TDLAS-based NH3 mole fraction measurement for exhaust diagnostics during selective catalytic reduction using a fiber-coupled 2.2-µm DFB diode laser

Stritzke, Felix; Diemel, Oliver; Wagner, Steven

doi:10.1007/s00340-015-6073-5

Cited by 59 publications

(23 citation statements)

References 37 publications

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“…A reference temperature of 296 K was used. Reproduced from Sur et al [15] Transition Quantity (4) 0.044 (2) 0.202 (8) 0.033 (1) 0.443 (14) 0.263 (11) n i 0.66 (5) 0.69 (5) 1.14 (5) 0.59 (5) -0.86 (10) sQ(10,6) γ i,0 (cm −1 /atm) 0.104 (5) 0.034 (2) 0.216 (20) 0.033 (1) 0.423 (26) 0.257 (8) n i 0.98 (10) 0.41 (10) 1.09 (10) 0.48 (10) -0.86 (20) sQ (9,9) γ i,0 (cm −1 /atm) 0.109 (4) 0.051 (2) 0.214 (7) 0.042 (2) 0.57 (17) 0.307 (9) n i 0.81 (5) 0.76 (5) 0.74 (5) 0.69 (5) -0.98 (10) sQ (9,8) γ i,0 (cm −1 /atm) 0.098 (3) 0.048 (2) 0.187 (10) 0.039 (1) 0.511 (16) 0.316 (13) n i 0.70 (5) 0.67 (5) 0.69 (5) 0.64 (5) -0.90 (10) at linecenter, we also have to consider how sensitive the resulting WMS-2f/1f signal will be to the presence of interfering species. Here, we present a novel procedure for choosing an optimal WMS modulation depth in the presence of spectral in...…”

Section: Modulation Depth Optimizationmentioning

confidence: 97%

“…For these situations, in addition to maximizing the WMS-2f signal The superscripts denote the uncertainties in the measurements with respect to the last decimal digit (e.g., for sQ(10,7): S(296 K) = 0.2195 ± 0.055 cm −2 /atm). Reproduced from Sur et al [15] Transition Linecenter (cm −1 ) E ′′ (cm −1 ) S @ 296 K (cm −2 /atm) sQ ( The superscripts denote the uncertainties in the measurements with respect to the last decimal digit (e.g., for sQ (10,7): γ N 2 ,0 = 0.087 ± 0.004 cm −1 /atm). A reference temperature of 296 K was used.…”

Section: Modulation Depth Optimizationmentioning

confidence: 99%

“…At higher hydrocarbon concentrations on the order of 100 ppm expected in practical environments, spectral interference from the strong hydrocarbon C-H symmetric stretch bands at 2.25 µm is expected to significantly degrade sensor performance. More recently, Stritzke et al [7] demonstrated detection limits of 50-70 ppm also using DFB diode lasers at 2.20 µm in 800 K exhaust with high H 2 O and CO 2 concentrations (15 % each). For NH 3 concentrations below this detection limit, however, this sensor fails because of strongly interfering H 2 O and CO 2 features.…”

Section: Introductionmentioning

confidence: 96%

“…The novelty of the current detection scheme lies in: (1) the selection of a previously unused NH 3 transition near 10.39 µm that is strong and relatively free of spectral interference from H 2 O and CO 2 transitions at high temperature compared to transitions previously showcased in the literature [5][6][7]14], and (2) the use of a novel procedure for selecting scanned-WMS tuning parameters that minimizes sensitivity to fluctuations in the concentration of spectral interferers without significantly sacrificing signalto-noise ratio (SNR) of the WMS lineshapes. Experimentally derived spectroscopic parameters of the transitions used for this sensor were reported by Sur et al [15], thus enabling higher-accuracy NH 3 spectral models than current databases (e.g., HITRAN).…”

Section: Introductionmentioning

confidence: 99%

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High-sensitivity in situ QCLAS-based ammonia concentration sensor for high-temperature applications

et al. 2016

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Haber-Bosch process, the organic synthesis of numerous compounds, and the selective catalytic reduction (SCR) of nitric oxide (NO x ) emissions in combustion-based energy systems (e.g., gas turbines and diesel engines) [1]. In SCR, ammonia is typically injected into the combustion exhaust and allowed to react with the NO x species to form water vapor and nitrogen. NO x and NH 3 concentrations are directly correlated in such applications. If NH 3 is injected at a sub-optimal temperature or flow rate, the optimal NO x abatement is not attained; if too much NH 3 is added, unreacted NH 3 will remain in the exhaust and escape into the environment, known as ammonia slip [2,3]. This poses a significant risk to the public as both NO x and NH 3 are toxic to public health and to the environment. To prevent sub-optimal operation of SCR systems, it is desirable to implement closed-loop control systems that can quickly respond to changing conditions within the SCR. A key element in such closed-loop systems is a real-time sensor for ammonia concentration. Unfortunately, common samplingbased speciation techniques either require high sampling flow rates to enable temporally resolved NH 3 concentration measurements (as in gas chromatography) or are slow by nature (as in Fourier transform infrared spectroscopy). Additionally, NH 3 adsorption onto the sampling manifolds can result in significant discrepancies between the measured and actual concentrations. Therefore, a high-sensitivity in situ sensor for trace quantities of NH 3 is needed to provide real-time monitoring of these industrial processes. To achieve this capability, laser absorption spectroscopy (LAS) is often used because of its significant advantages for in situ monitoring of gas properties associated with high temporal resolution, measurement sensitivity, and robustness against various forms of noise [4].Several studies have demonstrated in situ LAS-based NH 3 sensors in high-temperature environments. Webber Abstract A novel quantum cascade laser (QCL) absorption sensor is presented for high-sensitivity in situ measurements of ammonia (NH 3 ) in high-temperature environments, using scanned wavelength modulation spectroscopy (WMS) with first-harmonic-normalized second-harmonic detection (scanned WMS-2f/1f) to neutralize the effect of non-absorption losses in the harsh environment. The sensor utilized the sQ(9,9) transition of the fundamental symmetric stretch band of NH 3 at 10.39 µm and was sinusoidally modulated at 10 kHz and scanned across the peak of the absorption feature at 50 Hz, leading to a detection bandwidth of 100 Hz. A novel technique was used to select an optimal WMS modulation depth parameter that reduced the sensor's sensitivity to spectral interference from H 2 O and CO 2 without significantly sacrificing signal-to-noise ratio. The sensor performance was validated by measuring known concentrations of NH 3 in a flowing gas cell. The sensor was then demonstrated in a laboratory-scale methane-air burner seeded with NH 3 , achieving a demonstrated detecti...

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Section: Modulation Depth Optimizationmentioning

confidence: 97%

Section: Modulation Depth Optimizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

High-sensitivity in situ QCLAS-based ammonia concentration sensor for high-temperature applications

et al. 2016

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show abstract

“…The absorption signal intensity becomes an integrated value of the optical path. In this study, several optical paths are intersected to each other to form the analysis grid, reconstructing 2D temperature distribution by a CT method (Ma et al, 2008;Wang et al, 2010;Kasyutich et al, 2011;An et al, 2011;Deguchi et al, 2012;Deguchi et al, 2015;An et al, 2015;Cai, et al, 2015;Jatana, et al, 2015;McCann, et al, 2015;Seidel, et al, 2015;Stritzke, et al, 2015;Kamimoto et al, 2016). Figure 4 shows concept of analysis grids and laser beam paths.…”

Section: Theorymentioning

confidence: 99%

Simultaneous two cross-sectional measurements of NH<sub>3</sub> concentration in bent pipe flow using CT-tunable diode laser absorption spectroscopy

Matsui

Udagawa

Deguchi

et al. 2019

JTST

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Urea Selective Catalytic Reduction (urea SCR) system is widely used for diesel engine to reduce the emission of NO x by NH 3 which is provided by a hydrolysis of urea water. Concentration distribution of NH 3 in an exhaust pipe is an important factor for improvement of the SCR efficiency and prevention of NH 3 slip and urea deposit. Therefore, it is necessary to measure two-dimensional (2D) concentration of NH 3 in detail. The purpose of this study is to develop the real-time two cross-sectional measurements technology of NH 3 concentration using the computed tomography-tunable diode laser absorption spectroscopy (CT-TDLAS). Theoretical NH 3 concentration distribution which was reconstructed by CT agreed to CFD results and quadruple pipe's results showed good resolution by 14th order reconstruction. Therefore, this method has enough resolution and accuracy for measuring the concentration distribution of NH 3. And this method was employed in a bent pipe model demonstrated a urea SCR system. The experimental results of two cross-sectional 2D concentration of NH 3 show differences of the concentration distribution of NH 3 each cross-section and flow pattern like swirl flow. It was found that CT-TDLAS was an effective method to measure concentration distribution of NH 3 and observe characteristics of flow. In addition, observing flow pattern enable to validate CFD results, and it helps to improve efficiency of after treatment system.

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Direct Absorption and Photoacoustic Spectroscopy for Gas Sensing and Analysis: A Critical Review

Fathy

Sabry

Hunter

et al. 2022

Laser & Photonics Reviews

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Optical spectroscopy has a broad scientific basis in chemistry, physics, and material science, with diverse applications in medicine, pharmaceuticals, agriculture, and environmental monitoring. Fourier transform infrared (FTIR) spectrometers and tunable laser spectrometers (TLS) are key devices for measuring optical spectra. Superior performance in terms of sensitivity, selectivity, accuracy, and resolution is required for applications in gas sensing. This review deals with gas measurement based on either direct optical absorption spectroscopy or photoacoustic spectroscopy. Both approaches are applicable to FTIR spectroscopy or TLS. In photoacoustic spectroscopy, cantilever-based photoacoustic spectroscopy is focused due its high performance. A literature survey is conducted revealing the recent technological advances. Theoretical fundamental detection limits are derived for TLS and FTIR, considering both direct absorption and photoacoustic spectroscopies. A theoretical comparison reveals which technology performs better. The minimum normalized absorption coefficient and normalized noise equivalent absorption coefficient appear as key parameters for this comparison. For TLS-based systems, direct absorption spectroscopy is found to be the best for lower laser power and longer path length. For FTIR-based systems, direct absorption is found to be the best for low temperature sources, higher spectrometer throughput, faster mirror velocity, and longer gas cells.

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TDLAS-based NH3 mole fraction measurement for exhaust diagnostics during selective catalytic reduction using a fiber-coupled 2.2-µm DFB diode laser

Cited by 59 publications

References 37 publications

High-sensitivity in situ QCLAS-based ammonia concentration sensor for high-temperature applications

High-sensitivity in situ QCLAS-based ammonia concentration sensor for high-temperature applications

Simultaneous two cross-sectional measurements of NH<sub>3</sub> concentration in bent pipe flow using CT-tunable diode laser absorption spectroscopy

Direct Absorption and Photoacoustic Spectroscopy for Gas Sensing and Analysis: A Critical Review

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