E3S Web of Conferences,
Journal Year:
2024,
Volume and Issue:
581, P. 01028 - 01028
Published: Jan. 1, 2024
The
textile
industry
is
a
very
resource-intensive
sector,
considerably
contributing
to
environmental
deterioration
via
substantial
use
of
water,
electricity,
and
chemicals.
With
the
global
transition
towards
sustainable
practices,
notion
circular
economy
has
become
more
significant,
focusing
on
prolonging
product
lifespans,
reducing
waste,
facilitating
material
recovery.
An
effective
method
for
achieving
circularity
in
sector
Design
Disassembly
(DfD),
which
facilitates
straightforward
deconstruction
items
recycling
or
reuse.
This
study
examines
(DfD)
production,
emphasizing
methods
that
enable
separation
fibers,
trimmings,
fasteners,
hence
improving
garment
recyclability.
Data
was
gathered
comprehensive
examination
designs,
production
methodologies,
throughout
sector.
Findings
demonstrate
DfD
may
substantially
decrease
waste
enhance
recovery
rates.
Nonetheless,
obstacles
like
redesign
expenses,
customer
awareness,
compatibility
with
existing
techniques
persist.
presents
detailed
technique
incorporating
into
manufacturing
its
possible
effects
economy.
results
substantiate
assertion
implementation
be
crucial
advancement
toward
attaining
sustainability
Euro-Mediterranean Journal for Environmental Integration,
Journal Year:
2024,
Volume and Issue:
unknown
Published: July 27, 2024
The
challenges
of
balancing
environmental
sustainability
with
economic
and
social
growth
are
intensifying,
unsustainable
consumption
production
patterns
posing
significant
risks
on
a
global
scale
(i.e.,
resource
scarcity,
raw
material
consumption,
waste
etc.).
Projections
indicate
sharp
increase
in
municipal
solid
associated
costs
by
2050
while
combating
all
implications
this
becomes
more
vital.
To
address
these
challenges,
the
European
Green
Deal
Sustainable
Development
Goals
(SDGs)
United
Nations,
particularly
SDG
12,
emphasize
necessity
sustainable
products,
materials,
energy,
water
etc.
This
involves
adopting
circular
economy
model,
which
transforms
into
resources,
conserving
natural
enhancing
performance.
Key
strategies
include
broader
implementation
R
(reduce,
reuse,
recycle,
remanufacture,
refurbish),
producer
responsibility,
advanced
monitoring
tools
like
Life
Cycle
Assessment
(LCA)
Material
Flow
Analysis
(MFA).
Additionally,
energy
systems
innovative
digital
technologies
(i.e.
artificial
intelligence,
Internet
Things,
blockchain
etc.)
holistic
utilization
Industry
5.0
play
crucial
role.
Public
education
awareness
essential
for
fostering
behaviors
coupled
effective
policy,
governance
building
trust
between
public
decision
makers.
At
same
time,
collaborative
efforts
from
governments,
industries,
communities
imperative
transitioning
to
economy,
ensuring
resilient
equitable
future.
Textile Research Journal,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 4, 2025
The
extensive
production
of
waste
wool
in
the
textile
industry
poses
significant
environmental
challenges.
To
address
this
issue,
we
present
a
novel
recycling
approach
that
transforms
into
carbonized,
porous,
and
C/N/O
co-doped
TiO
2
composite
material.
This
was
achieved
through
simple
one-step
hydrothermal
synthesis
followed
by
calcination
either
nitrogen
or
an
air
atmosphere.
innovative
method
not
only
repurposes
but
also
creates
material
with
impressive
adsorption
photocatalytic
properties,
offering
new
solution
for
remediation.
process
effectively
dispersed
nanoparticles,
increasing
number
active
sites.
When
calcined
atmosphere,
graphitization
biochar
enhanced,
doping
achieved,
oxygen
vacancies
were
created,
all
which
significantly
improved
performance.
resulting
exhibited
capacity
methylene
blue
dye
13.8
times
higher
than
untreated
sample,
9.9
sample
air.
Furthermore,
retained
99%
its
original
after
second
cycle,
indicating
strong
potential.
Photocatalytic
performance
tests
showed
marked
improvement
degradation
efficiency
blue,
Congo
red,
tetracycline
hydrochloride
under
simulated
solar
irradiation.
primary
species
involved
singlet
(
1
O
)
photogenerated
holes
(h
+
),
while
superoxide
radicals
([Formula:
see
text])
hydroxyl
(‧OH)
contributed
to
photodegradation
blue.
use
as
catalyst
support
extends
practical
applications
helps
reduce
impact
organic
pollutants.
Polymer Composites,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 2, 2025
Abstract
Currently,
glass
fiber‐reinforced
resin
composites,
as
an
advanced
optically
transparent
material,
have
garnered
widespread
attention
and
research.
In
the
context
of
new‐era
developments,
there
is
a
growing
demand
expectation
for
visual
artistic
expression
light‐transmitting
composites.
this
study,
fiber
fabric,
silk
recycled
polyester
jacquard
fabric
were
used
reinforcement
materials,
while
epoxy
was
selected
matrix
material.
A
green
decorative
composite
with
uniform
light
diffusion
soft
effects
prepared
using
vacuum
bag
molding
process.
By
altering
woven
structure
(plain
weave,
twill
satin
weave),
yarn
density,
twist
optical
properties
composites
can
be
regulated.
The
unique
triangular
cross‐section,
structure,
large
folds
plain‐woven
particularly
conducive
to
reflection
refraction
within
composite,
thereby
significantly
enhancing
Furthermore,
bending
failure
behavior
investigated
through
three‐point
tests,
acoustic
emission
(AE)
test,
micro‐computed
tomography
(Micro‐CT)
scanning.
laminate
specimens
reinforced
exhibited
best
performance,
strength
modulus
reaching
434.4
MPa
19.0
GPa,
respectively.
combination
AE
micro‐CT
scanning
techniques
successfully
established
correlation
between
signals
damage
modes.
This
study
identified
main
modes
plain
woven,
breakage,
interlayer
delamination,
fiber/resin
debonding,
Highlights
Waste
textiles
use
in
Silk
fabric's
weave
affected
composites'
properties.
Fiber
breakage
Plain
optimal
diffuse
light,
superior
flexural
performance.
