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Ndt

NDT, short for non-destructive testing, is a collective term for methods used to evaluate the properties and integrity of materials, components, or assemblies without causing damage or permanently altering their use. NDT aims to detect defects, measure dimensions, characterize materials, or monitor condition in service, supporting safety, quality, and reliability across industries such as aerospace, automotive, energy, construction, and manufacturing. The term is sometimes used interchangeably with non-destructive evaluation (NDE), though in some contexts NDE emphasizes the evaluation aspect.

Common NDT techniques include ultrasonic testing, which uses high-frequency sound waves to reveal internal flaws and

An NDT program typically involves planning, selecting appropriate methods, performing inspections, interpreting results, and documenting findings.

Safety and regulatory considerations include radiation protection for radiographic testing, proper handling and disposal of penetrants,

to
measure
thickness;
radiographic
testing,
using
X-rays
or
gamma
rays
to
image
internal
features;
magnetic
particle
testing,
which
detects
surface
and
near-surface
defects
in
ferromagnetic
materials
by
magnetization
and
the
visualization
of
iron
particles;
liquid
penetrant
testing,
where
a
visible
or
fluorescent
dye
reveals
surface
openings
after
a
penetrant
is
applied
and
drawn
out;
eddy
current
testing,
based
on
electromagnetic
induction
to
detect
cracks
and
assess
material
properties,
especially
near
the
surface
in
conductive
materials;
visual
inspection,
the
simplest
method,
aided
by
lighting,
magnification,
or
cameras;
and
acoustic
emission
testing,
which
monitors
transient
stress
waves
produced
under
load
to
identify
active
defect
growth.
Other
methods
include
thermography
and
leak
testing
as
appropriate.
Personnel
are
trained
and
certified
to
levels
(often
Level
1,
Level
2,
or
Level
3)
under
standards
such
as
ISO
9712
or
regional
schemes
like
the
ASNT
SNT-TC-1A.
Selection
of
method
depends
on
the
material,
geometry,
defect
type,
and
service
conditions,
with
acceptance
criteria
defined
by
codes
and
standards.
and
safe
equipment
operation.
The
development
of
NDT
dates
back
to
the
discovery
of
X-rays
in
1895,
followed
by
advances
in
magnetic
and
ultrasonic
techniques
in
the
mid-20th
century,
with
ongoing
standardization
and
technological
refinement
since.