NOx storage and reduction with propylene on Pt/BaO/alumina

Abstract

An experimental study was carried out of periodically operated NOx (NO + NO~2~) storage and reduction on a model Pt/BaO/Al~2~O~3~ catalyst powder. The effect of the reductant (propylene) injection policy on time‐averaged NOx conversion was evaluated in terms of feed composition and temperature, reductant pulse duration, and overall cycle time. Conditions giving time‐averaged NOx conversions exceeding 90% were identified. The reductant‐to‐oxidant ratio during the injection and the total cycle time are both found to be critical factors to achieve high conversion. The time‐averaged conversion is bounded above and below by the steady‐state conversions obtained with feeds having the same compositions as that during the rich and lean part of the cycle, respectively. For a fixed supply of propylene, short pulses of high concentration are much more effective than longer pulses of reduced concentration. The NOx conversion achieves a maximum value at an intermediate overall cycle time when the propylene pulse of fixed duty fraction is net reducing. High conversions are sustained over a wide temperature window (200–400°C). A simple storage–reduction cycle is proposed that elucidates the main findings in the study. The key factor for high NOx conversion is the temporal production of oxygen‐deficient conditions coupled with high catalyst temperatures, both resulting from the intermittent catalytic oxidation of propylene. © 2004 American Institute of Chemical Engineers AIChE J, 50: 2526–2540, 2004