Experimental Study on the Basic Phenomena of Flame Stabilization Mechanism in a Porous Burner for Premixed Combustion Application

Djordjevic, Neda; Habisreuther, Peter; Zarzalis, Nikolaos

doi:10.1021/ef3013008

Cited by 13 publications

(8 citation statements)

References 38 publications

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“…The first one is an atmospheric burner with a cylindrical PIM ( Fig. 2.a) [47]. The second one is confined and can operate at pressure levels up to 20 bar.…”

Section: Experimental Test Rigs and Proceduresmentioning

confidence: 99%

Experimental study, 1D volume-averaged calculations and 3D direct pore level simulations of the flame stabilization in porous inert media at elevated pressure

Bedoya

Dinkov

Habisreuther

et al. 2015

Combustion and Flame

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“…The first one is an atmospheric burner with a cylindrical PIM ( Fig. 2.a) [47]. The second one is confined and can operate at pressure levels up to 20 bar.…”

Section: Experimental Test Rigs and Proceduresmentioning

confidence: 99%

Experimental study, 1D volume-averaged calculations and 3D direct pore level simulations of the flame stabilization in porous inert media at elevated pressure

Bedoya

Dinkov

Habisreuther

et al. 2015

Combustion and Flame

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“… 18 Excellent thermal properties of a porous ceramic foam enable combustion of premixed low calorific fuels that would not be otherwise possible. 19 , 20 At present, the use of porous burners can be found in several engineering applications. 21 , 22 These include propulsion and gas turbine systems, 23 , 24 heat exchangers, 25 and chemical processing.…”

Section: Introductionmentioning

confidence: 99%

On the Response of Ultralean Combustion of CH₄/H₂ Blends in a Porous Burner to Fluctuations in Fuel Flow—an Experimental Investigation

et al. 2021

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Fluctuations in the fuel flow rate may occur in practical combustion systems and result in flame destabilization. This is particularly problematic in lean and ultralean modes of burner operation. In this study, the response of a ceramic porous burner to fluctuations in the flow rate of different blends of methane and hydrogen is investigated experimentally. Prior to injection into the porous burner, the fuel blend is premixed with air at equivalence ratios below 0.275. The fuel streams are measured and controlled separately by programmable mass flow controllers, which impose sinusoidal fluctuations on the flow rates. To replicate realistic fluctuations in the fuel flow rate, the period of oscillations is chosen to be on the order of minutes. The temperature inside the ceramic foam is measured using five thermocouples located at the center of the working section of the burner. The flame embedded in porous media is imaged while the fuel flow is modulated. Analysis of the flame pictures and temperature traces shows that the forced oscillation of the fuel mixture leads to flame movement within the burner. This movement is found to act in accordance with the fluctuations in methane and hydrogen flows for both CH 4 (90%)–H 2 (10%) and CH 4 (70%)–H 2 (30%) mixtures. However, both fuel mixtures are noted to be rather insensitive to hydrogen flow fluctuation with a modulation amplitude below 30% of the steady flow. For the CH 4 (70%)–H 2 (30%) mixture, the flame in the porous medium can be modulated by fluctuations between 0 and 30% of steady methane flow without any noticeable flame destabilization.

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“…Various experimental and numerical investigations examined the effects of geometrical and thermophysical properties of porous matrix on flame characteristics in the porous burner. 19–24…”

Section: Introductionmentioning

confidence: 99%

Numerical study on the combustion characteristics in a porous-free flame burner for lean mixtures

Ghorashi

Hashemi

Mollamahdi

2019

Proceedings of the Institution of Mechanical Engineers, Part C:

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The present work implements a numerical simulation to investigate the combustion process in a porous-free flame burner. The non-equilibrium thermal condition is performed, and discretization and solving of the governing equations are conducted in a two-dimensional axisymmetric model. In order to simulate the combustion process, a reduced chemical kinetic mechanism of GRI 3.0, which includes 16 species and 41 reactions, is used. In order to prove the precision of the numerical method, some experimental tests are carried out and the numerical results are in a good agreement with the experimental measurements. The numerical results demonstrate that the porous-free flame burner has a higher flame stability compared to the conventional porous burner and the radiative efficiency of the porous-free flame burner is less than the porous burner. In addition, an increase in thermal conduction of the porous medium leads to an extension in the flame stability. In addition, the results show that with decreasing the pore density of porous medium, the flame stability is extended.

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Experimental Study on the Basic Phenomena of Flame Stabilization Mechanism in a Porous Burner for Premixed Combustion Application

Cited by 13 publications

References 38 publications

Experimental study, 1D volume-averaged calculations and 3D direct pore level simulations of the flame stabilization in porous inert media at elevated pressure

Experimental study, 1D volume-averaged calculations and 3D direct pore level simulations of the flame stabilization in porous inert media at elevated pressure

On the Response of Ultralean Combustion of CH₄/H₂ Blends in a Porous Burner to Fluctuations in Fuel Flow—an Experimental Investigation

Numerical study on the combustion characteristics in a porous-free flame burner for lean mixtures

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Experimental Study on the Basic Phenomena of Flame Stabilization Mechanism in a Porous Burner for Premixed Combustion Application

Cited by 13 publications

References 38 publications

Experimental study, 1D volume-averaged calculations and 3D direct pore level simulations of the flame stabilization in porous inert media at elevated pressure

Experimental study, 1D volume-averaged calculations and 3D direct pore level simulations of the flame stabilization in porous inert media at elevated pressure

On the Response of Ultralean Combustion of CH4/H2 Blends in a Porous Burner to Fluctuations in Fuel Flow—an Experimental Investigation

Numerical study on the combustion characteristics in a porous-free flame burner for lean mixtures

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On the Response of Ultralean Combustion of CH₄/H₂ Blends in a Porous Burner to Fluctuations in Fuel Flow—an Experimental Investigation