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3D‐Structured Monoliths of Nanoporous Polymers by Additive Manufacturing

Hock, Sebastian / Rose, Marcus

Recent advances in 3D printing provide great opportunities for the utilization of functional materials in chemical engineering and heterogeneous catalysis. In this work cylindrical monoliths with varying geometries of transport channels are designed and printed by a fused deposition modeling (FDM) 3D printer from thermoplastic polymers. Their hydrodynamic characteristics are investigated. For a proof of concept composite monoliths of microporous hyper‐crosslinked polymers (HCP) are printed. They contain up to 40 wt % of HCP with an accessible specific surface area of up to 171 m²g⁻¹.

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3D‐Structured Monoliths of Nanoporous Polymers by Additive Manufacturing

Hock, Sebastian / Rose, Marcus

Recent advances in 3D printing provide great opportunities for the utilization of functional materials in chemical engineering and heterogeneous catalysis. In this work cylindrical monoliths with varying geometries of transport channels are designed and printed by a fused deposition modeling (FDM) 3D printer from thermoplastic polymers. Their hydrodynamic characteristics are investigated. For a proof of concept composite monoliths of microporous hyper‐crosslinked polymers (HCP) are printed. They contain up to 40 wt % of HCP with an accessible specific surface area of up to 171 m²g⁻¹.

3D‐Structured Monoliths of Nanoporous Polymers by Additive Manufacturing

Hock, Sebastian / Rose, Marcus

Recent advances in 3D printing provide great opportunities for the utilization of functional materials in chemical engineering and heterogeneous catalysis. In this work cylindrical monoliths with varying geometries of transport channels are designed and printed by a fused deposition modeling (FDM) 3D printer from thermoplastic polymers. Their hydrodynamic characteristics are investigated. For a proof of concept composite monoliths of microporous hyper‐crosslinked polymers (HCP) are printed. They contain up to 40 wt % of HCP with an accessible specific surface area of up to 171 m²g⁻¹.

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Title:

3D‐Structured Monoliths of Nanoporous Polymers by Additive Manufacturing

Contributors:

Hock, Sebastian (author) / Rose, Marcus (author)

Published in:

Chemie Ingenieur Technik ; 92 ; 525-531

Publication date:

2020-05-01

Size:

7 pages

ISSN:

0009-286X , 1522-2640

DOI:

https://doi.org/10.1002/cite.201900149

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

English

Keywords:

3D printing , Hydrodynamic properties , Monolith , Porous polymer , Hierarchical porosity

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