Macromol. React. Eng. 6/2020

Touloupidis, Vasileios; Rittenschober, Gerold; Paulik, Christian

doi:10.1002/mren.202070011

Cited by 7 publications

(35 citation statements)

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“…The catalyst reactivity (in this case, described by its propagation parameter) [ 3 ] guides the particle growth rate. Nevertheless, monomer diffusion potential (via open pores and polymer) will further define the available local amount of monomer that reaches the active site.…”

Section: Resultsmentioning

confidence: 99%

Single Particle Growth, Fragmentation and Morphology Modelling: A DEM Approach

Soleimani

Aigner

Touloupidis

2022

Macro Reaction Engineering

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In this work, the development of a 3D discrete element method (DEM) modeling concept and application that can describe and explain the catalyst particle growth and fragmentation mechanism and follow the morphology developments is presented. The proposed unified modeling methodology is able to predict the expected particle morphology in terms of exact shape, size, and porosity, taking into account the major contributing effects, including reaction kinetics, thermodynamics as well as mechanical considerations. The developed DEM model is validated based on indicative particle morphology patterns as captured experimentally via the SEM technique, managing to qualitatively predict the observed particle morphology. These results indicate the potential of DEM approach in polymer reaction engineering (PRE), expanding the simulation capabilities and range of application.

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Section: Resultsmentioning

confidence: 99%

Single Particle Growth, Fragmentation and Morphology Modelling: A DEM Approach

Soleimani

Aigner

Touloupidis

2022

Macro Reaction Engineering

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“…In general, the ZN catalysts are multi‐sites, which leads to the production of polyolefins with broad MWD. Typically, these catalysts are said to contain between three and six sites, [ 51,58–60 ] where each site has its own set of kinetic parameters, leading to different reaction rates and properties (e.g., chain length and comonomer fraction in the polymer). [ 61,62 ]…”

Section: Mathematical Modelling Of Multizone Gas Phase Pp Reactorsmentioning

confidence: 99%

“…In general, the ZN catalysts are multi-sites, which leads to the production of polyolefins with broad MWD. Typically, these catalysts are said to contain between three and six sites, [51,[58][59][60] where each site has its own set of kinetic parameters, leading to different reaction rates and properties (e.g., chain length and comonomer fraction in the polymer). [61,62] Good overviews of the possible kinetic schemes in olefin polymerizations in slurry and gas phase ZN catalysts are given by Touloupidis [11] and Thakur et al [62] The elimination of some elementary steps is typically made to simplify the development of the kinetic model while retaining the ability to accurately estimate the overall polymerization rate and polymer average molecular weight.…”

Section: Microscale: Molecular Levelmentioning

confidence: 99%

Multiscale modelling of multizone gas phase propylene (co)polymerization reactors—A comprehensive review

et al. 2022

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Catalysts and polymerization processes have evolved over the years. Such significant developments have allowed producers to broaden the range of polymer microstructure and process productivity, thereby making it possible to offer a wide range of end-use properties at a reasonably low cost. However, these advantages in catalyst performance and reactor operation require that we understand as much as possible about reactor operation in the broadest sense. In addition to the fundamental experimental study of polymer chemistry, this means that one needs to develop complete, robust process models. The present paper provides a rapid overview of recent developments in various gas phase propylene (co)polymerization reactors in use today, concentrating on multizone gas phase polypropylene reactors: i.e.,

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“…35,36 On the other hand, the macroscopic modelling approaches are focusing on the selection of the operation conditions of the reactors to perform optimization studies. 5,[17][18][19][37][38][39][40][41][42][43][44] Two examples of this class of modeling approaches: The Polymer Flow (PF) models are a typical example of modeling aimed to predict the final polymer properties like MWD, CCD and of the reaction rate; 8,45 The Morphology models (MF) based on experimental information, like porometer data, [17][18][19] are used to describe how the fragmentation takes place during the polymerization reaction. 17,40,41,45,46 However, though they can well describe the fragmentation mechanism, they are not predictive "a priori" because experimental morphology information are needed at different stages of the process.…”

Section: Introductionmentioning

confidence: 99%