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01.06.2014 | Original Paper

Ultra-lightweight paper foams: processing and properties

verfasst von: A. Madani, S. Zeinoddini, S. Varahmi, H. Turnbull, A. B. Phillion, J. A. Olson, D. M. Martinez

Erschienen in: Cellulose | Ausgabe 3/2014

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Abstract

A methodology for producing a low density cellulose-based foam has been developed by combining a surfactant with pulp, mixing at high velocity to entrain air, and then drying in a non-restrained fashion. The structure of the foam, characterized through optical microscopy and X-ray computed tomographic microscopy, consists of pulp fibres in random orientations surrounding air bubbles along with large void spaces. Through careful design of experiments, the effect of fibre type, length distribution, surfactant, and air content on the mechanical behavior and permeability of the foam material was investigated. The results indicate that foamed cellulose materials can be produced at a strength of one-half the tensile strength of a standard handsheet, but having a relative density of only one percent. No chemical additives were used to enhance the strength of these samples as the properties of the foam material are enhanced simply through variation of the process parameters. Thus, a strong cellulose-based foam, with a density as low as 10 mg/cm³, can be fabricated using standard papermaking infrastructure and hence at low cost.

Vorheriger Artikel Dissolving-grade birch pulps produced under various prehydrolysis intensities: quality, structure and applications

Nächster Artikel Switchable water absorption of paper via liquid flame spray nanoparticle coating

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Two other surfactants were also tested. \(\hbox{Ammonyx}^{\circledR}\)LO (cationic) performed similarily to Bioterge, while \(\hbox{Toximul}^{\circledR}\)SEE-340 (nonionic), did not produce bubbles suitable for foaming of paper.

Like Blomqvist et al. (2008), no significant difference in foam was obtained when the initial concentration of the pulp was varied between 0.25–1 wt% except that more energy was needed to bring the solution to the required air content.

This value corresponds to the density of cellulose. We assume that this value also represents the density of the papermaking fibre cell walls that may include cracks, pores, and chemical constituents other than cellulose.

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Titel: Ultra-lightweight paper foams: processing and properties
verfasst von: A. Madani
S. Zeinoddini
S. Varahmi
H. Turnbull
A. B. Phillion
J. A. Olson
D. M. Martinez
Publikationsdatum: 01.06.2014
Verlag: Springer Netherlands
Erschienen in: Cellulose / Ausgabe 3/2014
Print ISSN: 0969-0239
Elektronische ISSN: 1572-882X
DOI: https://doi.org/10.1007/s10570-014-0197-3

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