Experimental and theoretical analysis of in-plane cohesive testing of paperboard

Johan Tryding; Gustav Marin; Mikael Nygårds; Petri Mäkelä; Giulio Ferrari

doi:10.1177/1056789516630776

Experimental and theoretical analysis of in-plane cohesive testing of paperboard

Johan Tryding, Gustav Marin, Mikael Nygårds, Petri Mäkelä, Giulio Ferrari

Solid Mechanics

Research output: Contribution to journal › Article › peer-review

Abstract

In-plane cohesive failure of paperboard was characterized by short-span uniaxial tension tests. Six paperboards' qualities were experimentally investigated, from which cohesive stress-widening curves were extracted. A fracture energy was defined, expressed in the tensile strength and maximum slope of the cohesive stress-widening relation. Analytical cohesive relations were derived based on the tensile strength and maximum slope, utilizing the Morse potential for diatomic molecules. It was experimentally found that the maximum slope and fracture energy depend on the tensile strength. The ratio of the maximum slope to the elastic modulus (stable length) was shown to be independent of the tensile strength.

Original language	English
Pages (from-to)	895-918
Number of pages	24
Journal	International Journal of Damage Mechanics
Volume	26
Issue number	6
DOIs	https://doi.org/10.1177/1056789516630776
Publication status	Published - 2017 Aug 1

Subject classification (UKÄ)

Paper, Pulp and Fiber Technology

Free keywords

cohesive fracture
experiment
in-plane direction
orthotropic
Paperboard

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10.1177/1056789516630776

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title = "Experimental and theoretical analysis of in-plane cohesive testing of paperboard",

abstract = "In-plane cohesive failure of paperboard was characterized by short-span uniaxial tension tests. Six paperboards' qualities were experimentally investigated, from which cohesive stress-widening curves were extracted. A fracture energy was defined, expressed in the tensile strength and maximum slope of the cohesive stress-widening relation. Analytical cohesive relations were derived based on the tensile strength and maximum slope, utilizing the Morse potential for diatomic molecules. It was experimentally found that the maximum slope and fracture energy depend on the tensile strength. The ratio of the maximum slope to the elastic modulus (stable length) was shown to be independent of the tensile strength.",

keywords = "cohesive fracture, experiment, in-plane direction, orthotropic, Paperboard",

author = "Johan Tryding and Gustav Marin and Mikael Nyg{\aa}rds and Petri M{\"a}kel{\"a} and Giulio Ferrari",

year = "2017",

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T1 - Experimental and theoretical analysis of in-plane cohesive testing of paperboard

AU - Tryding, Johan

AU - Marin, Gustav

AU - Nygårds, Mikael

AU - Mäkelä, Petri

AU - Ferrari, Giulio

PY - 2017/8/1

Y1 - 2017/8/1

N2 - In-plane cohesive failure of paperboard was characterized by short-span uniaxial tension tests. Six paperboards' qualities were experimentally investigated, from which cohesive stress-widening curves were extracted. A fracture energy was defined, expressed in the tensile strength and maximum slope of the cohesive stress-widening relation. Analytical cohesive relations were derived based on the tensile strength and maximum slope, utilizing the Morse potential for diatomic molecules. It was experimentally found that the maximum slope and fracture energy depend on the tensile strength. The ratio of the maximum slope to the elastic modulus (stable length) was shown to be independent of the tensile strength.

AB - In-plane cohesive failure of paperboard was characterized by short-span uniaxial tension tests. Six paperboards' qualities were experimentally investigated, from which cohesive stress-widening curves were extracted. A fracture energy was defined, expressed in the tensile strength and maximum slope of the cohesive stress-widening relation. Analytical cohesive relations were derived based on the tensile strength and maximum slope, utilizing the Morse potential for diatomic molecules. It was experimentally found that the maximum slope and fracture energy depend on the tensile strength. The ratio of the maximum slope to the elastic modulus (stable length) was shown to be independent of the tensile strength.

KW - cohesive fracture

KW - experiment

KW - in-plane direction

KW - orthotropic

KW - Paperboard

U2 - 10.1177/1056789516630776

DO - 10.1177/1056789516630776

M3 - Article

AN - SCOPUS:85022070705

SN - 1056-7895

VL - 26

SP - 895

EP - 918

JO - International Journal of Damage Mechanics

JF - International Journal of Damage Mechanics

IS - 6

ER -

Experimental and theoretical analysis of in-plane cohesive testing of paperboard

Abstract

Subject classification (UKÄ)

Free keywords

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