Experimental Investigation of Soot Production and Oxidation in a Lab-Scale Rich–Quench–Lean (RQL) Burner

Helou, Ingrid El; Skiba, A.; Mastorakos, Epaminondas

doi:10.1007/s10494-020-00113-5

Cited by 10 publications

(17 citation statements)

References 59 publications

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“…The 11 kW burner is a turbulent, bluff body, swirl stabilized non-premixed ethylene/air burner operating at atmospheric pressure and identical to the one used in [25,26]. Ethylene is axially injected along the axis through a straight tube 4 mm in diameter.…”

Section: Methodsmentioning

confidence: 99%

“…For all, the total fuel and air flow rates remain constant keeping the equivalence ratio constant at 0.3, but the air flow split between the primary annular (Up,a) and the secondary dilution jets (Ud,a), and the location of these jets (Hj), is different. These parametric variations were chosen as the work of [25,26] revealed that each change in air split, and dilution air location led to a varying degree of soot particle production both in flame and at the exhaust stimulating further investigations in this paper. The Base Case is without any dilution air.…”

Section: Methodsmentioning

confidence: 99%

“…The aim of the present work is to report PSD and fv measurements in an ethylene non-premixed swirl burner, in order to promote our understanding of the effect of secondary air injection on soot production and oxidation from RQL combustors, and to supplement previous work conducted on this burner using both probes and laser diagnostics [25,26]. Probe measurements were performed both within and at the exit of the combustor, as both the amount and location of dilution air were systematically varied, to provide information on how the PSD and fv changes with operating conditions and location in a flame configuration of practical relevance.…”

Section: Introductionmentioning

confidence: 99%

“…Probe measurements were performed both within and at the exit of the combustor, as both the amount and location of dilution air were systematically varied, to provide information on how the PSD and fv changes with operating conditions and location in a flame configuration of practical relevance. Additionally, extinction experiments were conducted within the flame to quantify LII measurements reported previously [26]. Thus, this work aims to be a link between in situ and ex situ measurements, usually conducted separately, and discuss the difficulties when comparing the two.…”

Section: Introductionmentioning

confidence: 99%

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Soot particle size distribution measurements in a turbulent ethylene swirl flame

Falco

Helou

Oliveira

et al. 2021

Proceedings of the Combustion Institute

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There is a need to better understand particle size distributions (PSDs) from turbulent flames from a theoretical, practical and even regulatory perspective. Experiments were conducted on a sooting turbulent non-premixed swirled ethylene flame with secondary (dilution) air injection to investigate exhaust and in-burner PSDs measured with a Scanning Mobility Particle Sizer (SMPS) and soot volume fractions (fv) using extinction measurements. The focus was to understand the effect of systematically changing the amount and location of dilution air injection on the PSDs and fv inside the burner and at the exhaust. The PSDs were also compared with planar Laser Induced Incandescence (LII) calibrated against the average fv. LII provides some supplemental information on the relative soot amounts and spatial distribution among the various flow conditions that helps interpret the results. For the flame with no air dilution, fv drops gradually along the centreline of the burner towards the exhaust and the PSD shows a shift from larger particles to smaller. However, with dilution air fv reduces sharply where the dilution jets meet the burner axis. Downstream of the dilution jets fv reduces gradually and the PSDs remain unchanged until the exhaust. At the exhaust, the flame with no air dilution shows significantly more particles with an fv one to two orders of magnitude greater compared to the Cases with dilution. This dataset provides insights into soot spatial and particle size distributions within turbulent flames of relevance to gas turbine combustion with differing dilution parameters and the effect dilution has on the particle size. Additionally, this work measures fv using both ex situ and in situ techniques, and highlights the difficulties associated with comparing results across the two. The results are useful for validating advanced models for turbulent combustion.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Soot particle size distribution measurements in a turbulent ethylene swirl flame

Falco

Helou

Oliveira

et al. 2021

Proceedings of the Combustion Institute

Self Cite

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“…However, a low number of ISRs with arbitrary spacing can still be useful as a rough estimate of soot emissions and inexpensive parametric analysis. Preliminary investigations in the ethylene Cambridge Rich-Quench-Lean (RQL) combustor [10,11,21,[45][46][47] [49], which is also a target flame of the International Sooting Flame workshop.…”

Section: Resultsmentioning

confidence: 99%

Soot Emission Simulations of a Single Sector Model Combustor Using Incompletely Stirred Reactor Network Modeling

Gkantonas

Foale

Giusti

et al. 2020

Journal of Engineering for Gas Turbines and Power

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The simulation of soot evolution is a problem of relevance for the development of low-emission aero-engine combustors. Apart from detailed CFD approaches, it is important to also develop models with modest computational cost so a large number of geometries can be explored, especially in view of the need to predict engine-out soot particle size distributions (PSDs) to meet future regulations. This paper presents an approach based on Incompletely Stirred Reactor Network (ISRN) modeling that simplifies calculations, allowing for the use of very complex chemistry and soot models. The method relies on a network of Incompletely Stirred Reactors (ISRs), which are inhomogeneous in terms of mixture fraction but characterized by homogeneous conditional averages, with the conditioning performed on the mixture fraction. The ISRN approach is demonstrated here for a single sector lean-burn model combustor operating on Jet-A1 fuel in pilot-only mode, for which detailed CFD and experimental data are available. Results show that reasonable accuracy is obtained at a significantly reduced computational cost. Real fuel chemistry and a detailed physicochemical sectional soot model are consequently employed to investigate the sensitivity of ISRN predictions to the chemical mechanism chosen and to provide an estimate of the soot particle size distribution at the combustor exit.

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Comprehensive characterization of sooting butane jet flames, Part 2: Temperature and soot particle size

Mulla

Yon

Honoré

et al. 2021

Combustion and Flame

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The present work investigates the effect of jet-exit Reynolds number (Re) on soot particle size and flame temperature in n-butane jet flames. Correlation of temperature with soot volume fraction (f v ), soot precursor (polycyclic aromatic hydrocarbons or PAH), and reaction zone (OH) is also examined. The investigated flames (Re = 5000 to 21500) are identical as of the companion work (Part 1). The temperature was measured in a low-sooting region using a fine-wire thermocouple. The soot particle size distribution was obtained using a scanning mobility particle sizer (SMPS). Temporal evolution (with 0.1 s resolution) of f v in the extracted aerosol sample was monitored with a Pegasor particle sensor (PPS). f v from LII and PPS are compared, and the reasons for differences are discussed in detail. The radial location of peak temperature is biased towards the fuel-rich side. At Re 5000, peak-PAH occurs at 650 K, whereas in lifted turbulent flame (Re 21500), peak-PAH shifts to 940 K. PAH formation temperature is influenced by air/fuel mixing. Despite the variation of turbulence level (Re = 5000 -21500), peak-f v in the soot inception region occurs at a nearly identical temperature of 1400 K. Peak-f v shifts towards lower temperature with increasing height, likely due to oxidation by diffused OH. The soot mode diameter (D m ) was measured along the axis. D m increases with height and reaches a maximum near peak-f v region. D m at moderate Re

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Experimental Investigation of Soot Production and Oxidation in a Lab-Scale Rich–Quench–Lean (RQL) Burner

Cited by 10 publications

References 59 publications

Soot particle size distribution measurements in a turbulent ethylene swirl flame

Soot particle size distribution measurements in a turbulent ethylene swirl flame

Soot Emission Simulations of a Single Sector Model Combustor Using Incompletely Stirred Reactor Network Modeling

Comprehensive characterization of sooting butane jet flames, Part 2: Temperature and soot particle size

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