Volatile tracer dispersion in multi-phase packed beds

“…High temperatures and a nonpolar reaction medium make identification of a suitable tracer difficult. While volatile tracers have been utilized for small scale RTD analysis, 26 partitioning of the tracer between the gas and liquid phase complicates analysis. Squalane, a heavy C 30 hydrocarbon, was considered to be a nonvolatile and thus useful probe for the liquid phase RTD.…”

“…With those assumptions, the plug flow reactor mass balances take the form similar to a reactive distillation model. 26 Liquid phase:…”

“…(See the Supporting Information for further details). With those assumptions, the plug flow reactor mass balances take the form similar to a reactive distillation model Liquid phase: U l φ normald C A , l normald z = prefix− k C A , l C B , l + false( k a false) g l ( 1 H d , A C A , g − C A , l ) U l φ normald C B , l normald z = prefix− k C A , l C B , l + false( k a false) g l ( 1 H d , B C B , g − C B , l ) Vapor phase: …”

Continuous Thermal Oxidation of Alkenes with Nitrous Oxide in a Packed Bed Reactor

“…High temperatures and a nonpolar reaction medium make identification of a suitable tracer difficult. While volatile tracers have been utilized for small scale RTD analysis, 26 partitioning of the tracer between the gas and liquid phase complicates analysis. Squalane, a heavy C 30 hydrocarbon, was considered to be a nonvolatile and thus useful probe for the liquid phase RTD.…”

“…With those assumptions, the plug flow reactor mass balances take the form similar to a reactive distillation model. 26 Liquid phase:…”

“…(See the Supporting Information for further details). With those assumptions, the plug flow reactor mass balances take the form similar to a reactive distillation model Liquid phase: U l φ normald C A , l normald z = prefix− k C A , l C B , l + false( k a false) g l ( 1 H d , A C A , g − C A , l ) U l φ normald C B , l normald z = prefix− k C A , l C B , l + false( k a false) g l ( 1 H d , B C B , g − C B , l ) Vapor phase: …”

Continuous Thermal Oxidation of Alkenes with Nitrous Oxide in a Packed Bed Reactor

“…45 At the same time, the channelling effect of gas within the micro-packed bed can lead to a serious by-passing of volatile species within the liquid medium. 46 Fig. 5b corresponds to micro-fluidic design 1 with a five times larger PEG-flow-rate in the 5.5 mm-width bed.…”

Tailoring the multiphase flow pattern of gas and liquid through micro-packed bed of pillars

“…Another option is to scale microreactors up to the range of milli-reactors (with reactor inner diameters in the order of tens of millimeters) . In both cases, when the catalyst particles are smaller than ∼500 μm, the hydrodynamics are usually dominated by viscous stress and interfacial tension at the liquid–gas boundary rather than by gravity and inertial forces. , Larger scale packed-bed reactors in which the catalyst pellets are about 1–3 mm, generally known as trickle-bed reactors, have semiempirical equations that are commonly used for design purposes . However, the inherent packing randomness combined with the strong capillary and viscous forces in micropacked-bed reactors preclude the use of simple and accurate modeling equations to predict mass-transfer coefficients under different conditions.…”

Modeling Pore-Scale Two-Phase Flow: How to Avoid Gas-Channeling Phenomena in Micropacked-Bed Reactors via Catalyst Wettability Modification