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Wood Science and Technology
Published in: Wood Science and Technology 1/2010

01-02-2010 | Original

Cantilever experimental setup for rheological parameter identification in relation to wood drying

Authors: Mohssine Moutee, Yves Fortin, Aziz Laghdir, Mario Fafard

Published in: Wood Science and Technology | Issue 1/2010

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Abstract

Wood exhibits a pronounced time dependent deformation behavior which is usually split into ‘viscoelastic’ creep at constant moisture content (MC) and ‘mechano-sorptive’ creep in varying MC conditions. Experimental determination of model rheological parameters on a material level remains a serious challenge, and diversity of experimental methods makes published results difficult to compare. In this study, a cantilever experimental setup is proposed for creep tests because of its close analogy with the mechanical behavior of wood during drying. Creep measurements were conducted at different load levels (LL) under controlled temperature and humidity conditions. Radial specimens of white spruce wood [Picea glauca (Moench.) Voss.] with dimensions of 110 mm in length (R), 25 mm in width (T), and 7 mm in thickness (L) were used. The influence of LL and MC on creep behavior of wood was exhibited. In constant MC conditions, no significant difference was observed between creep of tensile and compressive faces of wood cantilever. For load not greater than 50% of the ultimate load, the material exhibited a linear viscoelastic creep behavior at the three equilibrium moisture contents considered in the study. The mechano-sorptive creep after the first sorption phase was several times greater than creep at constant moisture conditions. Experimental data were fitted with numerical simulation of the global rheological model developed by authors for rheological parameter identification.
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Metadata
Title
Cantilever experimental setup for rheological parameter identification in relation to wood drying
Authors
Mohssine Moutee
Yves Fortin
Aziz Laghdir
Mario Fafard
Publication date
01-02-2010
Publisher
Springer-Verlag
Published in
Wood Science and Technology / Issue 1/2010
Print ISSN: 0043-7719
Electronic ISSN: 1432-5225
DOI
https://doi.org/10.1007/s00226-009-0274-1

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