2016
DOI: 10.3390/en9090738
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Deformation Study of Lean Methane-Air Premixed Spherically Expanding Flames under a Negative Direct Current Electric Field

Abstract: This paper compares numerical simulations with experiments to study the deformation of lean premixed spherically expanding flames under a negative direct current (DC) electric field. The experiments, including the flame deformation and the ionic distribution on the flame surface were investigated in a mesh to mesh electric field. Besides, a numerical model of adding an electric body force to the positive ions on the flame surface was also established to perform a relevant simulation. Results show that the sphe… Show more

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Cited by 7 publications
(2 citation statements)
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“…The interaction between the electric field and the flame also worked in the premixed flame. Li [26] and Fang [27] investigated the effect of electric field on methane-air mixture premix flame experimentally. The deformation process of the spherically expanding premixed flame was observed, and the application of an electric field commonly promotes flame propagation and increases the heat release rate.…”
Section: Introductionmentioning
confidence: 99%
“…The interaction between the electric field and the flame also worked in the premixed flame. Li [26] and Fang [27] investigated the effect of electric field on methane-air mixture premix flame experimentally. The deformation process of the spherically expanding premixed flame was observed, and the application of an electric field commonly promotes flame propagation and increases the heat release rate.…”
Section: Introductionmentioning
confidence: 99%
“…This mechanism could also contribute to a controlled growth and aggregation of nano-particles in flame synthesis described in Section 2.3. Many fundamental experiments using lab-scale burners have been carried out for studying electric field enhanced combustion using premixed (see, e.g., [22][23][24][25][26][27][28][29][30]) and non-premixed flames [31,32]. Attempts for a technical application at higher thermal load were conducted by Weinberg et al for a meso-scale burner [33], by Sakhrieh et al for a Bunsen flame array [34] and Altendorfner et al [35] for a swirl flame that is usually applied in gas-turbine burners.…”
Section: Electric Field Assisted Combustionmentioning
confidence: 99%