Quantitative Laser-Induced Fluorescence Measurements and Modeling of Nitric Oxide in High-Pressure (6–15 Atm) Counterflow Diffusion Flames

Ravikrishna, RV; Naik, Sameer V.; Cooper, Clayton S.; Laurendeau, Normand M.

doi:10.1080/00102200490267331

Cited by 6 publications

(9 citation statements)

References 21 publications

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“…The complete understanding of the chemical kinetics involved in the production of NO at high pressure requires accurate in situ measurements of NO concentration. Most of the studies dedicated to NO measurements in laminar high pressure flames were performed using Laser Induced Fluorescence by the groups of N.M. Laurendeau [20][21][22][23][24][25][26][27][28][29][30] and R.K. Hanson [31][32][33][34][35].…”

Section: Introductionmentioning

confidence: 99%

“…The first NO LIF measurements in a counterflow burner configuration were performed by Thomsen et al [23,24] who presented an experimental and modeling study of NO formation in premixed CH4/air flames at equivalence ratios varying from 0.65 to 1.5 at atmospheric and high pressures. Further studies were performed in high pressure partially premixed and diffusion flames [25][26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

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NO formation in high pressure premixed flames: Experimental results and validation of a new revised reaction mechanism

Persis

Pillier

Idir

et al. 2020

Fuel

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This paper presents an experimental and modelling study of NO formation in high pressure premixed flames.Experiments were performed in a high-pressure counterflow burner in which laminar premixed CH4/air flames were stabilised at equivalence ratios of E.R=0.7, 1 and 1.2 and for pressures varying from 0.1 to 0.7 MPa. We report quantitative NO mole fraction profiles measured by Laser Induced Fluorescence. The effects of pressure and equivalence ratio on NO formation are discussed. These results are compared to the simulations using two reaction mechanisms: NOmecha2.0 associated to a detailed mechanism for methane oxidation: GDFkin ® 3.0 and the mechanism from Klippenstein et al., which is the most recent high-pressure NOx formation mechanism available in the literature. In general, both mechanisms are able to predict NO correctly in lean and stoichiometric high pressure flames; however, in rich flames, GDFkin ® 3.0_NOmecha2.0 gives the best predictions. The performances of these mechanisms are also tested on NO measurements in high-pressure flames from the literature.A kinetic analysis is then presented to identify the main pathways that lead to the formation and consumption of NO and highlight the differences between the two mechanisms, as well as a sensitivity analysis to identify important reactions that influence the formation/consumption of NO in our high pressure flames.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

NO formation in high pressure premixed flames: Experimental results and validation of a new revised reaction mechanism

Persis

Pillier

Idir

et al. 2020

Fuel

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“…The chemical reaction mechanism GRI -mech 3.0 is generally used to calculate methane combustion, which consists of 325 chemical reactions involving 53 species. The mechanism can reasonably and reliably predicate NOX formation, but leads to an overestimation of prompt NOX when the thermal route dominates NOX formation [30][31]. However, solving the tens/hundreds of millions of Lagrangian particles clearly implies a long computational time when using the detailed mechanism, and a high computer configuration is required [32].…”

Section: Numerical Results and Discussion 21 Numerical Modelmentioning

confidence: 99%

The Chemical and Physical Effect of Diluent H2O on NO and CO Emissions in Computational CH4 / Air Laminar Diffusion Flames

Yang¹,

Zhang²,

Sun³

et al. 2019

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“…Several researchers have extensively investigated the prompt-NO route in counterflow diffusion flames using hydrocarbons such as methane and ethane. [160][161][162][163][164][165] The measurements initially showed a necessity in the improvement of prompt-NO initiation reactions used in GRI 2.11 mechanism especially for predictions below 6 bar. Predictions by GRI 3.0 were found to be in better agreement with the NO measurements at pressures below 8 bar.…”

Section: No Studiesmentioning

confidence: 99%

Advances in understanding combustion phenomena using non-premixed and partially premixed counterflow flames: A review

Ravikrishna

Sahu

2017

International Journal of Spray and Combustion Dynamics

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Counterflow flames provide an ideal platform for understanding the flame structure and as a model to study the effect of physical and chemical perturbations on the flame structure. This article reviews the advances made in the understanding of combustion dynamics and chemistry through experimental and numerical studies in counterflow non-premixed and partially premixed flames. Key contributions on fundamental aspects such as extinction, ignition and effect of perturbations on the stability of diffusion flames are first summarized and analysed. The review then focuses on the progress made in the understanding of the effect of inert particles and flame suppressants on the flame characteristics. A review of detailed studies on edge flames facilitates further understanding of local quenching and re-ignition phenomena in highly turbulent flames. The influence of radiation model and unsteady flow-conditions on the flame kinetics and dynamics along with work on NO x kinetics has been discussed. The review also outlines that specific experiments need to be carried out over a wide range of conditions for further understanding and validation of numerical models.

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Quantitative Laser-Induced Fluorescence Measurements and Modeling of Nitric Oxide in High-Pressure (6–15 Atm) Counterflow Diffusion Flames

Cited by 6 publications

References 21 publications

NO formation in high pressure premixed flames: Experimental results and validation of a new revised reaction mechanism

NO formation in high pressure premixed flames: Experimental results and validation of a new revised reaction mechanism

The Chemical and Physical Effect of Diluent H2O on NO and CO Emissions in Computational CH4 / Air Laminar Diffusion Flames

Advances in understanding combustion phenomena using non-premixed and partially premixed counterflow flames: A review

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