D Temperature Detection Characteristics of Engine Exhaust Gases Using CT Tunable Diode Laser Absorption Spectroscopy

Two dimensional (2D) temperature and concentration distribution is related to the combustion structure, the combustor efficiency in engines, burners, gas turbines and so on. Recently, tunable diode laser absorption spectroscopy (TDLAS) as a multi-species measurement technique with high sensitivity and high response has been developed and applied to industrial process monitoring and control technologies in combustion environments. With these engineering developments, transient phenomena such as start-ups and load changes in engines have been gradually elucidated in various conditions. This paper discusses a study of the fast response 2D temperature distribution measurement method based on the combination of TDLAS and Computed Tomographic (CT) reconstruction using absorption spectra of water vapor at 1388nm. The computed tomography tunable diode laser absorption spectroscopy (CTTDLAS)method was appliedtoengine exhausts for 2D temperature distribution measurements. The measured 2D temperature showed better characteristics compared with the temperature measured by a thermocouple. Theoretical H2O absorption spectra in the 1388 nm near-infrared region calculated by the revised HITRAN database were used for temperature measurement. For accurate measurement of temperature in combustion gases, the spectroscopic databases were modified using experimentally measured spectral parameters that are not found in the databases. Accuracy of temperature measurement using TDLAS have also been discussed to demonstrate its applicability to various types of combustor. 2D Temperature Detection Characteristics of Engine Exhaust Gases Using CT Tunable Diode Laser Absorption Spectroscopy Publication History: Received: September 01, 2015 Accepted: November 24, 2015 Published: November 26, 2015


Introduction
Improvements in combustion efficiencies and reduction in harmful combustion emissions such as NOx, CO and particles in engines, burners, gas turbines and so on are important for our lives and the science development.It can be accomplished by measuring and controlling the important combustion parameters such as temperature and species concentration.Conventionally a thermocouple and a sampling probe have been widely used as a temperature and concentration measurement devices.However it is intrinsically a point measurement methodand it is difficult to measure temperature and concentration distributions inside the combustion chamber and exhaust with sufficient time resolution.Compared to the point measurement, combustion chamber designs and fuelling strategies can be efficiently evaluated by visualizing two dimensional(2D) temperature and concentration distributions, which have effects on complex phenomena such as knocking, combustion instability and production of pollutants in combustors.Therefore, 2D temperature and concentration distribution plays an important role for the combustion structure, the combustion efficiency and reduction of pollutants including NOx, CO and particles in engines, burners, gas turbines and so on.
Recently, tunable diode laser absorption spectroscopy (TDLAS) as a for temperature and species concentration measurement technique with high sensitivity and high response in combustion environments has been researched and applied to the actual combustors [1][2][3][4][5][6][7][8][9][10][11][12].With these engineering developments, transient phenomena such as start-ups and load changes in engines have been gradually elucidated in various conditions [3].This paper discusses a study of the fast response 2D temperature and concentration distribution measurement method based on the combination of TDLAS and Computed Tomographic (CT) reconstruction using absorption spectra of water vapor at 1388nm.The computed tomography tunable diode laser absorption spectroscopy (CT-TDLAS)method [13][14][15][16][17] was applied to engine exhausts for 2D temperature distribution measurement.Theoretical H

Theory
The gas temperature and species concentration measurement method using near infrared tunable diode laser absorption spectroscopy (TDLAS) was used in this research.TDLAS is a multispecies measurement technique with high sensitivity and high response by continuously scanning laser wavelengths and measuring absorption spectra of selected gases.Principle of TDLAS is based on Lambert Beer's law.When a beam of laser diode is transmittedacross the measurement area containing target gases, the strength of the permeated light is related to absorber concentration according to Lambert Beer's law.TDLAS depends on this spectroscopic principles to continuously measure temperature and species concentration of selected gases.The number density of the measured species n is related to the amount of light absorbed as in the following formula [1]: Here, I λ0 is the incident light intensity, I λ the transmitted light intensity, A λ the absorbance, n i the number density of species i, L the 0 , , / exp{ } exp ( ) path length, S i,j the temperature dependent absorption line strength of the absorption line j, and G vi,j the line broadening function.
In this study H 2 O absorption spectra in the 1388nm near-infrared region were used for sensitive measurement of temperature in combustion environments.Theoretical H 2 O absorption spectra in the 1388 nm near-infrared region calculated by the HITRAN database [18] are shown in Figure 1.Three absorption lines located at 1388.135nm (#1), 1388.326nm(#2), and 1388.454nm(#3) have remarkable temperature dependence were chosen to measure temperature.It is important to use several absorption lines with different temperature dependence to reduce the temperature error induced by a CT algorism.When several laser beamsare transmitted across the measurement area containing a target gas as shown Figure 2, integrated absorbance of each laser path is related to the absorber temperature and concentration distribution along the path as in the following formula [13][14][15][16][17]: Here, A λ,p is integrated absorbance of some wavelength λ in a path, α λ,q is absorption coefficient of some wavelength λ inside a grid q on the path and is depend on temperature and density of species.L p,q is path length inside the grid q.
Temperature and H 2 O concentration at each analysis grid were determined using a multifunction minimization method [19] to minimize the spectral fitting error at 1338.0-1338.6 nm.Sets of H 2 O densities and temperatures at analysis grids are obtainedby the best-fitted distributions for a given measurement of A λ , pusing the  , , , P q p q q q A n L minimization procedure shown in Figure 3.A set of measured H 2 O absorption spectra was compared to the theoretical spectra to minimize the mean squared errors.
A polynomial noise reduction technique [14,15] was also used to reduce noises such as the effect of laser beam steering.

Experiment Evaluation of temperature measurement accuracy
Tunable diode laser absorption spectroscopies (TDLAS) of H 2 O in a heated cell were used to obtain the spectroscopic data and improve temperature measurement accuracy.Figure 4 shows the experimental setup for H 2 O absorption spectra measurements from 300K to 800K using TDLAS.A distributed feedback(DFB)diode laser (NTT Electronics Co., NLK1E5GAAA) at 1388nm was used for obtaining H2O absorption spectra at 1388-1388.6nm.The laser was driven with diode laser controller (Thorlabs Co., TXP5004) with current source and temperature-control units (Thorlabs Co., ITC5052).Wavelength modulation was consisted of 5 kHz saw tooth ramp, which has better wavelength linearity for spectral evaluation than sinusoidal modulation, using a function generator (Wave factory Co., WF1946).The laser beam was irradiated into the measurement cell using a collimator (THORLABS Co., 50-1310-APC).The transmitted light intensities were detected by a photodiode (Hamamatsu Photonics and G8370-01).The photodiode signal was amplified by an amplifier (Stanford Research Systems, SR445A) and directly stored by a recorder (HIOKI E.E.Co., 8861 Memory High coda HD Analog16).

2D temperature measurements in engine exhausts using CT-TDLAS
Figure 5 shows the outline of an experimental apparatus of the 2D temperature measurement used in this study.A DFB laser (NTT Electronics Co., NLK1E5GAAA) at 1388nm with scanning range of 0.6nm was used to measure water vapor absorption spectra.The lasers were scanned at 1kHz and these outputs were mixed using a fiber combiner.Absorption spectra were simultaneously measured to calculate the instant 2D temperature using 16 path measurement cells shown in Figure 5.The laser beam was separated by an optical fiber splitter (OPNETI CO., SMF-28e 1310nm SWBC 1×16) and the separated laser beams were irradiated into the target area by 16 collimators (THORLABS Co., 50-1310-APC).The transmitted light intensities were detected by photodiodes (Hamamatsu Photonics and G8370-01), and taken into the recorder (HIOKI E.E.Co., 8861 Memory Highcoda HD Analog16).The data acquisition rate was 500kHz (500 data points on every 1 scan of absorption spectra).Temperature in the measurement region was also measured by chromel-alumel thermocouples with a diameter of 100μm (KMT-100-100-120).
2D temperature measurements in engine exhausts using CT-TDLAS were performed using a gasoline engine (FUJI HEAVY INDUSTRIES, Inc., EX13) as shown in Figure 6.The laser paths were set at the position 5mm above the outlet of the engine exhaust pipes.The diameter of 16 path measurement cell was 70mm.The diameter of the engine exhaust pipe is 22mm with thickness of 3.5mm and the pipe length was 160mm.

Evaluation of temperature measurement accuracy
In this study three absorption lines located at 1388.135 nm (#1), 1388.326nm (#2), and 1388.454nm (#3) were chosen to measure temperature and H 2 O concentration.Absorption spectra of H 2 O at 1388-1388.6nm in the heated cell were measured by TDLAS.The corrected theoretical spectra showed good agreement with measurement results as shown Figure 8. Figure 9 shows comparison of measured temperature between TDLAS and thermocouple.Improved agreement of measured temperature between TDLAS and thermocouple was obtained using corrected spectroscopic data.It is worth to mention that the revision of the spectroscopic database leads to better temperature measurement accuracy.

2D temperature measurements in engine exhausts using CT-TDLAS
CT measurement cell was applied to engine exhausts.The center of an exhaust outlet was set at the center of the CT measurement cell.The exhaust gas temperature distribution was measured by CT tunable diode laser absorption spectroscopy (CT-TDLAS).The exhaust gas temperature at X=0mm, Y=0mm was simultaneously measured by a thermocouple.Figure 10 shows the temperature history measured by the thermocouple at X=Y=0mm, averaged temperature of the laser path 6 and 8, and engine rotation speed.The engine was started at t=0s and the engine revolution was increased up to 2500 rpm.In this   Figure 11 show the 2D temperature measurement results in engine exhausts.The results showed high temperature area at the center of the exhaust pipe and temperature distribution was a rapid change according to the engine evolution.The rapid 2D temperature measurement in engine exhaust using CT-TDLAS successfully demonstrated the merit of this technique for practical diagnostic use, including high temperature and pressure area such as internal combustion engine.
In high temperature (1000-2000 K) and pressure (1-5MPa) fields such as the temperature distribution in combustion chambers of an standard vehicle engine, the spectral parameters under these conditions to evaluate quantitative measurements of temperature and species concentration will be important.

Conclusion
2D Temperature detection characteristics of engine exhausts using CT tunable diode l Laser absorption spectroscopy were investigated.Based on the results of this study, the following conclusions are summarized as follows.
1. Theoretical absorption spectra calculated by HITRAN database showed several discrepancies between measured and calculated spectra.The revision of the spectroscopic data leads to better measurement accuracy.2. The 2D temperature measurement method using CT tunable diode laser absorption spectroscopy was developed and

Figure 2 :
Figure 2: CT grid and laser path.
TDLAS and they are compared with corrected theoretical spectra.The theoretical absorption spectra of H 2 O were revised by the measured spectralparameters, which include the set of temperature dependent absorption line strength (S i,j (T)) between 1388-1388.6nm.

Page 4 of 7 Figure 4 :
Figure 4: Experimental apparatus for evaluation of temperature measurement accuracy.

Figure 9 :
Figure 9: Comparison of measured temperatures by TDLAS and thermocouple.

Mechanical Systems Engineering Takahiro Kamimoto and Yoshihiro Deguchi *
Graduate School of Advanced Technology and Science, Tokushima University, 2-1, Minamijyosanjima, Tokushima, 770-8506 Japan 2 O absorption spectra in the 1388 nm International Journal of