Two-Dimensional Temperature Measurement in a High-Temperature and High-Pressure Combustor Using Computed Tomography Tunable Diode Laser Absorption Spectroscopy (CT-TDLAS) with a Wide-Scanning Laser at 1335

Abstract

Tunable diode laser absorption spectroscopy (TDLAS) technology is a developing method for temperature and species concentration measurements with the features of non-contact, high precision, high sensitivity, etc. The difficulty of two-dimensional (2D) temperature measurement in actual combustors has not yet been solved because of pressure broadening of absorption spectra, optical accessibility, etc. In this study, the combination of computed tomography (CT) and TDLAS with a wide scanning laser at 1335–1375 nm has been applied to a combustor for 2D temperature measurement in high temperature of 300–2000 K and high pressure of 0.1–2.5 MPa condition. An external cavity type laser diode with wide wavelength range scanning at 1335–1375 nm was used to evaluate the broadened H₂O absorption spectra due to the high-temperature and high-pressure effect. The spectroscopic database in high temperature of 300–2000 K and high pressure of 0.1–5.0 MPa condition has been revised to improve the accuracy for temperature quantitative analysis. CT reconstruction accuracy was also evaluated in different cases, which presented the consistent temperature distribution between CT reconstruction and assumed distributions. The spatial and temporal distributions of temperature in the high-temperature and high-pressure combustor were measured successfully by CT-TDLAS using the revised spectroscopic database.

Keywords

Two-dimensional temperature measurement 2D high-temperature and high-pressure field tunable diode laser absorption spectroscopy TDLAS computed tomography CT combustion

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References

Tagliante

Poinsot

Pickett

L.M.

, et al. “A Conceptual Model of the Lame Stabilization Mechanisms for a Lifted Diesel-Type Flame Based on Direct Numerical Simulation and Experiments”. Combust. Flame. 2019. 201: 65–77.

Salinero

Gómez-Barea

Fuentes-Cano

, et al. “Measurement and Theoretical Prediction of Char Temperature Oscillation During Fluidized Bed Combustion.” Combust. Flame. 2018. 192: 190–204.

Lin

Q.J.

Zhao

Yao

, et al. “Ordinary Optical Fiber Sensor for Ultra-High Temperature Measurement Based on Infrared Radiation”. Sensors. 2018. 18: 4071.

Boigné

Muhunthan

Mohaddes

, et al. “X-ray Computed Tomography for Flame-Structure Analysis of Laminar Premixed Flames”. Combust. Flame. 2019. 200: 142–154.

Förster

Crua

Davy

, et al. “Temperature Measurements Under Diesel Engine Conditions Using Laser Induced Grating Spectroscopy”. Combust. Flame. 2019. 199: 249–257.

Benoy

Wilson

Lengden

, et al. “Measurement of CO₂ Concentration and Temperature in an Aero Engine Exhaust Plume Using Wavelength Modulation Spectroscopy”. IEEE Sens. J. 2017. 17(19): 6409–6417.

Nwaboh

J.A.

Pratzler

Werhahn

, et al. “Tunable Diode Laser Absorption Spectroscopy Sensor for Calibration Free Humidity Measurements in Pure Methane and Low CO₂ Natural Gas”. Appl. Spectrosc. 2017. 71(5): 888–900.

Hänsel

Reyes-Reyes

Persijn

S.T.

, et al. “Temperature Measurement Using Frequency Comb Absorption Spectroscopy of CO₂”. Rev. Sci. Instrum. 2017. 88: 053113.

Minamide

Mizutani

Wakatsuki

“Temperature Distribution Measurement with Acoustic Computerized Tomography Using Rectangular Arrangement of Transducers”. Jpn. J. Appl. Phys. 2009. 48: 07GC02.

10.

Bolshov

M.A.

Kuritsyn

Y.A.

Romanovskii

Y.V.

“Tunable Diode Laser Spectroscopy as a Technique for Combustion Diagnostics”. Spectrochim. Acta, Part B. 2015. 106: 45–66.

11.

Sur

Sun

Jeffries

J.B.

, et al. “Scanned-Wavelength-Modulation-Spectroscopy Sensor for CO, CO₂, CH₄, and H₂O in a High-Pressure Engineering-Scale Transport-Reactor Coal Gasifier”. Fuel. 2015. 150: 102–111.

12.

Yamakage

Muta

Deguchi

, et al. “Development of Direct and Fast Response Exhaust Gas Measurement”. SAE Tech. Pap.. 2008-01-2758.

13.

Rieker

G.B.

Liu

, et al. “Rapid Measurements of Temperature and H₂O Concentration in IC Engines with a Spark Plug-Mounted Diode Laser Sensor”. Proc. Combust. Inst. 2007. 31: 3041–3049.

14.

Mironenko

V.R.

Kuritsyn

Y.A.

Liger

V.V.

, et al. “Data Processing Algorithm for Diagnostics of Combustion Using Diode Laser Absorption Spectrometry”. Appl. Spectrosc. 2018. 72(2): 199–208.

15.

H. McCann, P. Wright, K. Daun. “Chemical Species Tomography”. Industrial Tomography: Systems and Applications. Amsterdam. Netherlands: Elsevier, 2015. Chap. 5, Pp. 135–174.

16.

Sanders

S.T.

, et al. “50-kHz-Rate 2D Imaging of Temperature and H2O Concentration at the Exhaust Plane of a J85 Engine Using Hyperspectral Tomography”. Opt. Express. 2013. 21(1): 1152–1162.

17.

Tsekenis

S.A.

Tait

McCann

“Spatially Resolved and Observer-Free Experimental Quantification of Spatial Resolution in Tomographic Images”. Rev. Sci. Instrum. 2015. 86: 035104.

18.

Liu

Cao

, et al. “Reconstruction of Axisymmetric Temperature and Gas Concentration Distributions by Combining Fan-Beam TDLAS with Onion-Peeling Deconvolution”. IEEE Trans. Instrum. Meas. 2014. 63(12): 3067–3075.

19.

Liu

Cao

Lin

, et al. “Online Cross-Sectional Monitoring of a Swirling Flame Using TDLAS Tomography”. IEEE Trans. Instrum. Meas. 2018. 67(6): 1338–1348.

20.

Brittelle

M.S.

Lauzier

P.T.

, et al. “2015 Demonstration of Temperature Imaging by H₂O Absorption Spectroscopy Using Compressed Sensing Tomography”. Appl. Opt. 2015. 54(31): 9190–9199.

21.

Seidel

Wagner

Dreizler

, et al. “Robust, Spatially Scanning, Open-Path TDLAS Hygrometer Using Retro-Reflective Foils for Fast Tomographic 2-D Water Vapor Concentration Field Measurements”. Atmos. Meas. Tech. 2015. 8: 2061–2068.

22.

Deguchi

Kamimoto

Kiyota

“Time Resolved 2D Concentration and Temperature Measurement Using CT Tunable Laser Absorption Spectroscopy”. Flow Meas. Instrum. 2015. 46: 312–318.

23.

Kamimoto

Deguchi

Zhang

, et al. “Real-Time 2D Concentration Measurement of CH₄ in Oscillating Flames Using CT Tunable Diode Laser Absorption Spectroscopy”. J. Appl. Nonlinear Dyn. 2015. 4(3): 295–303.

24.

Deguchi

Kamimoto

Wang

Z.Z.

, et al. “Applications of Laser Diagnostics to Thermal Power Plants and Engines”. Appl. Therm. Eng. 2014. 73: 1453–1464.

25.

Y. Deguchi. “Tunable Diode Laser Absorption Spectroscopy”. Industrial Applications of Laser Diagnostics. New York: CRS Press Taylor and Francis, 2011. Chap. 6, Pp. 167–205.

26.

Rothman

L.S.

Gordon

I.E.

Barbe

, et al. “The HITRAN2008 Molecular Spectroscopic Database.” J. Quant. Spectrosc. Radiat. Transfer. 2009. 110: 533–572.

27.

Karagiannopoulos

Cheadle

Wright

, et al. “Multiwavelength Diode-Laser Absorption Spectroscopy using External Intensity Modulation by Semiconductor Optical Amplifiers”. Appl. Opt. 2012. 51(34): 8057–8067.

28.

Cai

W.W.

“Numerical Investigation of Hyperspectral Tomography for Simultaneous Temperature and Concentration Imaging”. Appl. Opt. 2008. 47(21): 3751–3759.

29.

Cai

W.W.

Kaminski

C.F.

“A Tomographic Technique for the Simultaneous Imaging of Temperature, Chemical Species, and Pressure in Reactive Flows Using Absorption Spectroscopy with Frequency-Agile Lasers”. Appl. Phys. Lett. 2015. 104: 034101.

30.

Kraetschmer

Takami

, et al. “Validation of Temperature Imaging by H₂O Absorption Spectroscopy Using Hyperspectral Tomography in Controlled Experiments”. Appl. Opt. 2011. 50(4): A29–A37.

31.

Wang

Cen

K.F.

, et al. “Two-Dimensional Tomography for Gas Concentration and Temperature Distributions Based on Tunable Diode Laser Absorption Spectroscopy”. Meas. Sci. Technol. 2010. 21: 045301.

32.

Kasyutich

V.L.

Martin

P.A.

“Towards a Two-Dimensional Concentration and Temperature Laser Absorption Tomography Sensor System”. Appl. Phys. B: Lasers Opt. 2011. 102: 149–162.

33.

Jeon

M.G.

Deguchi

Kamimoto

, et al. “Performances of New Reconstruction Algorithms for CT-TDLAS (Computer Tomography-Tunable Diode Laser Absorption Spectroscopy)”. Appl. Therm. Eng. 2017. 115: 1148–1160.

34.

Polydorides

Tsekenis

Fisher

, et al. “A Constrained Solver for Optical Absorption Tomography”. Appl. Opt. 2018. 57: B1–B9.

35.

Liu

Zhao

Y.X.

Khambampati

A.K.

, et al. “A Parametric Level Set Method for Imaging Multiphase Conductivity Using Electrical Impedance Tomography”. IEEE Trans. Instrum. Meas. 2018. 4(4): 552–561.

36.

Ren

S.Y.

Lei

Jia

Z.P.

“Reconstruction Method for Temperature Field Measurement using Ultrasonic Tomography”. Chem. Eng. Sci. 2018. 183: 177–189.

37.

Kamimoto

Deguchi

Kiyota

“High Temperature Field Application of Two Dimensional Temperature Measurement Technology Using CT Tunable Diode Laser Absorption Spectroscopy”. Flow Meas. Instrum. 2015. 46: 51–57.

38.

Kamimoto

Deguchi

“2D Temperature Detection Characteristics of Engine Exhaust Gases Using CT Tunable Diode Laser Absorption Spectroscopy”. Int. J. Mech. Syst. Eng. 2015. 1: 109.

39.

L.M.

Guo

“Transform-Domain Fast Sum of the Squared Difference Computation for H.264/AVC Rate-Distortion Optimization”. IEEE Trans. Circuits Syst. Video Technol. 2007. 17(6): 765–773.

40.

Pan

“Recent Progress in Digital Image Correlation”. Exp. Mech. 2011. 51: 1223–1235.

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Two-Dimensional Temperature Measurement in a High-Temperature and High-Pressure Combustor Using Computed Tomography Tunable Diode Laser Absorption Spectroscopy (CT-TDLAS) with a Wide-Scanning Laser at 1335–1375 nm

Abstract

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