Oxygen Chemistry in Polymer Fouling: Insights from Multiphase Detailed Kinetic Modeling

Author(s)

Pang, Hao-Wei; Dong, Xiaorui; Green, William H.

Abstract

Polymer fouling is a pervasive challenge in downstream processes of steam cracking. Molecular oxygen is likely to present and known to strongly affect various polymerization processes, yet the role of oxygen in distillation column fouling remains poorly understood. Building upon the foundations laid in our preceding study [Pang et al., Ind. Eng. Chem. Res. 2023, 62, 36, 14266–14285], this work presents a detailed kinetic modeling approach to investigate the impact of oxygen on polymer fouling in a typical debutanizer. The fouling model incorporates molecular oxygen as a primary source of contamination in the feedstock and encompasses a comprehensive network of chemical reactions, phase equilibria, and interphase transport phenomena. Critical model parameters are derived from quantum chemistry calculations to ensure accuracy. The sensitivity of fouling rates to varying levels of dissolved oxygen is examined. We find that even small traces (ppb level) of molecular oxygen contaminant in the feedstock can significantly accelerate fouling growth in the colder section. Furthermore, the dominant pathways of fouling are observed to shift over time due to diffusion limitations. This study showcases the power and adaptability of predictive detailed kinetic modeling in deciphering the mechanistic fundamentals of polymer fouling.

Date issued

2024-01-02

URI

https://hdl.handle.net/1721.1/153422

Department

Massachusetts Institute of Technology. Department of Chemical Engineering

Journal

Industrial & Engineering Chemistry Research

Publisher

American Chemical Society (ACS)

Citation

Hao-Wei Pang, Xiaorui Dong, and William H. Green Industrial & Engineering Chemistry Research 2024 63 (2), 1013-1028.

Version: Author's final manuscript

ISSN

0888-5885

1520-5045

Keywords

Industrial and Manufacturing Engineering, General Chemical Engineering, General Chemistry