Premixed flame quenching distance between cold walls: Effects of flow and Lewis number

Aiden Kelly; Rémi Daou; Joel Daou; Vadim N. Kurdyumov; Prabakaran Rajamanickam

doi:10.1016/j.proci.2025.105836

Premixed flame quenching distance between cold walls: Effects of flow and Lewis number

Aiden Kelly, Rémi Daou, Joel Daou, Vadim N. Kurdyumov, Prabakaran Rajamanickam

Research output: Contribution to journal › Article › peer-review

Abstract

This study investigates the critical conditions for flame propagation in channels with cold walls. We analyse the impact of the Lewis number and flow amplitude (𝐴) on the minimum channel width required to sustain a premixed flame. Our results span a wide range of Lewis numbers, encompassing both aiding and opposing flow conditions. Results are presented for both variable and constant density models. A combined numerical approach, involving stationary and time-dependent simulations, is employed to determine quenching distances and solution stability. We find that smaller Lewis numbers and aiding flows (𝐴 < 0) facilitate flame propagation in narrower channels, while opposing flows (𝐴 > 0) tend to destabilise the flame, promoting asymmetric solutions. For sufficiently large positive values of 𝐴, the quenching distance is determined by asymmetric solutions, rather than the typical symmetric ones.

Original language	English
Article number	105836
Number of pages	6
Journal	PROCEEDINGS OF THE COMBUSTION INSTITUTE
Volume	41
DOIs	https://doi.org/10.1016/j.proci.2025.105836
Publication status	Published - 1 Oct 2025

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title = "Premixed flame quenching distance between cold walls: Effects of flow and Lewis number",

abstract = "This study investigates the critical conditions for flame propagation in channels with cold walls. We analyse the impact of the Lewis number and flow amplitude (𝐴) on the minimum channel width required to sustain a premixed flame. Our results span a wide range of Lewis numbers, encompassing both aiding and opposing flow conditions. Results are presented for both variable and constant density models. A combined numerical approach, involving stationary and time-dependent simulations, is employed to determine quenching distances and solution stability. We find that smaller Lewis numbers and aiding flows (𝐴 < 0) facilitate flame propagation in narrower channels, while opposing flows (𝐴 > 0) tend to destabilise the flame, promoting asymmetric solutions. For sufficiently large positive values of 𝐴, the quenching distance is determined by asymmetric solutions, rather than the typical symmetric ones.",

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T1 - Premixed flame quenching distance between cold walls: Effects of flow and Lewis number

AU - Kelly, Aiden

AU - Daou, Rémi

AU - Daou, Joel

AU - Kurdyumov, Vadim N.

AU - Rajamanickam, Prabakaran

PY - 2025/10/1

Y1 - 2025/10/1

N2 - This study investigates the critical conditions for flame propagation in channels with cold walls. We analyse the impact of the Lewis number and flow amplitude (𝐴) on the minimum channel width required to sustain a premixed flame. Our results span a wide range of Lewis numbers, encompassing both aiding and opposing flow conditions. Results are presented for both variable and constant density models. A combined numerical approach, involving stationary and time-dependent simulations, is employed to determine quenching distances and solution stability. We find that smaller Lewis numbers and aiding flows (𝐴 < 0) facilitate flame propagation in narrower channels, while opposing flows (𝐴 > 0) tend to destabilise the flame, promoting asymmetric solutions. For sufficiently large positive values of 𝐴, the quenching distance is determined by asymmetric solutions, rather than the typical symmetric ones.

AB - This study investigates the critical conditions for flame propagation in channels with cold walls. We analyse the impact of the Lewis number and flow amplitude (𝐴) on the minimum channel width required to sustain a premixed flame. Our results span a wide range of Lewis numbers, encompassing both aiding and opposing flow conditions. Results are presented for both variable and constant density models. A combined numerical approach, involving stationary and time-dependent simulations, is employed to determine quenching distances and solution stability. We find that smaller Lewis numbers and aiding flows (𝐴 < 0) facilitate flame propagation in narrower channels, while opposing flows (𝐴 > 0) tend to destabilise the flame, promoting asymmetric solutions. For sufficiently large positive values of 𝐴, the quenching distance is determined by asymmetric solutions, rather than the typical symmetric ones.

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DO - 10.1016/j.proci.2025.105836

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JO - PROCEEDINGS OF THE COMBUSTION INSTITUTE

JF - PROCEEDINGS OF THE COMBUSTION INSTITUTE

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Premixed flame quenching distance between cold walls: Effects of flow and Lewis number

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