Mathematical Model and Parameter Estimation for Gas-Phase Ethylene Homopolymerization with Supported Metallocene Catalyst

A dynamic model for gas-phase ethylene homopolymerization using a supported metallocene catalyst is developed in this work. A single-site model was first developed, with model parameters estimated from measurements from 11 experimental runs in a semibatch laboratory-scale reactor. Estimability analy...

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Veröffentlicht in:	Industrial & engineering chemistry research 2005-04, Vol.44 (8), p.2428-2442
Hauptverfasser:	Kou, Bo, McAuley, Kim B, Hsu, C. C, Bacon, David W, Yao, K. Zhen
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Sprache:	eng
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container_title	Industrial & engineering chemistry research
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creator	Kou, Bo McAuley, Kim B Hsu, C. C Bacon, David W Yao, K. Zhen
description	A dynamic model for gas-phase ethylene homopolymerization using a supported metallocene catalyst is developed in this work. A single-site model was first developed, with model parameters estimated from measurements from 11 experimental runs in a semibatch laboratory-scale reactor. Estimability analysis techniques were applied to aid in the parameter estimation. Although the single-site model provided good fits for both the polymerization rate and hydrogen concentration, it failed to accurately predict the molecular weight data and its distribution. Sequentially, a simplified two-site model was built to improve model predictions. The two-site model, which used three additional parameters, showed significant improvements over the single-site model. The two-site model was validated using the data from two extra experimental runs, which were not employed in the parameter estimation process. Most of the model predictions fall within the 95% confidence intervals of the experimental data.
doi_str_mv	10.1021/ie048957o
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title	Mathematical Model and Parameter Estimation for Gas-Phase Ethylene Homopolymerization with Supported Metallocene Catalyst
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