Effect of different wall materials and thermal-barrier coatings on the flame-wall interaction of laminar premixed methane and propane flames

•Quenching distance strongly depends on stoichiometry and fuel.•Quenching distances decrease with increasing thickness of coatings.•Wall materials with higher thermal conductivity have no effect on FWI.•Scaling laws hold for different wall materials and coatings.•OH* exists much closer to the wall t...

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Bibliographic Details
Published in:The International journal of heat and fluid flow 2018-02, Vol.69, p.95-105
Main Authors: Häber, Thomas, Suntz, Rainer
Format: Article
Language:English
Subjects:
Ceramics
Chemiluminescence
Flame-wall interaction
Quenching distance
Soot
Thermal-barrier coatings
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Summary:•Quenching distance strongly depends on stoichiometry and fuel.•Quenching distances decrease with increasing thickness of coatings.•Wall materials with higher thermal conductivity have no effect on FWI.•Scaling laws hold for different wall materials and coatings.•OH* exists much closer to the wall than CH*. We investigate the flame-wall interaction of laminar, premixed methane/air and propane/air flames in a stationary, sidewall-quenching configuration over a wide range of equivalence ratios. Both, the wall material (stainless-steel, cast iron, aluminum), the type of thermal-barrier coating (soot, zirconium dioxide, titanium dioxide) and its thickness (only for zirconium dioxide) were systematically varied. The flame-wall interaction is characterized by the measurement of quenching distances, which are based on the separate analysis of chemiluminescence images of electronically excited OH* and CH* radicals. A method has been developed to determine the position of the wall in the chemiluminescence images with sub-pixel accuracy. It turns out, that while the quenching distance strongly changes with stoichiometry and fuel, it only weakly depends on the wall material and type of coating, although the quenching distance tends to decreases with increasing thickness of the ceramic coating. Overall, the data confirms present scaling laws with a quenching Peclet number of PeQ ≈ 7.5. Quenching distances determined independently for OH* and CH* differ more strongly than the distances of peak mole fractions in an undisturbed flame, without the influence of the wall.
ISSN:0142-727X
1879-2278
DOI:10.1016/j.ijheatfluidflow.2017.12.004