Springer series in reliability engineering,
Год журнала:
2024,
Номер
unknown, С. 79 - 103
Опубликована: Янв. 1, 2024
This
comprehensive
exploration
goes
into
the
principles,
techniques,
and
real-world
applications
of
Reliability-Centered
Design
(RCD)
system
resilience
in
engineering.
The
paper
begins
by
elucidating
core
principles
RCD,
which
include
identifying
critical
components,
assessing
failure
modes,
designing
for
redundancy,
devising
effective
maintenance
strategies,
mitigating
consequences
failures.
In-depth
discussions
on
these
provide
engineers
designers
with
a
robust
framework
enhancing
reliability
products,
systems,
processes.
chapter
proceeds
to
dissect
powerful
design
emphasizing
role
Experiments
(DOE),
tolerance
analysis,
quality
control
improving
reliability.
Systematically
addressing
variations
uncertainties,
can
develop
products
systems
that
consistently
meet
performance
standards,
even
under
adverse
conditions.
System
redundancy
analysis
are
explored
extensively,
focusing
diverse
types
implementing
failover
mechanisms
absorb
shocks
recover
from
disruptions.
Risk
assessment
is
central
element,
as
guides
readers
through
parameters,
quantifying
risks,
developing
risk
mitigation
strategies.
Through
compelling
case
studies
best
practices,
this
offers
practical
insights
how
RCD
applied
across
industries.
Industry-specific
examples
showcase
successful
application
while
lessons
past
failures
underscore
importance
continuous
improvement
engineering
design.
resource
engineers,
designers,
practitioners
seeking
create
robust,
reliable,
adaptable
withstand
challenges
disruptions
minimizing
risks
empowers
professionals
knowledge
tools
excel
dynamic
demanding
Heliyon,
Год журнала:
2024,
Номер
10(13), С. e34071 - e34071
Опубликована: Июль 1, 2024
The
circular
economy
(CE)
is
reasoned
to
organize
complex
systems
supporting
sustainable
resilience
by
distinguishing
between
waste
materials
and
economic
growth.
This
crucial
the
electronic
(e-waste)
industry
of
developed
countries,
e-waste
operation
management
has
become
their
top
priority
because
contains
toxic
valuable
sources
elements.
In
UK,
although
London
Metropolitan
city
boasts
an
ambitious
target
underlying
context
CE,
practical
implementation
yet
be
feasible,
with
few
investigations
detailing
if
how
existing
implications
enable
industrial
social-ecological
sectors
continue
performance
functionalities
in
face
undesired
disruptions.
this
paper,
a
dynamic
Bayesian
Network
(dynamic
BN)
approach
address
range
potential
risks.
considered
as
application
study
for
development.
Through
utilization
BN,
comprehensive
analysis
yields
Resilience
Index
(RI)
0.5424,
coupled
StdDev
0.01350.
These
metrics
offer
profound
insight
into
intricate
workings
system
its
capacity
swiftly
rebound
from
unexpected
shocks
disturbances.
newfound
understanding
equips
policymakers
knowledge
needed
navigate
complexities
effectively.
drawn
these
in-depth
analyses
furnish
invaluable
information,
enabling
them
make
judicious
decisions
that
advance
cause
management.
findings
underscore
absorptive
resilient
stands
foremost
defense
mechanism
against
unforeseen
challenges.
Furthermore,
it
becomes
evident
two
pivotal
factors,
namely
"diversifying
supply
chain"
"enhancing
chain
transparency,"
play
roles
augmenting
sustainability
within
London's
targets.
factors
are
instrumental
steering
trajectory
towards
more
future,
aligning
aspirations
greener
eco-conscious
future.
Springer series in reliability engineering,
Год журнала:
2024,
Номер
unknown, С. 79 - 103
Опубликована: Янв. 1, 2024
This
comprehensive
exploration
goes
into
the
principles,
techniques,
and
real-world
applications
of
Reliability-Centered
Design
(RCD)
system
resilience
in
engineering.
The
paper
begins
by
elucidating
core
principles
RCD,
which
include
identifying
critical
components,
assessing
failure
modes,
designing
for
redundancy,
devising
effective
maintenance
strategies,
mitigating
consequences
failures.
In-depth
discussions
on
these
provide
engineers
designers
with
a
robust
framework
enhancing
reliability
products,
systems,
processes.
chapter
proceeds
to
dissect
powerful
design
emphasizing
role
Experiments
(DOE),
tolerance
analysis,
quality
control
improving
reliability.
Systematically
addressing
variations
uncertainties,
can
develop
products
systems
that
consistently
meet
performance
standards,
even
under
adverse
conditions.
System
redundancy
analysis
are
explored
extensively,
focusing
diverse
types
implementing
failover
mechanisms
absorb
shocks
recover
from
disruptions.
Risk
assessment
is
central
element,
as
guides
readers
through
parameters,
quantifying
risks,
developing
risk
mitigation
strategies.
Through
compelling
case
studies
best
practices,
this
offers
practical
insights
how
RCD
applied
across
industries.
Industry-specific
examples
showcase
successful
application
while
lessons
past
failures
underscore
importance
continuous
improvement
engineering
design.
resource
engineers,
designers,
practitioners
seeking
create
robust,
reliable,
adaptable
withstand
challenges
disruptions
minimizing
risks
empowers
professionals
knowledge
tools
excel
dynamic
demanding
