Unsteady ultra-lean combustion of methane and biogas in a porous burner – An experimental study
Unsteady ultra-lean combustion of methane and biogas in a porous burner – An experimental study
The response of ultra-lean flames, stabilised in a porous burner, to the fluctuations imposed on the fuel flow rate is investigated experimentally. The study is motivated by the likelihood of small biogas generators to produce fuels with temporal variations in their flow rate and chemical composition. The employed porous burner includes layers of silicon carbide porous foam placed inside a quartz tube. The burner is equipped with a series of axially arranged thermocouples and is imaged by a digital camera. Methane and a blend of methane and carbon dioxide (mimicking biogas) are mixed with air and then fed to the burner at equivalence ratios below 0.3. The fuel flow rate is modulated with a programmable mass flow controller by imposing a sinusoidal wave with variable amplitude and frequency on the steady fuel flow. Through analysis of the flame images and collected temperature traces, it is shown that the imposed disturbances result in motion of the flame inside the burner. Such motion is found to qualitatively follow the temporal variation in the fuel flow for both methane and biogas. Nonetheless, the amplitude of the flame oscillations for methane is found to be higher than that for biogas. Further, it is observed that exposure of the burner to the fuel fluctuations for a long time (180 s) eventually results in flame destabilisation. However, stabilised combustion was achieved for methane mixtures at amplitudes between 0 and 30% of steady values over a period of 60 s. This study reveals the strong effects of unsteady heat transfer in porous media upon the fluctuations in flame position.
Habib, Rabeeah
4a0a29f8-dcfe-4002-b369-d534c4e63985
Yadollahi, Bijan
76b7347b-00ec-482c-863f-9e6a60b1815b
Saeed, Ali
d21accb0-c60c-4375-9117-2e44096048d1
Doranehgard, Mohammad Hossein
93bdb781-6a63-47fb-b201-3009c95b4642
Li, Larry K.B.
af5dec8b-bef0-4e46-a1a6-e26a7d05de38
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
5 January 2021
Habib, Rabeeah
4a0a29f8-dcfe-4002-b369-d534c4e63985
Yadollahi, Bijan
76b7347b-00ec-482c-863f-9e6a60b1815b
Saeed, Ali
d21accb0-c60c-4375-9117-2e44096048d1
Doranehgard, Mohammad Hossein
93bdb781-6a63-47fb-b201-3009c95b4642
Li, Larry K.B.
af5dec8b-bef0-4e46-a1a6-e26a7d05de38
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Habib, Rabeeah, Yadollahi, Bijan, Saeed, Ali, Doranehgard, Mohammad Hossein, Li, Larry K.B. and Karimi, Nader
(2021)
Unsteady ultra-lean combustion of methane and biogas in a porous burner – An experimental study.
Applied Thermal Engineering, 182, [116099].
(doi:10.1016/j.applthermaleng.2020.116099).
Abstract
The response of ultra-lean flames, stabilised in a porous burner, to the fluctuations imposed on the fuel flow rate is investigated experimentally. The study is motivated by the likelihood of small biogas generators to produce fuels with temporal variations in their flow rate and chemical composition. The employed porous burner includes layers of silicon carbide porous foam placed inside a quartz tube. The burner is equipped with a series of axially arranged thermocouples and is imaged by a digital camera. Methane and a blend of methane and carbon dioxide (mimicking biogas) are mixed with air and then fed to the burner at equivalence ratios below 0.3. The fuel flow rate is modulated with a programmable mass flow controller by imposing a sinusoidal wave with variable amplitude and frequency on the steady fuel flow. Through analysis of the flame images and collected temperature traces, it is shown that the imposed disturbances result in motion of the flame inside the burner. Such motion is found to qualitatively follow the temporal variation in the fuel flow for both methane and biogas. Nonetheless, the amplitude of the flame oscillations for methane is found to be higher than that for biogas. Further, it is observed that exposure of the burner to the fuel fluctuations for a long time (180 s) eventually results in flame destabilisation. However, stabilised combustion was achieved for methane mixtures at amplitudes between 0 and 30% of steady values over a period of 60 s. This study reveals the strong effects of unsteady heat transfer in porous media upon the fluctuations in flame position.
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Published date: 5 January 2021
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Local EPrints ID: 509187
URI: http://eprints.soton.ac.uk/id/eprint/509187
ISSN: 1359-4311
PURE UUID: 925147d0-d410-4c3f-929a-be74d34a9871
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Date deposited: 12 Feb 2026 17:46
Last modified: 13 Feb 2026 03:16
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Contributors
Author:
Rabeeah Habib
Author:
Bijan Yadollahi
Author:
Ali Saeed
Author:
Mohammad Hossein Doranehgard
Author:
Larry K.B. Li
Author:
Nader Karimi
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