Infrared and Laser Engineering, Volume. 49, Issue 6, 20190575(2020)
Mainstream NDIR breathing CO2 monitoring system based on new light chamber structure
Figures & Tables(15)
Fig. 2. (a) Optimization results of the CPC focusing system; (b) Aluminum CPC
Fig. 3. (a) Signal acquisition system (gas chamber) with CPC; (b) Respiratory CO2 monitoring system; (c) Schematic diagram of the main parts of the monitoring system
Fig. 4. (a) Straight cylinder concentrator; (b) Cone concentrator; (c) compound parabolic concentrator ray trace using ZEMAX, and samples of them; (d) Photoconductive infrared detector of the chamber
Fig. 5. (a) CMOS detector(Point Grey Research, Inc) (left) and IR source EMIRS200(Axetris)(right); (b) Environment of CPC verification experiment
Fig. 7. When the CPC and the detector are at different distances, (a) Spot pattern on the detector obtained by ZEMAX simulation; (b)Spot pattern captured by the CMOS detector in the verification experiment;(c) Comparison of the normalized light spot cross-section brightness distribution between the simulation results (silver) and experimental results (orange) at different distances between the CPC and the detector
Fig. 8. (a)Straight cylinder concentrator, (b)cone concentrator , (c)light distribution of compound parabolic concentrator on the signal channel detector
Fig. 9. Relationship between the output signals of three systems corresponding to the CO2 concentration in the range of 10 000 ppm to 73 000 ppm CO2 concentration
Table 1. Input parameters in ZEMAX
View tableView in ArticleTable 1. Input parameters in ZEMAX
Parameters Value Power of the source/W 1 Type of IR source Thermal infrared emitters (Lambertian source) Detector size/mm2 7.2×5.6 Number of analyzing rays 10 000 000 IR source size/mm2 2.1×1.8 Distance from light source to CPC/mm 0.5 Distance from CPC to detector/mm 20
Table 2. Optimized parameters of CPC
View tableView in ArticleTable 2. Optimized parameters of CPC
Parameters Value Radial aperture/mm 1.79 Angle/(°) 22.86 Length/mm 9.99
Table 3. Optical efficiency simulation results of three structures
View tableView in ArticleTable 3. Optical efficiency simulation results of three structures
Type Light efficiency Straight cylinder concentrator 0.047% Cone concentrator 1.2% Compound parabolic concentrator 4.3%
Table 4. Third-order polynomial fitting coefficient and calibration coefficient of system output and CO2 concentration
View tableView in ArticleTable 4. Third-order polynomial fitting coefficient and calibration coefficient of system output and CO2 concentration
Type a b c d R 2Straight cylinder 0.000 70 –0.148 7 10.494 24.943 0.969 9 Cone 0.001 5 –0.314 8 22.866 52.963 0.978 1 CPC 0.001 1 –0.262 3 24.033 68.779 0.985 3
Table 5. Signal-to-noise ratio of the monitoring system after installing three structures
View tableView in ArticleTable 5. Signal-to-noise ratio of the monitoring system after installing three structures
Type SNR Straight cylinder 12.8 Cone 17.2 CPC 24.65
Tools
Get Citation
Copy Citation Text
Tao Xiong, Ming Gao, Gibson Des, Hutson David. Mainstream NDIR breathing CO2 monitoring system based on new light chamber structure[J]. Infrared and Laser Engineering, 2020, 49(6): 20190575
Paper Information
Category: Photoelectric measurement
Received: Mar. 5, 2020
Accepted: --
Published Online: Aug. 19, 2020
The Author Email:
© Copyright 2018-2021 | Chinese Laser Press.
All Rights Reserved 沪ICP备15018463号-20