, CO2, NO2 molecular radiation spectrum for comparative analysis. Among them, the high temperature flame molecular spectrum mainly has 7.3~7.6, 8.7 and 4.0 μm SO2 bands, 1.8~2.1 and 6.4 μm H2O bands, 4.2~4.6 μm CO2 bands, and 2.5~2.9 μm H2O and CO2 common bands. The high temperature NO2 gas did not reach the detection limit of the infrared spectrometer, and the 6.0~6.4, 3.4 and 2.4 μm NO2 bands can be known through the HITRAN database simulation. In order to further distinguish the flame spectra of various chemicals, the calibrated flame spectrum signal is normalized, and the db2 wavelet basis function is used for 6-layer decomposition to obtain the approximate coefficients of the high frequency part and the detail coefficients of the low-frequency part, by comparing different chemistry, the approximation and detail coefficient difference of the high-temperature flame spectrum. The results show that the flame spectrum characteristics of carbon disulfide and the chemical flame spectrum characteristics of wavelet analysis can be used as an important basis for distinguishing low-carbon chemicals from oils and for subsequent remote sensing detection of low-carbon chemical characteristic pollutants, component concentration inversion and identification evaluation Its pollution hazards lay an important foundation.
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Received: 2020-12-25
Accepted: 2021-03-16
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Corresponding Authors:
CHEN Zhi-li
E-mail: zhilichen518@foxmail.com
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