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    Journals >Laser & Optoelectronics Progress >Volume 59 >Issue 13 >Page 1300006 > Article
    • Laser & Optoelectronics Progress
    • Vol. 59, Issue 13, 1300006 (2022)
    Application Research of Tunable Diode Laser Absorption Spectroscopy in Petroleum Industry
    Jinyi Li1、*, Lianhui Li1, Shuo Zhao2, Peng Ren2, Shanjun Tian2, and Hongli Jin2
    Author Affiliations
  • 1Tianjin Key Laboratory of Intelligent Control of Electrical Equipment, School of Control Science and Engineering, Tiangong University, Tianjin 300387, China
  • 2Eastern Crude Oil Storage and Transportation Co., Ltd., National Petroleum and Natural Gas Pipe Network Group, Xuzhou 221008, Jiangsu , China
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    DOI: 10.3788/LOP202259.1300006 Cite this Article Set citation alerts
    Jinyi Li, Lianhui Li, Shuo Zhao, Peng Ren, Shanjun Tian, Hongli Jin. Application Research of Tunable Diode Laser Absorption Spectroscopy in Petroleum Industry[J]. Laser & Optoelectronics Progress, 2022, 59(13): 1300006 Copy Citation Text show less
    Structure diagram of the gas cell sampling system
    Fig. 1. Structure diagram of the gas cell sampling system
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    Cooperative target telemetry system based on WMS
    Fig. 2. Cooperative target telemetry system based on WMS
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    Layout of a fenced TDLAS system
    Fig. 3. Layout of a fenced TDLAS system
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    Handheld TDLAS system with non-cooperative targets for remote sensing
    Fig. 4. Handheld TDLAS system with non-cooperative targets for remote sensing
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    Intelligent robot equipped with RMLD[44]
    Fig. 5. Intelligent robot equipped with RMLD[44]
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    Realization of the leak localization[44]
    Fig. 6. Realization of the leak localization[44]
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    UAV carrying a small methane laser sensor[45]
    Fig. 7. UAV carrying a small methane laser sensor[45]
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    Structure of the ICL non-cooperative target telemetry experiment system[46]
    Fig. 8. Structure of the ICL non-cooperative target telemetry experiment system[46]
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    Leak plume image[46]
    Fig. 9. Leak plume image[46]
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    A set of methane and ethane detector system deployed on the vehicle[62]
    Fig. 10. A set of methane and ethane detector system deployed on the vehicle[62]
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    Field test results of dual-gas (methane / ethane) sensor system. (a) Methane; (b) ethane[62]
    Fig. 11. Field test results of dual-gas (methane / ethane) sensor system. (a) Methane; (b) ethane[62]
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    A new type of compact dense mode multi-channel gas cell[92]
    Fig. 12. A new type of compact dense mode multi-channel gas cell[92]
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    A portable hydrogen sulfide detection sensor[93]
    Fig. 13. A portable hydrogen sulfide detection sensor[93]
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    A mid-infrared hydrogen sulfide gas detection system[97]
    Fig. 14. A mid-infrared hydrogen sulfide gas detection system[97]
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    TDLAS system for oxygendetection in the remaining empty layer at the top of oil tank[114]
    Fig. 15. TDLAS system for oxygendetection in the remaining empty layer at the top of oil tank[114]
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    Structure of the detector gun in the TDLAS system[114]
    Fig. 16. Structure of the detector gun in the TDLAS system[114]
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    A handheld remote methane leak detector[125]
    Fig. 17. A handheld remote methane leak detector[125]
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    RMLD deployed on UAV[126]
    Fig. 18. RMLD deployed on UAV[126]
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    Device combining the robot platform “Gasbot” with RMLD[129-130]
    Fig. 19. Device combining the robot platform “Gasbot” with RMLD[129-130]
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    ManufacturerModelDetection limitFeatureReference
    HESAIHS40005×10-6 mhandheld standoff detect47
    HANWEIHRLD1005×10-6 mhandheld standoff detect48
    Anfu ElectronicsFLT1005×10-6 mIP68 level protection49
    AURORAARD10005×10-6 mlow power consumption50
    GAINWAYGW3020B0.001%high stability51
    CHUANGZHIZCB10010-6pump suction52
    ERANNTEXMS60010-8pump suction53
    DOG TechnologiesRLGD1005×10-6 mportable54
    CORWCONLmn5×10-6 mportable55
    MSAS-1012-1500×10-6 mcooperative target telemetry56
    Table 1. Performance index of methane detector
    Target gasDetection band /μmDetection schemeDetection componentDetection limitDetection accuracyOptical path /mReference
    CH41.653non-cooperative target telemetrysingle50×10-6 m-20.042
    1.651open optical pathsingle2.0×10-6 Hz-1/2-0.143
    1.653gas cell10×10-6-2.044
    1.650non-cooperative target telemetry5×10-6 m50%15.045
    C2H61.653gas cell---57
    --38.458
    3.360740×10-12-57.659
    3.340299×10-12-54.660
    1.653-4.8%-61
    3.337non-cooperative target telemetry2.4×10-12--62
    C3H81.684gas cellmultiple---63
    1.686single---64
    3.3703×10-6 m-0.265
    multiple---69
    single0.6×10-6--66
    C4H101.686multiple---71
    3.370single0.5×10-6--65
    C2H41.621open optical pathmultiple40×10-6 m20×10-6100.072
    3.267single53×10-9-3.379
    3.35696×10-9-29.978
    1.625---76
    1.626multiple-5%5.074
    single6.6×10-61.135%-81
    -1×10-69.075
    C₂H₂1.530open optical pathmultiple--76.080
    1.5904.9×10-6-10.081
    1.520---83
    1.53050×10-6 m40×10-6100.077
    1.520gas cellsingle0.3×10-6-80.084
    single540×10-9-0.385
    3.026multiple1×10-60.3%20.086
    H2S1.578gas cell224×10-9-56.790
    1.590--30.095
    1.569--20.096
    1.5781.2×10-6-30.098
    1.58015×10-6 m-12089
    1.578single0.14×10-6-15.093
    1.575multiple42×10-6 m-5.088
    1.578single60×10-9-29.392
    8.00079 μg/m3-1.091
    150×10-9-100.097
    CO1.578multiple14×10-6--104
    1.566single0.25×10-6-56.7101
    4.560gas cellmultiple1.98×10-90.22×10-1236.0106
    4.800single-0.5 μmol/mol76.0107
    2.33040×10-6 m--108
    1.18×10-6-14.5109
    multiple0.58×10-6-14.5110
    single0.2×10-6-20.0111
    O20.760non-cooperative target telemetry2050×10-6 m--114
    H2O1-3non-cooperative target telemetry0.2×10-6-121
    2.7gas cellmultiple0.31 mmol/mol40 nmol/mol4.0122
    Table 2. Summary of TDLAS applications in petroleum industry
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    Jinyi Li, Lianhui Li, Shuo Zhao, Peng Ren, Shanjun Tian, Hongli Jin. Application Research of Tunable Diode Laser Absorption Spectroscopy in Petroleum Industry[J]. Laser & Optoelectronics Progress, 2022, 59(13): 1300006
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