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Multi-objective optimization of ANN-based vacuum pressure swing adsorption process for ethane and ethylene separation

Authors
Lim, Myung KyunYun, Ji SubCho, Kyung HoYoon, Ji WoongLee, U-HwangFerreira, AlexandreMafalda Ribeiro, AnaNogueira, Idelfonso B.R.Park, JaedeukKim, Jin-KukKim, Kiwoong
Issue Date
Mar-2025
Publisher
한국공업화학회
Keywords
Adsorption; Artificial neural networks; Energy consumption; Particle swarm optimization
Citation
Journal of Industrial and Engineering Chemistry, v.143, pp 221 - 239
Pages
19
Indexed
SCIE
SCOPUS
KCI
Journal Title
Journal of Industrial and Engineering Chemistry
Volume
143
Start Page
221
End Page
239
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/212601
DOI
10.1016/j.jiec.2024.08.025
ISSN
1226-086X
1876-794X
Abstract
A bilevel optimization methodology was developed for separating ethane and ethylene using vacuum pressure swing adsorption. Data generated through Latin hypercube sampling and normalization were employed to construct a neural network at a lower level, serving as a surrogate model for the comprehensive first-principle adsorption process. Following sensitivity analysis based on Monte Carlo simulation, optimization, data resampling, and reconciliation were performed at an upper level. Two cases were performed to optimize the ethane and ethylene separation process. In the first scenario, ethylene recovery was optimized under a purity constraint, resulting in an enhancement from 65.28 % to 87.19 %. In the second scenario, both ethylene recovery and energy consumption were simultaneously optimized with the purity constraint, leading to the generation of a Pareto front. From this Pareto front, two operating conditions were determined: one using TOPSIS and the other aimed at reducing energy consumption from a conventional distillation column to 0.733 MJ/kg-ethylene. Compared to conventional distillation, the vacuum pressure swing adsorption (VPSA) process showed 82.8 % recovery with 0.747 MJ/kg-ethylene and 72.21 % recovery with 0.683 MJ/kg-ethylene. A dynamic analysis and an economic analysis of scaling up VPSA process were performed to compare with C2 splitter.
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