TY - JOUR
T1 - Population Balance Equations for Reactive Separation in Polymer Upcycling
AU - Kim, Changhae Andrew
AU - Sahasrabudhe, Chinmay A.
AU - Wang, Yi Yu
AU - Yappert, Ryan
AU - Heyden, Andreas
AU - Huang, Wenyu
AU - Sadow, Aaron D.
AU - Peters, Baron
N1 - Publisher Copyright:
© 2024 American Chemical Society.
PY - 2024/2/27
Y1 - 2024/2/27
N2 - Many polymer upcycling efforts aim to convert plastic waste into high-value liquid hydrocarbons. However, the subsequent cleavage of middle distillates to light gases can be problematic. The reactor often contains a vapor phase (light gases and middle distillates) and a liquid phase (molten polymers and waxes with a suspended or dissolved catalyst). Because the catalyst resides in the liquid phase, middle distillates that partition into the vapor phase are protected against further cleavage into light gases. In this paper, we consider a simple reactive separation strategy, in which a gas outflow removes the volatile products as they form. We combine vapor-liquid equilibrium models and population balance equations (PBEs) to describe polymer upcycling in a two-phase semibatch reactor. The results suggest that the temperature, headspace volume, and flow rate of the reactor can be used to tune selectivity toward the middle distillates, in addition to the molecular mechanism of catalysis. We anticipate that two-phase reactor models will be important in many polymer upcycling processes and that reactive separation strategies will provide ways to boost the yield of the desired products in these cases.
AB - Many polymer upcycling efforts aim to convert plastic waste into high-value liquid hydrocarbons. However, the subsequent cleavage of middle distillates to light gases can be problematic. The reactor often contains a vapor phase (light gases and middle distillates) and a liquid phase (molten polymers and waxes with a suspended or dissolved catalyst). Because the catalyst resides in the liquid phase, middle distillates that partition into the vapor phase are protected against further cleavage into light gases. In this paper, we consider a simple reactive separation strategy, in which a gas outflow removes the volatile products as they form. We combine vapor-liquid equilibrium models and population balance equations (PBEs) to describe polymer upcycling in a two-phase semibatch reactor. The results suggest that the temperature, headspace volume, and flow rate of the reactor can be used to tune selectivity toward the middle distillates, in addition to the molecular mechanism of catalysis. We anticipate that two-phase reactor models will be important in many polymer upcycling processes and that reactive separation strategies will provide ways to boost the yield of the desired products in these cases.
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U2 - 10.1021/acs.langmuir.3c03004
DO - 10.1021/acs.langmuir.3c03004
M3 - Article
C2 - 38350109
AN - SCOPUS:85185582058
SN - 0743-7463
VL - 40
SP - 4096
EP - 4107
JO - Langmuir
JF - Langmuir
IS - 8
ER -