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Non-Destructive Evaluation/Testing - NDE/NDT
Electromagnetic
Testing - (ET)
 Eddy
current, penetrating radar and other electromagnetic
techniques are used to detect or measure
flaws, bond or weld integrity, thickness,
electrical conductivity, detect the presence
of rebar or metals. Eddy current is the
most widely applied electromagnetic NDT
technique. The eddy current method is also
useful in sorting alloys and verifying heat
treatment. Eddy current testing uses an
electromagnet to induce an eddy current
in a conductive sample. The response of
the material to the induced current is sensed.
Since the probe does not have to contact
the work surface, eddy current testing is
useful on rough surfaces or surfaces with
wet films or coatings.
Methods include
--
Eddy Current Testing
-
In standard eddy current
testing, a circular coil carrying an AC
current is placed in close proximity to
an electrically conductive specimen. The
alternating current in the coil generates
a changing magnetic field, which interacts
with the test object and induces eddy currents.
Variations in the phase and magnitude of
these eddy currents can be monitored using
a second 'search' coil, or by measuring
changes to the current flowing in the primary
'excitation' coil. Variations in the electrical
conductivity or magnetic permeability of
the test object, or the presence of any
flaws, will cause a change in eddy current
flow and a corresponding change in the phase
and amplitude of the measured current. This
is the basis of standard (flat coil) eddy
current inspection, the most widely used
eddy current technique.
Barkhausen Noise Analysis (BNA) -
Barkhausen Noise Analysis
(BNA) method, also referred to as the
Magnetoelastic or the Micromagnetic method
is based on a concept of inductive measurement
of a noise-like signal, generated when
magnetic field is applied to a ferromagnetic
sample. After a German scientist Professor
Heinrich Barkhausen who explained the
nature of this phenomenon already in 1919,
this signal is called Barkhausen noise.
Ground Penetrating Radar
(GPR) -
Ground penetrating radar
is a nondestructive geophysical method
that produces a continuous cross-sectional
profile or record of subsurface features,
without drilling, probing, or digging.
Ground penetrating radar (GPR) profiles
are used for evaluating the location and
depth of buried objects and to investigate
the presence and continuity of natural
subsurface conditions and features.
Ground penetrating radar
operates by transmitting pulses of ultra
high frequency radio waves (microwave
electromagnetic energy) down into the
ground through a transducer or antenna.
The transmitted energy is reflected from
various buried objects or distinct contacts
between different earth materials. The
antenna then receives the reflected waves
and stores them in the digital control
unit.
Magnetic Resonance Imaging
(MRI) -
Magnetic
resonance imaging (MRI) is an imaging
technique used primarily in medical settings
to produce high quality images of the
inside of the human body. MRI is based
on the principles of nuclear magnetic
resonance (NMR), a spectroscopic technique
used by scientists to obtain microscopic
chemical and physical information about
molecules.
Microwave Inspection
-
Microwave (or short-pulse
radar) inspection techniques involve the
transmission and reflection of relatively
low frequency (often around 1 GHz) electromagnetic
(EM) waves in various materials. The term
ground penetrating radar (GPR) is often
used to describe microwave inspection
systems for locating utility lines below
ground and mild steel rebar in concrete
decks/pavements. Microwave inspection
exploits the principle that dielectric
properties of various materials affect
the transmission and reflection of EM
waves in those materials.
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