Methane partial oxidation reverse flow reactor scale up and optimization

Estimation of methane partial oxidation reciprocal flow filtration combustion reactor performance in the case of its scale up (flow rates G = 4, 40, 400 and 4000 Nm3/h) as well as parametric study of the bigger scale reactor is performed numerically. It is shown that residence time growth with reactor scale up is compensated with maximum temperature decrease. Reduced aspect ratio reactors are considered for higher productivity systems. tric study performed for G = 400 Nm3/h reduced aspect ratio reactor show: Φ = 2.7 equivalence ratio is optimal to maximize conversion ratio and H2 output concentration; smaller porous media particle d0 = 2–3 mm should be used for lower specific mass flow rates Gm = 0.5–1 kg/m2/s and bigger particles – for higher Gm; porosity variation m = 0.4–0.55 does not influence conversion ratio; kaowool insulation layer increase from 3 to 10 cm results in ∼1% growth of conversion ratio while further increase up to 50 cm provides less than 0.5% gain. sults may be utilized for bigger scale reactors design, optimization and exploitation.