Mean-field approach to compression of thick porous fibre networks

J A Ketoja; Sara Paunonen; Elina Pääkkönen; Tiina Pöhler; Tuomas Turpeinen; Arttu Miettinen; Tero Mäkinen; Juha Koivisto; Mikko Alava

Mean-field approach to compression of thick porous fibre networks

J A Ketoja, Sara Paunonen, Elina Pääkkönen, Tiina Pöhler, Tuomas Turpeinen, Arttu Miettinen, Tero Mäkinen, Juha Koivisto, Mikko Alava

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Abstract

We discuss a new mean-field theory to describe the compression behaviour of thick low-density fibre networks. The theory is based on the idea that in very large systems, the statistics of free segment lengths causes the stress-deformation behaviour to be quantitatively predictable. The theoretical ideas are supported by several different experimental characterisations. Firstly, we have carried out single-fibre buckling tests using hemp fibres, which indicate a maximum level of axial stress before deformation localization, after which the load-carrying ability of a fibre decays. Secondly, the stress-compression behaviour of over 130 different foam-formed lightweight fibre materials were measured. For kraft pulps with low fines content, the average stress compression behaviour closely follows the theoretical prediction as described in terms of a universal s-function. Moreover, the acoustic emission can be described by the same function until collective phenomena cause deviations from the predicted behaviour. Similar deviations at smaller compressive strains are seen with furnishes with high fines content or added nanocelluloses together with samples with large voids. The localized buckling deformations lead to rapid stress re-distributions and subsequent fibre displacements in a fibre network as shown with in-situ CCD imaging.

Original language	English
Title of host publication	Advances in Pulp and Paper Research, Cambridge 2022
Subtitle of host publication	Transactions of the 17th Fundamental Research Symposium
Editors	Douglas W. Coffin, Warren J. Batchelor
Publisher	Pulp & Paper Fundamental Research Society
Pages	371-388
Volume	1
ISBN (Print)	978-0-9926163-6-6
Publication status	Published - 31 Aug 2022
MoE publication type	A4 Article in a conference publication
Event	17th Fundamental Research Symposium - Cambridge, United Kingdom Duration: 29 Aug 2022 → 1 Sept 2022

Conference

Conference	17th Fundamental Research Symposium
Country/Territory	United Kingdom
City	Cambridge
Period	29/08/22 → 1/09/22

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Ketoja, J. A., Paunonen, S., Pääkkönen, E., Pöhler, T., Turpeinen, T., Miettinen, A., Mäkinen, T., Koivisto, J., & Alava, M. (2022). Mean-field approach to compression of thick porous fibre networks. In D. W. Coffin, & W. J. Batchelor (Eds.), Advances in Pulp and Paper Research, Cambridge 2022: Transactions of the 17th Fundamental Research Symposium (Vol. 1, pp. 371-388). Pulp & Paper Fundamental Research Society.

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title = "Mean-field approach to compression of thick porous fibre networks",

abstract = "We discuss a new mean-field theory to describe the compression behaviour of thick low-density fibre networks. The theory is based on the idea that in very large systems, the statistics of free segment lengths causes the stress-deformation behaviour to be quantitatively predictable. The theoretical ideas are supported by several different experimental characterisations. Firstly, we have carried out single-fibre buckling tests using hemp fibres, which indicate a maximum level of axial stress before deformation localization, after which the load-carrying ability of a fibre decays. Secondly, the stress-compression behaviour of over 130 different foam-formed lightweight fibre materials were measured. For kraft pulps with low fines content, the average stress compression behaviour closely follows the theoretical prediction as described in terms of a universal s-function. Moreover, the acoustic emission can be described by the same function until collective phenomena cause deviations from the predicted behaviour. Similar deviations at smaller compressive strains are seen with furnishes with high fines content or added nanocelluloses together with samples with large voids. The localized buckling deformations lead to rapid stress re-distributions and subsequent fibre displacements in a fibre network as shown with in-situ CCD imaging.",

author = "Ketoja, {J A} and Sara Paunonen and Elina P{\"a}{\"a}kk{\"o}nen and Tiina P{\"o}hler and Tuomas Turpeinen and Arttu Miettinen and Tero M{\"a}kinen and Juha Koivisto and Mikko Alava",

year = "2022",

month = aug,

day = "31",

language = "English",

isbn = "978-0-9926163-6-6",

volume = "1",

pages = "371--388",

editor = "Coffin, {Douglas W.} and Batchelor, {Warren J.}",

booktitle = "Advances in Pulp and Paper Research, Cambridge 2022",

publisher = "Pulp & Paper Fundamental Research Society",

address = "United Kingdom",

note = "17th Fundamental Research Symposium ; Conference date: 29-08-2022 Through 01-09-2022",

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Ketoja, JA , Paunonen, S , Pääkkönen, E, Pöhler, T, Turpeinen, T, Miettinen, A, Mäkinen, T, Koivisto, J & Alava, M 2022, Mean-field approach to compression of thick porous fibre networks. in DW Coffin & WJ Batchelor (eds), Advances in Pulp and Paper Research, Cambridge 2022: Transactions of the 17th Fundamental Research Symposium. vol. 1, Pulp & Paper Fundamental Research Society, pp. 371-388, 17th Fundamental Research Symposium, Cambridge, United Kingdom, 29/08/22.

Mean-field approach to compression of thick porous fibre networks. / Ketoja, J A ; Paunonen, Sara ; Pääkkönen, Elina et al.
Advances in Pulp and Paper Research, Cambridge 2022: Transactions of the 17th Fundamental Research Symposium. ed. / Douglas W. Coffin; Warren J. Batchelor. Vol. 1 Pulp & Paper Fundamental Research Society, 2022. p. 371-388.

Research output: Chapter in Book/Report/Conference proceeding › Conference article in proceedings › Scientific › peer-review

TY - GEN

T1 - Mean-field approach to compression of thick porous fibre networks

AU - Ketoja, J A

AU - Paunonen, Sara

AU - Pääkkönen, Elina

AU - Pöhler, Tiina

AU - Turpeinen, Tuomas

AU - Miettinen, Arttu

AU - Mäkinen, Tero

AU - Koivisto, Juha

AU - Alava, Mikko

PY - 2022/8/31

Y1 - 2022/8/31

N2 - We discuss a new mean-field theory to describe the compression behaviour of thick low-density fibre networks. The theory is based on the idea that in very large systems, the statistics of free segment lengths causes the stress-deformation behaviour to be quantitatively predictable. The theoretical ideas are supported by several different experimental characterisations. Firstly, we have carried out single-fibre buckling tests using hemp fibres, which indicate a maximum level of axial stress before deformation localization, after which the load-carrying ability of a fibre decays. Secondly, the stress-compression behaviour of over 130 different foam-formed lightweight fibre materials were measured. For kraft pulps with low fines content, the average stress compression behaviour closely follows the theoretical prediction as described in terms of a universal s-function. Moreover, the acoustic emission can be described by the same function until collective phenomena cause deviations from the predicted behaviour. Similar deviations at smaller compressive strains are seen with furnishes with high fines content or added nanocelluloses together with samples with large voids. The localized buckling deformations lead to rapid stress re-distributions and subsequent fibre displacements in a fibre network as shown with in-situ CCD imaging.

AB - We discuss a new mean-field theory to describe the compression behaviour of thick low-density fibre networks. The theory is based on the idea that in very large systems, the statistics of free segment lengths causes the stress-deformation behaviour to be quantitatively predictable. The theoretical ideas are supported by several different experimental characterisations. Firstly, we have carried out single-fibre buckling tests using hemp fibres, which indicate a maximum level of axial stress before deformation localization, after which the load-carrying ability of a fibre decays. Secondly, the stress-compression behaviour of over 130 different foam-formed lightweight fibre materials were measured. For kraft pulps with low fines content, the average stress compression behaviour closely follows the theoretical prediction as described in terms of a universal s-function. Moreover, the acoustic emission can be described by the same function until collective phenomena cause deviations from the predicted behaviour. Similar deviations at smaller compressive strains are seen with furnishes with high fines content or added nanocelluloses together with samples with large voids. The localized buckling deformations lead to rapid stress re-distributions and subsequent fibre displacements in a fibre network as shown with in-situ CCD imaging.

M3 - Conference article in proceedings

SN - 978-0-9926163-6-6

VL - 1

SP - 371

EP - 388

BT - Advances in Pulp and Paper Research, Cambridge 2022

A2 - Coffin, Douglas W.

A2 - Batchelor, Warren J.

PB - Pulp & Paper Fundamental Research Society

T2 - 17th Fundamental Research Symposium

Y2 - 29 August 2022 through 1 September 2022

ER -

Mean-field approach to compression of thick porous fibre networks

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