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Sensors (Basel, Switzerland)
Oct 18, 2022;22 (20):

Optical Gas-Cell Dynamic Adsorption in a Photoacoustic Spectroscopy-Based SOF and SOF Gas Sensor.

Ying Zhang, Mingwei Wang, Pengcheng Yu, Zhe Liu
Author Information
  1. Ying Zhang: Scientific Research Institute of Electric Power, Guizhou Power Grid Company Ltd., 251 Jiefang Road Nanming District, Guiyang 550002, China. ORCID
  2. Mingwei Wang: Scientific Research Institute of Electric Power, Guizhou Power Grid Company Ltd., 251 Jiefang Road Nanming District, Guiyang 550002, China.
  3. Pengcheng Yu: Scientific Research Institute of Electric Power, Guizhou Power Grid Company Ltd., 251 Jiefang Road Nanming District, Guiyang 550002, China.
  4. Zhe Liu: Scientific Research Institute of Electric Power, Guizhou Power Grid Company Ltd., 251 Jiefang Road Nanming District, Guiyang 550002, China.
PMID: 36298300 DOI: 10.3390/s22207949

Abstract

SOF and SOF are the main components from the decomposition of insulation gas SF. Photoacoustic spectroscopy (PAS) has been acknowledged as an accurate sensing technique. Polar material adsorption for SOF and SOF in the photoacoustic gas cell of PAS may affect detection efficiency. In this paper, the optical gas-cell dynamic adsorptions of four different materials and the detection effects on SOF and SOF are theoretically analyzed and experimentally demonstrated. The materials, including grade 304 stainless steel (SUS304), grade 6061 aluminum alloy (Al6061), polyvinylidene difluoride (PVDC), and polytetrafluoroethylene (PTFE), were applied inside the optical gas cell. The results show that, compared with metallic SUS304 and Al6061, plastic PVDC and PTFE would reduce the gas adsorption of SOF and SOF by 10 to 20% and shorten the response time during gas exchange. The complete gas defusing period in the experiment was about 30 s. The maximum variations of the 90% rising time between the different adsorption materials were approximately 3 s for SOF and 6 s for SOF, while the generated photoacoustic magnitudes were identical. This paper explored the material selection for PAS-based gas sensing in practical applications.

Keywords

adsorption effect harmonic detection optical gas sensing photoacoustic cell photoacoustic spectroscopy

References

  1. Photoacoustics. 2022 Apr 12;26:100353 [PMID: 35479193]
  2. Photoacoustics. 2022 Jun 30;27:100382 [PMID: 36068799]
  3. Sensors (Basel). 2021 Aug 21;21(16): [PMID: 34451086]
  4. Front Optoelectron. 2021 Dec;14(4):407-413 [PMID: 36637758]
  5. ACS Omega. 2020 Mar 27;5(13):7722-7728 [PMID: 32280916]
  6. Opt Express. 2017 Feb 06;25(3):1806-1814 [PMID: 29519033]

Grants

  1. QianKeHeZhiCheng [2021] General 365/Science and Technology Support Program of Guizhou Province
  2. GZKJXM20210348/China Southern Power Grid Co., Ltd. Grant Project

MeSH Term

Adsorption
Aluminum
Stainless Steel
Spectrum Analysis
Plastics
Polytetrafluoroethylene

Chemicals

Aluminum
Stainless Steel
Plastics
Polytetrafluoroethylene
Journal Article

Word Cloud

Created with Highcharts 10.0.0SOFgasadsorptionphotoacousticsensingcelldetectionopticalmaterialssPhotoacousticspectroscopyPASmaterialpaperdifferentgradeSUS304Al6061PVDCPTFEtimemaincomponentsdecompositioninsulationSFacknowledgedaccuratetechniquePolarmayaffectefficiencygas-celldynamicadsorptionsfoureffectstheoreticallyanalyzedexperimentallydemonstratedincluding304stainlesssteel6061aluminumalloypolyvinylidenedifluoridepolytetrafluoroethyleneappliedinsideresultsshowcomparedmetallicplasticreduce1020%shortenresponseexchangecompletedefusingperiodexperiment30maximumvariations90%risingapproximately36generatedmagnitudesidenticalexploredselectionPAS-basedpracticalapplicationsOpticalGas-CellDynamicAdsorptionSpectroscopy-BasedGasSensoreffectharmonic

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