In
this
study,
the
heat
transfer
and
fluid
flow
characteristics
of
Cu–SiO2–TiO2
ternary
hybrid
nanofluids
in
a
semi-permeable
channel
with
injection
or
suction
at
top
surface
melting
condition
bottom
wall
were
investigated.
The
analysis
incorporates
effects
magnetoconvection,
radiation,
Joule
heating
on
thermal
dynamics.
Differential
Transformation
Method
is
employed
to
solve
dimensionless
governing
equations
under
appropriate
initial
boundary
conditions.
A
detailed
parametric
investigation
was
conducted
evaluate
influence
key
parameters,
including
Hartmann
number,
Reynolds
Eckert
nanoparticle
volume
fraction,
skin
friction
coefficient,
Nusselt
number.
results
reveal
that
increasing
number
reduces
velocity
while
enhancing
temperature
profiles
due
intensified
Lorentz
forces.
Elevated
numbers
boost
convective
intensity,
higher
fractions
significantly
improve
conductivity,
leading
numbers.
Injection
enhances
transport
by
strengthening
flow,
whereas
layer
thickness.
addition,
radiation
further
modulate
phenomena
optimize
energy
transfer.
These
findings
highlight
potential
for
achieving
superior
performance,
underscoring
their
applicability
modern
storage
management
systems.
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences,
Год журнала:
2024,
Номер
119(2), С. 160 - 172
Опубликована: Июль 30, 2024
This
comprehensive
review
critically
examines
recent
research
concerning
the
application
of
nanofluids
in
heat
exchangers.
The
utilization
nanofluids,
which
are
colloidal
suspensions
nanoparticles
a
base
fluid,
has
garnered
significant
attention
enhancing
transfer
performance.
Various
studies
have
explored
potential
benefits
and
challenges
associated
with
incorporating
into
exchanger
systems.
Through
systematic
analysis
literature,
this
assesses
effectiveness
improving
efficiency
overall
performance
Key
parameters
such
as
nanoparticle
concentration,
size,
type
thoroughly
evaluated
to
understand
their
influence
on
characteristics.
Additionally,
factors
stability,
flow
behavior,
thermal
conductivity
enhancement
scrutinized
provide
understanding
nanofluid
behavior
also
addresses
limitations
areas
requiring
further
investigation
optimize
applications.
By
synthesizing
findings,
aims
contribute
advancement
knowledge
field
technology
Ultimately,
insights
provided
offer
valuable
guidance
for
researchers
engineers
seeking
enhance
processes
through
implementation
nanofluid-based
Nanofluids
advantages
like
enhanced
tailored
properties,
promising
optimized
designs,
leading
energy
reduced
costs.
However,
remain,
dispersion
cost-effectiveness,
necessitating
refinement.
Interdisciplinary
collaboration
is
crucial
advancing
applications,
fostering
innovation
meet
demands
sustainable
solutions.