TY - JOUR
T1 - Improved and generalized criteria for the instantaneous regime for multiple parallel Gas-Liquid reactions
AU - Janssens, Pieter
AU - Poissonnier, Jeroen
AU - Thybaut, Joris W.
AU - van Swaaij, Wim P.M.
AU - Bos, René
N1 - Funding Information:
P.J. thanks Javier Ibáñez Abad (EnginZyme) for the valuable discussions related to the numerical solution strategies. R.B. thanks Tim Nisbet (Shell) for inspiring discussions during discovery of the old criteria breakdown.
Publisher Copyright:
© 2023 Elsevier B.V.
PY - 2023/6/1
Y1 - 2023/6/1
N2 - The classic criteria to determine if a second-order irreversible gas–liquid reaction (AG+νBBL→νCCL) proceeds in the instantaneous regime are based on the Hatta number, HaA, and the infinite enhancement factor, EA,∞, i.e., HaA>2 and HaA≫EA,∞-1. There is no consensus, however, with respect to the latter threshold value and this work shows that it highly depends on the considered reactant concentrations and rate coefficients, in particular when the non-volatility assumption of the liquid phase component is relieved. Generalizing the original derivation yields an extended expression, which is condensed into a new dimensionless number, φA,∞, and allows to rewrite the second criterion as φA,∞>15, where [Formula presented]. Next, it is demonstrated that a breakthrough of the gas-phase reactant into the bulk-liquid is readily observed at high interface concentrations of the gas-phase reactant with respect to the bulk concentration of the liquid-phase reactant, even though the classic criteria have been met. Such a situation is quite common in the chemical industry, e.g., in case of the selective reactive removal of an impurity (BL) from a process stream containing a valuable product by a soluble gaseous component (AG). The root cause of this deviating behavior results from the position of the reaction plane and an additional criterion, φB,∞>15, is needed to resolve this. As such, the set of improved criteria are necessary and sufficient to describe the instantaneous regime for any position of the reaction plane. To conclude, a methodology is presented to apply the modified criteria to multiple parallel reactions, and the validity of these improved and generalized criteria is numerically demonstrated.
AB - The classic criteria to determine if a second-order irreversible gas–liquid reaction (AG+νBBL→νCCL) proceeds in the instantaneous regime are based on the Hatta number, HaA, and the infinite enhancement factor, EA,∞, i.e., HaA>2 and HaA≫EA,∞-1. There is no consensus, however, with respect to the latter threshold value and this work shows that it highly depends on the considered reactant concentrations and rate coefficients, in particular when the non-volatility assumption of the liquid phase component is relieved. Generalizing the original derivation yields an extended expression, which is condensed into a new dimensionless number, φA,∞, and allows to rewrite the second criterion as φA,∞>15, where [Formula presented]. Next, it is demonstrated that a breakthrough of the gas-phase reactant into the bulk-liquid is readily observed at high interface concentrations of the gas-phase reactant with respect to the bulk concentration of the liquid-phase reactant, even though the classic criteria have been met. Such a situation is quite common in the chemical industry, e.g., in case of the selective reactive removal of an impurity (BL) from a process stream containing a valuable product by a soluble gaseous component (AG). The root cause of this deviating behavior results from the position of the reaction plane and an additional criterion, φB,∞>15, is needed to resolve this. As such, the set of improved criteria are necessary and sufficient to describe the instantaneous regime for any position of the reaction plane. To conclude, a methodology is presented to apply the modified criteria to multiple parallel reactions, and the validity of these improved and generalized criteria is numerically demonstrated.
KW - Enhancement factor
KW - Gas-Liquid mass transfer
KW - Hatta number
KW - Instantaneous reaction
KW - n/a OA procedure
UR - http://www.scopus.com/inward/record.url?scp=85152746519&partnerID=8YFLogxK
U2 - 10.1016/j.cej.2023.142744
DO - 10.1016/j.cej.2023.142744
M3 - Article
AN - SCOPUS:85152746519
SN - 1385-8947
VL - 465
JO - Chemical Engineering Journal
JF - Chemical Engineering Journal
M1 - 142744
ER -