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Modeling the 3D Printing of Nanocellulose Hydrogels
Antti Paajanen
,
Tatu Pinomaa
, Heikki Pajari
, Sini Metsä-Kortelainen
,
Panu Lahtinen
, Asta Nurmela
Research output
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Conference article
›
Scientific
Overview
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Dive into the research topics of 'Modeling the 3D Printing of Nanocellulose Hydrogels'. Together they form a unique fingerprint.
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Keyphrases
3D Printing
100%
3D Printing Process
33%
Biomaterials
33%
Bleached Kraft Pulp
33%
Capillary
33%
Cellulose Materials
33%
Computational Fluid Dynamics
66%
Computational Fluid Dynamics Analysis
33%
Computational Fluid Dynamics Modeling
33%
Dynamic Packaging
33%
Flow Behavior
33%
Flow Condition
66%
Fluid Behavior
33%
High Shear Rate
33%
History Dependence
33%
Limiting Behavior
33%
Mass Flow
33%
Material Properties
33%
Medical Applications
66%
Nanocellulose
33%
Nanocellulose Hydrogel
100%
Nozzle
33%
OpenFOAM
33%
Operating Pressure
66%
Power-law Fluid
33%
Pressure-driven Flow
33%
Print Resolution
33%
Printhead
100%
Printing Parameters
66%
Printing Pastes
33%
Printing Speed
33%
Rheological Modeling
33%
Rheological Properties
33%
Rheometry
100%
Shear Rate
66%
Specimen Quality
33%
Steady State
33%
Steady-state Conditions
33%
TEMPO Oxidation
33%
Thixotropy
66%
Transient Experiments
33%
Transient State
33%
Viscosimetry
33%
Volume of Fluid Method
33%
Wound Care Products
33%
INIS
3d printing
100%
air
25%
applications
50%
biological materials
25%
capillaries
25%
cellulose
25%
computational fluid dynamics
100%
deposition
50%
flow models
25%
fluids
50%
hydrogels
100%
interactions
25%
levels
25%
modeling
100%
nozzles
25%
oxidation
25%
power
25%
pulps
25%
resolution
75%
sensitivity
25%
shear
75%
speed
25%
steady-state conditions
50%
thixotropy
50%
validation
25%
values
25%
volume
25%
wounds
25%
Engineering
Care Product
25%
Computational Fluid Dynamics
100%
Dynamic Models
25%
Flow Behavior
25%
Flow Condition
50%
High Shear Rate
25%
Hydrogel
100%
Mediated Oxidation
25%
Medical Applications
50%
Nanocellulose
100%
Observed Flow
25%
Operating Pressure
50%
Power Law Fluid
25%
Printing Process
25%
Printing Resolution
25%
Shear Rate
50%
State Condition
25%
Surrounding Air
25%
Thixotropy
50%
Three Dimensional Printing
100%
Volume of Fluid Method
25%
Material Science
Biomaterial
25%
Computational Fluid Dynamics
100%
Dynamic Analysis
25%
Hydrogel
100%
Kraft Pulp
25%
Materials Property
25%
Nanocellulose
100%
Thixotropy
50%
Three Dimensional Printing
100%