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Compression strength mechanisms of low-density fibrous materials
Jukka A. Ketoja
*
,
Sara Paunonen
, Petri Jetsu
,
Elina Pääkkönen
*
Corresponding author for this work
Research output
:
Contribution to journal
›
Article
›
Scientific
›
peer-review
40
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Dive into the research topics of 'Compression strength mechanisms of low-density fibrous materials'. Together they form a unique fingerprint.
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Keyphrases
Buckling Theory
50%
Compression Cycle
50%
Compression Level
100%
Compression Strength
100%
Compressive Strain
50%
Correlation Analysis
50%
Deformation Behavior
50%
Deformation Front
50%
Dislocation
50%
Experimental Sample
50%
Fiber Materials
50%
Fiber Network
100%
Fibrous Materials
100%
Free Span
50%
Heterogeneous Deformation
50%
High-speed Imaging
50%
Image Correlation
50%
Lightweight Materials
50%
Local Deformation
50%
Low Density
100%
Material Density
100%
Material Effect
50%
Mechanical Testing
50%
Natural Cellulose Fibers
50%
Random Fiber Networks
50%
Ratio of Means
50%
Regenerated Cellulose Fiber
50%
Span Length
50%
Statistical Distribution
50%
Strength Mechanism
100%
Trial Point
50%
Universal Ratios
50%
INIS
applications
16%
buckling
16%
cellulose
16%
compression
50%
compression strength
100%
correlations
16%
deformation
50%
density
100%
dislocations
16%
distribution
16%
experimental data
16%
fibers
100%
foams
16%
images
16%
length
16%
levels
33%
mechanical tests
16%
proceedings
16%
randomness
16%
speed
16%
strains
16%
values
16%
Engineering
Compression Level
100%
Compression Strength
100%
Compressive Strain
50%
Deformation Behavior
50%
Density of Material
50%
Lightweight Material
50%
Mechanical Testing
50%
Regenerated Cellulosic Fibre
50%
Span Length
50%
Statistical Distribution
50%
Theoretical Value
50%
Material Science
Density
100%
Fibrous Material
100%
Mechanical Testing
25%