Document detail
ID
oai:HAL:hal-04224356v1
Topic
Natural fibers Elasticity Finite element analysis (FEA) Mechanical testing [INFO.INFO-DS]Computer Science [cs... [PHYS.MECA]Physics [physics]/Mecha... [SPI.AUTO]Engineering Sciences [ph...Author
Govilas, Jason Clevy, Cédric Beaugrand, Johnny Placet, VincentLangue
enEditor
HAL CCSD;Elsevier
Category
technologies: computer sciences
Year
2023
listing date
12/7/2023
Keywords
element geometry finite features models plant analysis fiber transverseAbstract
International audience; This study explores the link between plant fiber geometry and its transverse behavior, focusing on the resulting apparent transverse stiffness as determined by analytical models.
Using Finite Element Analysis (FEA) plant fiber transverse compression is simulated with two-dimensional models.
Simplified geometric representations of common geometric features are examined, showing how distinct attributes influence behavior.
The fiber lumen is shown to decrease apparent stiffness, while elliptical geometry and flat sections increase it.
An adaptation of analytical models for ellipticalcross-sections yields a 93 % improvement on identification accuracy.
Furthermore, the transverse compression of realistic geometries, extracted from microscopy images and presenting a blend of different features, is simulated.
The lumen’s impact on apparentstiffness is shown to outweigh the effects of other features.
These findings show the importance of apparent stiffness over fiber cell wall stiffness and how it may evolve under repeated loading, which has important implications for the composites sector.
Govilas, Jason,Clevy, Cédric,Beaugrand, Johnny,Placet, Vincent, 2023, Investigating the influence of plant fiber geometry on apparent transverse elastic properties through finite element analysis, HAL CCSD;Elsevier
