E3S Web of Conferences,
Год журнала:
2024,
Номер
552, С. 01099 - 01099
Опубликована: Янв. 1, 2024
In
the
sustainability
of
ceramic
forming
this
paper
will
provide
a
comprehensive
review
way
that
ceramics
have
changed
over
time
towards
due
to
Industry
4.0’s
current
manufacturing
technologies
which
are
improving
day
by
day.
Particularly
study
focuses
on
reducing
depletion
resources,
energy
utilization,
and
natural
pollution
examining
how
conventional
strategies
for
can
be
replaced
new
ones
emphasize
form
solution.
Basically,
highlights
few
crucial
properties
in
including
its
capacity
resist
high
temperatures,
flexibility,
chemical
inactivity,
their
significance
several
areas
like
biomedical
designing,
hardware,
aviation,
machinery
industry,
many
more
applications.
When
drawbacks
traditional
methods
were
analyzed
such
as
cost
lengthy
processing
periods,
clarifies
there
is
need
sustainable
alternatives.
This
also
examines
possibilities
additive
(3D
printing)
hydroforming,
permit
accuracy
product
shape
while
utilizing
low
amount
materials
energy.
Going
forward,
research
looks
into
eco-friendly
make
most
secondary
sources
or
based
biomass-based
added
substances
binders.
Using
examples
from
real
circumstances
information
it
demonstrates
where
utilized
different
divisions
design,
space
travel,
electronics,
wellbeing
care,
renewable
sources.
By
doing
so,
emphasizes
making
seems
trigger
environmental
enhancements
well
keep
up
resource
efficiency
shift
circular
economy.
Fiber-reinforced
mycelium
(FRM)
composites
offer
an
innovative
and
sustainable
approach
to
construction
materials
for
architectural
structures.
Mycelium,
the
root
structure
of
fungi,
can
be
combined
with
various
natural
fibers
(NF)
create
a
strong
lightweight
material
environmental
benefits.
Incorporating
NF
like
hemp,
jute,
or
bamboo
into
matrix
enhances
mechanical
properties.
This
combination
results
in
composite
that
boasts
enhanced
strength,
flexibility,
durability.
Natural
FRM
sustainability
through
utilization
agricultural
waste,
reducing
carbon
footprint
compared
conventional
materials.
Additionally,
yet
nature
resulting
makes
it
versatile
applications,
while
its
inherent
insulation
properties
contribute
improved
energy
efficiency
buildings.
Developing
adopting
showcase
promising
step
towards
eco-friendly
Ongoing
research
collaboration
between
scientists,
engineers,
industry
will
likely
lead
further
improvements
expanded
applications.
article
provides
comprehensive
analysis
current
applications
paper
reviews
potential
impacts
these
context
practices.
Recently,
relevance
mycelium-based
has
extended
beyond
their
original
fields
microbiology
mycology
architecture.
Fibers,
Год журнала:
2024,
Номер
12(7), С. 57 - 57
Опубликована: Июль 9, 2024
Fiber-reinforced
mycelium
(FRM)
composites
offer
an
innovative
and
sustainable
approach
to
construction
materials
for
architectural
structures.
Mycelium,
the
root
structure
of
fungi,
can
be
combined
with
various
natural
fibers
(NF)
create
a
strong
lightweight
material
environmental
benefits.
Incorporating
NF
like
hemp,
jute,
or
bamboo
into
matrix
enhances
mechanical
properties.
This
combination
results
in
composite
that
boasts
enhanced
strength,
flexibility,
durability.
Natural
FRM
sustainability
through
utilization
agricultural
waste,
reducing
carbon
footprint
compared
conventional
materials.
Additionally,
yet
nature
resulting
makes
it
versatile
applications,
while
its
inherent
insulation
properties
contribute
improved
energy
efficiency
buildings.
Developing
adopting
showcases
promising
step
towards
eco-friendly
Ongoing
research
collaboration
between
scientists,
engineers,
industry
will
likely
lead
further
improvements
expanded
applications.
article
provides
comprehensive
analysis
current
applications
paper
reviews
potential
impacts
these
context
practices.
Recently,
applicability
mycelium-based
has
extended
beyond
their
original
domains
biology
mycology
architecture.
Proceedings of the Institution of Mechanical Engineers Part E Journal of Process Mechanical Engineering,
Год журнала:
2025,
Номер
unknown
Опубликована: Май 2, 2025
The
aim
of
this
article
was
to
fabricate
and
characterization
bamboo
dust
(BD)
with
white
dholpur
stone
powder
(WDSP)
in
ceramic
tile
manufacturing.
Bamboo
varied
from
0%,
5%,
6%,
7%,
8%.
WDSP
12%,
4%.
tiles
were
fabricated
by
a
hydraulic
compressed
uniaxial
pressing
machine
at
24
MPa.
Water
absorption,
ignition
loss,
shrinkage
rates,
breaking
strength,
modulus
rupture,
etc.
investigated
work.
X-ray
diffraction
(XRD)
scanning
electron
microscopy
(SEM)
used
determine
crystalline
structure,
chemical
composition,
overall
morphology
tiles.
result
revealed
that
the
maximum
linear
obtained
WA-5-IV
(5.07%).
While
rupture
depicted
WA-4
(49.93
(N/mm
2
)).
Buildings,
Год журнала:
2025,
Номер
15(10), С. 1717 - 1717
Опубликована: Май 19, 2025
Wood,
steel,
and
concrete
constitute
the
three
predominant
structural
materials
employed
in
contemporary
commercial
residential
construction.
In
composite
applications,
bond
interfaces
between
these
represent
critical
junctures
that
frequently
exhibit
a
reduced
load-bearing
capacity,
rendering
them
susceptible
to
initiation
of
cracks.
To
elucidate
fracture
propagation
mechanisms
at
material
interfaces,
this
study
implements
cohesive
zone
method
(CZM)
numerically
simulate
interfacial
cracking
behavior
two
systems:
glued
laminated
timber
(GLT)
reinforced
(RC).
The
adopted
CZM
framework
utilizes
progressive
delamination
approach
through
elements
governed
by
bilinear
traction–separation
constitutive
law.
This
methodology
enables
simulation
failure
distinct
modes:
mode
I
(pure
normal
separation),
II
in-plane
shear),
mixed-mode
(mode
m)
failure.
Numerical
models
were
developed
for
GLT
beams,
RC
slab
structures
investigate
cracks
under
monotonic
loading
conditions.
results
demonstrate
strong
agreement
with
experimental
observations
structures,
validating
CZM’s
efficacy
characterizing
both
mechanical
crack
displacement
fields.
model
successfully
captures
transverse
tensile
I)
parallel
wood
grain,
longitudinal
shear
II),
specimens.
Subsequent
application
components
revealed
comparable
predictive
accuracy
simulating
response
patterns
interfaces.
These
findings
collectively
substantiate
robustness
proposed
modeling
complex
phenomena
across
diverse
construction
systems.
