Use of a µ-Scale Synthetic Gas Bench for Direct Comparison of Urea-SCR and NH3-SCR Reactions over an Oxide Based Powdered Catalyst

Abstract: Abstract:The selective catalytic reduction (SCR) of NOx by NH3 has been extensively studied in the literature, mainly because of its high potential to remediate the pollution of diesel exhaust gases. The implementation of the NH3-SCR process into passenger cars requires the use of an ammonia precursor, provided by a urea aqueous solution in the conventional process. Although the thermal decomposition and hydrolysis mechanisms of urea are well documented in the literature, the influence of the direct use of ure… Show more

“…Note also that without catalyst, no evolution of the gas composition was recorded during the SCR experiments, whatever the studied temperature. 3 The studied catalyst, denoted aZr, was provided by Solvay. This material was developed for the urea-SCR process for vehicles equipped with a Diesel particulate filter (DPF).…”

“…Supplementary tests were also performed with the addition of 150 mg ZrO2 (Solvay) upstream the SCR catalyst. ZrO2 addition was demonstrated to allow the recovery of the activity in standard SCR condition (NO2/NOx = 0), 3 due to its catalytic activity in HNCO hydrolysis. 10…”

“…In order to evaluate powdered catalysts using the "real" reaction mixture, an innovative laboratory bench adapted to powdered catalysts (100 mg) was developed, allowing the use of NH3 or urea (aqueous solution) as NOx reductant specis. 3 The urea residence time between the injection zone and the catalytic bed is a key parameter of the deNOx efficiency. For short urea residence time, a significant decrease of the NOx reduction efficiency was observed over a prototype SCR catalyst provided by Solvay, when switching from gaseous NH3 to urea aqueous solution, especially in "standard-SCR" condition.…”

“…They showed that the decrease in NOx reduction with urea can be attributed to a lack in NH3 availability due to limitations in HNCO hydrolysis. 3 Then, it was assumed that HNCO is largely present at the catalyst surface for the shorter urea residence time, even if traces of urea cannot be excluded.…”

Study of the remarkable reactivity of HNCO/urea with NO₂ in the NO_x SCR by urea process over an oxide-based catalyst

“…Note also that without catalyst, no evolution of the gas composition was recorded during the SCR experiments, whatever the studied temperature. 3 The studied catalyst, denoted aZr, was provided by Solvay. This material was developed for the urea-SCR process for vehicles equipped with a Diesel particulate filter (DPF).…”

“…Supplementary tests were also performed with the addition of 150 mg ZrO2 (Solvay) upstream the SCR catalyst. ZrO2 addition was demonstrated to allow the recovery of the activity in standard SCR condition (NO2/NOx = 0), 3 due to its catalytic activity in HNCO hydrolysis. 10…”

“…In order to evaluate powdered catalysts using the "real" reaction mixture, an innovative laboratory bench adapted to powdered catalysts (100 mg) was developed, allowing the use of NH3 or urea (aqueous solution) as NOx reductant specis. 3 The urea residence time between the injection zone and the catalytic bed is a key parameter of the deNOx efficiency. For short urea residence time, a significant decrease of the NOx reduction efficiency was observed over a prototype SCR catalyst provided by Solvay, when switching from gaseous NH3 to urea aqueous solution, especially in "standard-SCR" condition.…”

“…They showed that the decrease in NOx reduction with urea can be attributed to a lack in NH3 availability due to limitations in HNCO hydrolysis. 3 Then, it was assumed that HNCO is largely present at the catalyst surface for the shorter urea residence time, even if traces of urea cannot be excluded.…”

Study of the remarkable reactivity of HNCO/urea with NO₂ in the NO_x SCR by urea process over an oxide-based catalyst

“…This arrangement, however, results in additional complexities in designing catalytic systems to ensure efficient urea decomposition and hydrolysis into NH 3 molecules. Based on the results obtained from well-controlled micro-scale reactor experiments, Seneque et al describe potential limitations of urea as an NH 3 carrier when urea residence time is not sufficient [8]. They further show that the observed lack of NH 3 availability can be attributed to the insufficient SCR catalyst activity for isocyanic acid (HNCO: urea decomposition product) hydrolysis, which can be complemented by adding an active hydrolysis catalyst (e.g., ZrO 2 ) upstream of the SCR catalyst.…”

Automotive Emission Control Catalysts

Transition metal oxides for combustion and depollution processes