Journal of Reinforced Plastics and Composites,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 17, 2025
The
objective
of
this
study
is
to
investigate
the
effects
alumina
filler
content
and
NaOH-treated
Roselle
fibers
on
mechanical,
thermal,
biodegradation,
tribological
properties
while
identifying
optimal
conditions
for
eco-friendly
applications.
Compression
molding
was
employed
fabricate
composites,
results
revealed
significant
improvements
in
performance
with
chemical
treatment
content.
Mechanical
testing
showed
that
10%
composite
exhibited
highest
tensile,
flexural,
impact
strengths
due
enhanced
interfacial
bonding
uniform
dispersion.
Thermal
analysis
demonstrated
improved
stability,
offering
best
thermal
degradation
resistance.
Biodegradation
studies
indicated
slower
weight
loss
alumina-filled
highlighting
their
environmental
durability.
Tribological
evaluations
achieved
lowest
specific
wear
rate
(SWR)
coefficient
friction
(COF),
supported
by
SEM
showing
minimal
debris
surface
damage.
Optimization
using
a
simulated
annealing
algorithm
identified
ideal
(sliding
velocity:
6.6
m/s,
sliding
distance:
500.33
m,
content:
10.62%)
minimized
SWR
(13.28
×
10⁻⁵
mm³/Nm)
COF
(0.278).
These
findings
provide
valuable
insights
into
fiber
composites
sustainable
applications
automotive
packaging
industries.
International Journal of Innovative Science and Research Technology (IJISRT),
Journal Year:
2024,
Volume and Issue:
unknown, P. 1672 - 1681
Published: May 3, 2024
Banana
fiber
is
an
underutilized
natural
resource
with
potential
for
industrial
applications
and
value
addition
at
the
smallholder
farm
level.
Traditional
manual
methods
extracting
fibers
from
banana
plant
wastes
are
inefficient
labour-intensive.
This
limits
opportunities
rural
communities
in
Africa
to
commercialize
cultivation.
The
study
aimed
address
this
challenge
by
developing
affordable
effective
mechanized
solution
tailored
small
farms.
Key
design
considerations
included
ease
of
operation,
portability,
durability,
optimization
a
single
operator.
Fabrication
using
basic
workshop
tools
demonstrated
technical
feasibility.
Structural
analysis
validated
structural
integrity.
Performance
testing
showed
85%
extraction
efficiency
5.36kg/sec,
outpacing
methods.
Results
confirm
machine
promote
higher
yields.
With
further
refinement,
developed
technology
can
stimulate
enterprise
industry
centered
on
production,
contributing
improved
livelihoods
continent.
Developments in the Built Environment,
Journal Year:
2023,
Volume and Issue:
16, P. 100255 - 100255
Published: Oct. 18, 2023
To
reduce
the
carbon
footprint
of
traditional
concrete
materials,
natural
fiber
is
vital.
This
study
systematically
analyzed
196
peer-reviewed
papers
using
literature
review
method
to
understand
fresh
properties,
mechanical
durability,
thermal
conductivity,
sound
absorption
sustainability,
applications,
barriers,
and
opportunities
for
concrete.
The
findings
indicate
that
reduces
cracking
rate,
increasing
tensile
strength.
Although
fibers
enhance
stress
distribution
within
concrete,
its
stability,
they
compressive
Additionally,
85.7%
concretes
exhibit
considerable
environmental
benefits;
however,
28.6%
43%
reviewed
studies
effective
economic
social
respectively.
Moreover,
this
demonstrates
following
potential
utilization:
60%
in
road
pavements
30%
residential
buildings.
However,
still
predominantly
utilized
laboratory
stage.
perspective
noteworthy:
summarizes
barriers
impede
application
develops
relevant
recommendations.
Environmental Chemistry Letters,
Journal Year:
2024,
Volume and Issue:
22(2), P. 715 - 750
Published: Jan. 29, 2024
Abstract
Traditional
building
materials
have
some
drawbacks
in
the
construction
industry,
particularly
terms
of
greenhouse
gas
emissions
and
energy
consumption.
Biomaterials
derived
from
renewable
sources
are
a
promising
alternative,
significantly
reducing
effect
enhancing
efficiency.
However,
traditional
still
dominate
sector,
there
is
lack
understanding
among
policymakers
developers
regarding
biomaterials.
Here,
we
review
biomaterials
their
policies
life
cycle
assessment
through
case
studies.
Bio-based
potential
to
reduce
over
320,000
tons
carbon
dioxide
by
2050.
They
also
exhibit
advantages
like
decreasing
water
absorption
40%,
consumption
8.7%,
acoustic
6.7%,
improving
mechanical
properties.
We
summarize
recent
advancements
mycelial
materials,
bioconcrete,
natural
fibers,
fiber-reinforced
composites.
explore
contributions
nanotechnology
microalgae
technology
biomaterials'
thermal
insulation
eco-friendliness.
Results in Engineering,
Journal Year:
2023,
Volume and Issue:
20, P. 101511 - 101511
Published: Oct. 18, 2023
Eco-friendly
bio-active
materials
designed
from
available
natural
resources
have
been
signified
a
big
challenge
in
the
past
few
decades.
Nevertheless,
deficiency
of
most
essential
knowledge
regarding
effective
processing
starting
which
has
used
to
fabricate
targeted
bio-polymeric
composites
framework
is
considered
foremost
encounter.
However,
cellulosic
fibers
(generally
extracted
different
parts
plants
like
bast/bark,
leaf,
steam)
received
more
attention
researchers,
due
their
outstanding
physiochemical,
thermomechanical,
morphological
properties
and
eco-friendly
nature/sustainability.
Basically,
features
hinge
on
proper
preparation
modification
process.
Conversely,
main
problem
fiber
its
hydrophilic
nature
while
polymeric
matrix
are
hydrophobic
thus
it
urgent
reduce
by
conducting
various
significant
chemical
techniques
so
as
improve
overall
quality
reinforcement
sustainable
biocomposite.
Therefore,
will
be
proposed
with
detailed
overview
focusing
notable
process
modifications
characterization
methods
this
review.
We
also
summarize
important
findings
earlier
literature
effects
treatments
being
emphasized.
Results in Engineering,
Journal Year:
2024,
Volume and Issue:
21, P. 101837 - 101837
Published: Feb. 6, 2024
Contemporary
infrastructure
requires
structural
elements
with
enhanced
mechanical
strength
and
durability.
Integrating
nanomaterials
into
concrete
is
a
promising
solution
to
improve
However,
the
intricacies
of
such
nanoscale
cementitious
composites
are
highly
complex.
Traditional
regression
models
encounter
limitations
in
capturing
these
intricate
compositions
provide
accurate
reliable
estimations.
This
study
focuses
on
developing
robust
prediction
for
compressive
(CS)
graphene
nanoparticle-reinforced
(GrNCC)
through
machine
learning
(ML)
algorithms.
Three
ML
models,
bagging
regressor
(BR),
decision
tree
(DT),
AdaBoost
(AR),
were
employed
predict
CS
based
comprehensive
dataset
172
experimental
values.
Seven
input
parameters,
including
graphite
nanoparticle
(GrN)
diameter,
water-to-cement
ratio
(wc),
GrN
content
(GC),
ultrasonication
(US),
sand
(SC),
curing
age
(CA),
thickness
(GT),
considered.
The
trained
70
%
data,
remaining
30
data
was
used
testing
models.
Statistical
metrics
as
mean
absolute
error
(MAE),
root
square
(RMSE)
correlation
coefficient
(R)
assess
predictive
accuracy
DT
AR
demonstrated
exceptional
accuracy,
yielding
high
coefficients
0.983
0.979
training,
0.873
0.822
testing,
respectively.
Shapley
Additive
exPlanation
(SHAP)
analysis
highlighted
influential
role
positively
impacting
CS,
while
an
increased
(w/c)
negatively
affected
CS.
showcases
efficacy
techniques
accurately
predicting
nanoparticle-modified
concrete,
offering
swift
cost-effective
approach
assessing
nanomaterial
impact
reducing
reliance
time-consuming
expensive
experiments.
Journal of Materials Research and Technology,
Journal Year:
2024,
Volume and Issue:
30, P. 4053 - 4063
Published: April 17, 2024
In
this
comprehensive
review,
we
dive
into
the
potential
of
natural
fibre
composites,
tracing
their
historical
use
spanning
three
millennia
and
recent
incorporation
polymer
matrices.
Various
fibres,
including
flax,
hemp,
jute,
more,
have
been
explored
as
reinforcements
due
to
renewable
nature
environmental
appeal.
Moreover,
these
fibers
are
gaining
traction
in
industries
such
automotive
packaging.
Leveraging
abundant
agricultural
waste
as,
wheat
husk,
rice
straw,
hemp
commercially
viable
fibre-reinforced
composites.
A
thorough
summary
is
given
article
diverse
array
fibers,
current
research
status,
encompassing
properties,
processing
techniques,
filler
materials
on
structural
factors,
thermogravimetric
analysis,
dynamic
mechanical
performance
under
thermal
loading,
fire
retardant
behaviour,
cone
calorimetric
analysis
various
other
applications,
all
while
referencing
latest
developments
field,
exploring
a
sustainable
future
with
Furthermore,
difficulties
associated
vulnerability
humidity,
retardancy
compliance
matrices,
examined.
This
paper
summarizes
complex
field
composites
covers
several
stability-related
appearance.
Sustainability,
Journal Year:
2024,
Volume and Issue:
16(3), P. 1223 - 1223
Published: Jan. 31, 2024
Fiber-reinforced
polymer
composites
(FRCs)
from
renewable
and
biodegradable
fiber
sustainable
resins
have
gained
substantial
attention
for
their
potential
to
mitigate
environmental
impacts.
The
limitations
of
these
become
evident
when
considered
in
the
context
high-performance
engineering
applications,
where
synthetic
like
glass
or
carbon
FRCs
typically
dominate.
A
balance
between
performance
composite
biodegradability
is
imperative
pursuit
what
may
be
termed
an
environmentally
conscious
composite.
This
comprehensive
review
article
provides
some
insight
into
sustainability
FRCs,
alongside
detailing
considerations
at
various
stages—materials,
performance,
end
life.
discussion
also
covers
different
types
natural
fibers
with
current
achievements
mechanical
functional
properties
such
composites,
followed
by
a
broad
survey
applications
across
diverse
applications.
