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Description  |
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BACKGROUND OF THE INVENTION
This invention refers to a material tester and more particularly to a novel
and improved electrical system for directing an ultrasonic search unit of
an ultrasonic nondestructive material tester, for example, over curved or
sloped surfaces and the like.
The use of pulse-echo ultrasonic nondestructive test methods to inspect
workpieces for flaws or defects is well-known in the prior art. It has
been found that pulse-echo ultrasonic testing is best suited for large
workpieces, whereby the search unit must scan the workpiece in such a
manner as to ensure that the entire area of the workpiece is inspected.
Normally, these scans are made along one axis with indexing of the probe
along the other axis before the return scan is started. In the case where
curved or contoured workpieces are tested, the workpiece is affixed to a
rotatable worktable and an indexing search unit is used.
When testing workpieces by the pulse-echo ultrasonic test method, it is
necessary generally to immerse the workpiece and the search unit in a
liquid couplant material, such as water, for achieving good ultrasonic
coupling.
In the prior art, devices capable of causing motion of the probe system
along the scan axes include very complicated electrical tape programmed
reading systems and digital and/or analog computers for deriving voltages
to change the position of the test probe. The use of such complex systems
is quite expensive.
Workpieces having a continuously changing slope are difficult to scan with
pulse-echo ultrasonic testing. When testing these workpieces, a
simultaneous change in the X and Y axis position is required to test for
flaws and defects. Other types of workpieces which are difficult to test
are curved wing surfaces of aircraft, turbine blades, and unevenly work
railroad rails.
It is desired, therefore, to provide an automatic electrical control system
which controls the axis position of a search unit to achieve scanning of
irregularly shaped and curved workpieces.
SUMMARY OF THE INVENTION
The present invention concerns a pulse-echo ultrasonic test system in which
the pulse-echo test transducer probe is aligned by suitable positioning
means to cause the test beam axis to be at a predetermined angle to a
selected workpiece surface. In a preferred embodiment, the beam is
positioned normal to the entrant surface of the workpiece. In this manner
the ultrasonic defect evaluation instrument receives echo signals which
are at a maximum and the shape, location and identity of a defect within
the workpiece can more accurately be identified. To this end, a preferred
embodiment of the present invention discloses an arrangement wherein the
test probe is supplemented by at least one laterally disposed alignment
probe positioned at a fixed distance and at an angle with respect to the
test probe, and which is energized cyclically for causing ultrasonic
signals to be transmitted toward the workpiece and for receiving echo
responsive signals therefrom. Alternatively, the test probe is straddled
by at least a pair of laterally disposed alignment probes positioned at a
fixed distance and at an angle with respect to the test probe. The
alignment probes are energized cyclically for causing ultrasonic signals
to be transmitted toward the workpiece and for receiving echo responsive
signals therefrom. Any difference in the amplitude of the echo signals
received by the respective alignment probes is indicative of the condition
that the test beam axis of the test probe deviates from normal incidence
upon the workpiece surface. The difference between the echo signals
received by the alignment probes is used to position the test probe until
the echo signals received by the alignment probes are of equal magnitude.
The positioning of the test probe is done must suitably by servomechanism
which is responsive to the difference of the heretofore stated echo
signals.
The above stated arrangements are particularly useful for immersion testing
of irregularly contoured workpieces. If the test probe is to be aligned
along two perpendicular planes, two pairs of alignment probes are
required. If each pair of probes is disposed in and is associated with one
of the planes in which alignment is sought, it will be apparent that by
means of the arrangement indicated heretofore, a completely automatic
alignment procedure is achieved which ensures that the beam axis of the
sonic energy propagated from the test probe is always normal to the
selected workpiece surface and that such alignment can be done completely
automatically and at predetermined intervals by suitably operated timing
and gating means.
A principal object of the present invention, therefore, is the provision of
a control circuit for an ultrasonic search unit for achieving scanning of
irregularly shaped workpieces.
Another important object of the present invention is the provision of an
ultrasonic pulse-echo test apparatus particularly suited for immersion
testing in which a servomechanism system is coupled to the test probe for
properly aligning the ultrasonic test probe with respect to the entrant
surface or some other selected surface of the workpiece.
A further object of the present invention is the provision of a pulse-echo
ultrasonic test apparatus utilizing alignment probes in conjunction wtih a
test probe for producing signals indicative of the alignment or
misalignment of the search unit relative to a selected workpiece surface,
particularly signals indicative of the deviation of the search beam axis
from being normal to such surface, and means for operating positioning
means responsive to such signals.
Other and furthr objects of the present invention will become more clearly
apparent from the following description when taken in conjunction with the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic illustration of an ultrasonic pulse-echo immersion
test apparatus;
FIG. 2 is another schematic illustration of an ultrasonic pulse-echo
immersion test apparatus;
FIG. 3 is a schematic illustration of a preferred embodiment of the present
invention;
FIG. 4 is a schematic electrical circuit diagram of an electrical circuit
used in conjunction with the preferred embodiment of the present invention
per FIG. 3;
FIG. 5 is an illustration of an alternative embodiment of the present
invention;
FIG. 6 is a plan view of further alternative embodiment of the present
invention;
FIG. 7 is a schematic electrical circuit diagram of an electrical circuit
used in conjunction with the embodiment shown in FIG. 6;
FIG. 8 is a schematic timing diagram illustrating the signals generated
within the electrical circuit as shown in FIG. 6, and
FIG. 9 is a sectional view of a portion of a preferred embodiment of the
invention.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to the figures and FIG. 1 in particular, a typical ultrasonic
pulse-echo immersion test apparatus is shown. A workpiece W having a
thickness t is immersed in a tank 10 containing a liquid couplant 12. An
ultrasonic frequency electrical pulse generator 14 is coupled to an
ultrasonic transmitter/receiver probe 16 and provides high frequency
electrical signals to the probe 16. The probe, immersed in the liquid 12,
converts the electrical signals to ultrasonic frequency compressive wave
energy signals, which signals are coupled to the workpiece W by means of
the couplant 12, such as water. Ultrasonic echo signals arising as the
result of acoustic discontinuities in the workpiece W are coupled via the
couplant 12 to the test probe 16 and transmitted to a receiver unit 17.
The intensity of the ultrasonic energy reflected from the workpiece W and
received by the test probe 16 is dependent, among other variables, upon
the angle of incidence of the transmitted ultrasonic energy beam into the
workpiece W. In FIG. 1, when the test probe 116 is disposed to cause the
angle of incidence of the transmitted ultrasonic energy beam to be normal
to the workpiece entrant surface 18, the amount of reflected energy
received by the test probe 16 is at a maximum. It is, therefore, desirable
to maintain this alignment to assure the largest possible echo signal. It
is also apparent that the energy reflected from the rear wall 20 of the
workpiece will be at a maximum in case of a flat, regularly shaped
workpiece W. The ratio of the intensity of the sound beam reflected from
the rear wall to the intensity of the signal arising responsive to a
defect 22 in the workpiece W is the value used to evaluate the magnitude
and position of defect 22 in the workpiece W. Defect measurements
performed in accordance with the instant principle is described generally
in Section 2.2 of the book "Ultrasonic Testing of Materials" by J. and H.
Krautkramer, Springer-Verlag, New York, 1969.
If the angle of the beam axis of the test probe 16 with respect to entrant
surface 18 of the workpiece W deviates from normal as shown in FIG. 2, the
sound energy reflected at the entrant surface 18 and received by the test
probe 16 is reduced due to the reflection and refraction of sonic energy
at the entrant surface 18. In a like manner, the ultrasonic echo signal
reflected from the rear wall 20 of the workpiece is also reduced. The
present invention utilizes the reduced ultrasonic echo signal amplitude
obtained as the result of an acute angle beam axis incidence upon the
workpiece to reposition the test probe 16 for maintaining the axis of the
sound beam normal to the workpiece entrant surface 18 or normal to another
selected ultrasonic energy reflecting surface.
In FIG. 3, an angled support 26 is shown which supports in one plane the
test probe 16 for transmitting an ultrasonic energy beam into a workpiece
W perpendicular to the surface and which supports an angularly disposed
alignment probe 24 for transmitting an ultrasonic energy beam along a
nonorthogonal path into the workpiece W. The alignment probe is disposed
at a distance d from the test probe 16 and the angle between the beam axis
of the alignment probe 24 and the workpiece is selected to be slightly
less than 90.degree., preferably, being in the range from approximately
65.degree. to 86.degree.. Accuracy of the present alignment method
increases as the angle .alpha..sub.1 approaches 86.degree.. The angle
.alpha..sub.1 is selected depending upon the material of the workpiece in
accordance with the graphs and tables found in the Appendix of the book
"Ultrasonic Testing of Materials" by J. and H. Krautkramer,
Springer-Verlag, New York, 1969. The angle .alpha..sub.1 is selected to
cause a reflected wave intensity at a predetermined percentage of the
transmitted wave intensity. When the .alpha..sub.1 is only slightly less
than 90.degree., the echo signal amplitude received by the alignment probe
24 is slightly less than the signal amplitude received by the test probe
16. The ratio of the two signals is fixed for the condition when test
probe 16 is transmitting ultrasonic energy beams normal to the workpiece
surface. The test probe is positioned responsive to changes of the ratio
of the alignment probe echo signal amplitude to the test probe echo signal
amplitude thereby maintaining the ratio at the desired fixed value.
FIG. 4 shows a preferred embodiment of an electrical circuit used to cause
the positioning of the test probe 16, FIG. 3, for providing an ultrasonic
energy beam axis from the test probe 16 normal to the entrant surface 18
of the workpiece W at location 19. A clock 30 provides timing signals
which are conducted along conductor 32 to a frequency divider circuit 34.
The divider circuit 34 divides the clock frequency by the total number of
probes in the alignment system. In the embodiment per FIG. 4, the divider
34 divides the clock frequency by a factor of two. The output of the
divider 34 is the input signal to a decoder 36. The decoder 36 provides
output signals to energize the pulser/receivers 38 and 42 in sequence to
provide trigger signals which sequentially and cylically energize the test
probe 16 and the alignment probe 24 for causing the probes to transmit and
receive ultrasonic energy. The received ultrasonic energy echoes are
converted by the probes to electrical signals which, after appropriate
signal processing, cause the positioning of the test probe 16 as will be
described hereinafter.
The pulser/receiver 38 is provided with an adjustment potentiometer 44. The
potentiometer 44 is adjusted to provide the proper pulser/receiver gain so
that the signal reflected from the entrant surface and received by the
alignment probe 24, conducted through the pulser/receiver 38, along
conductor 48 is of a predetermined smaller amplitude than the signal
conducted through pulser/receiver 42 from test probe 16 along conductor
50. While the gain of either the pulser or the receiver can be adjusted,
it is preferable to adjust the receiver gain. By positioning the support
and hence the probes for maintaining the same amplitude difference at the
output of the pulser/receivers 38 and 42, the test probe 16 will be
transmitting ultrasonic energy normal to the entrant surface. By adjusting
the gain of the pulser/receiver 38, the output of the pulser/receivers 38
and 42 can be made equal for the condition when test probe 16 transmits
ultrasonic energy normal to the entrant surface. It is apparent that of
alignment is desired at any angle other than normal to the entrant
surface, for example when testing along a zig-zag path, the potentiometer
44 may be adjusted to provide the desired amplitude gain for causing the
output signals of pulser/receivers 38 and 42 to be equal amplitude at any
predetermined beam axis angle incident upon the entrant surface.
The decoder 36 outputs are conducted to the pulser/receivers 38 and 42
associated with the alignment probe 24 and the test probe 16 along
conductors 52 and 55 respectively as well as to delay circuits 56 and 58.
The output of delay circuit 56 is coupled to a gate circuit 60 to permit
only signals received by alignment probe 24 during a predetermined time
interval to be processed by the servo amplifier circuit 68. In a like
manner, a gate circuit 62 is provided to permit only signals received by
test probe 16 during a predetermined time interval to be processed by the
servo amplifier circuit 68. The gate circuits 60 and 62 also receive an
input signal from the clock 30 for synchronizing the gate circuit with the
transmit pulse from the respective pulser/receiver circuits.
The echo signals received during the predetermined gate signal time
intervals are hereinafter referred to as the gated video signals. The
gated video signals are transmitted to peak detector circuits 64 and 66
respectively. The output signals of the peak detectors, the peak
amplitudes of the gated video signals, are provided as input signals to
the servo amplifier circuit 68. The servo amplifier circuit 68 comprises
RC time constant storing circuits 70 and 72, a resistor 74 connected from
RC time constant circuit 70 to the negative input of a differential
amplifier 76, a resistor 78 coupled from RC time constant storing circuit
72 to capacitor 80, both the resistor 78 and capacitor 80 are connected to
the positive input of the differential amplifier 76, the other terminal
from capacitor 80 is coupled to ground, and feedback capacitor 82 is
coupled from the output of amplifier 76 to the negative input of the
amplifier 76. The output signal from differential amplifier 76 is
conducted to a buffer amplifier 84 which provides an output error signal.
The output error signals of the servo amplifier circuit 68 is a bipolar
direct current voltage signal indicative of the angle of incidence of the
ultrasonic energy transmitted from the test probe 16 to the workpiece W.
The polarity of the signal is indicative of the direction in which the
test probe must be rotated for transmitting ultrasonic energy at a
predetermined angle to the workpiece surface. The magnitude of the error
signal is indicative of the amount of rotation the test probe must undergo
for transmitting ultrasonic energy at a predetermined angle to the
workpiece surface.
The error signal is transmitted along conductor 86 to a servomechanism
system 87 which is coupled to the support 26 for rotating the support and
hence the test probe to the desired position. Typical servomechanism
circuits are defined and shown in the booklet "Technical Information for
the Engineer", Number 1, Tenth Edition, by Singer-General Precision,
Incorporated, 1969. In a preferred embodiment, the servomechanism system
comprises a chopper modulator 88 which converts the direct current error
signal to an alternating current signal. The output of the chopper
modulator 88 is transmitted to the input of a servo amplifier 90 whose
output is provided to a bidirectional motor 92. The shaft 94 of the motor
is suitably coupled by means of gears to the support 26 as shown in FIG.
9, for providing rotational motion of the support responsive to the error
signal.
The error signal is also transmitted to the input of a window detector
circuit 104. The output of the window detector circuit 104 assumes a first
logic level state when the error signal is within predetermined amplitude
limits, the window, and changes to a second logic level state upon the
error signal amplitude exceeding the predetermined limits. A potentiometer
106 permits adjustment of the amplitude limits. Additionally a direct
current offset voltage is provided to the window detector in the case
where the error signal nominal value is not zero volts. The output of the
window detector is transmitted to the input of delay fip-flop 108. Upon
recepit of a pulse from decoder 36, synchronous with the trigger pulse to
pulser/receiver 42, the output of the delay flip-flop 108 will assume a
logic level state responsive to the error signal being within or outside
the amplitude limits of the window detector 104. The output of the delay
flip-flop 108 is conducted to an echo flaw detector (not shown) as a
"valid" or "invalid" signal. If the error signal is within the
predetermined amplitude limits a valid signal is conducted to the flaw
detector for providing that the ensuing echo signal received from the test
probe 16 is to be measured and elevated since the test probe 16 is
transmiting ultrasonic energy along the desired beam axis incident upon
the entrant surface. When the error signal is outside the predetermined
limits, the flaw detector receives an invalid signal and the ensuing test
probe 16 echo signal is not evaluated by the flaw detector because the
ultrasonic beam axis deviates from the desired angle relative to the
entrant surface of the workpiece.
If the support 26 is provided with an additional bend and a further
alignment probe 28 is affixed thereto to transmit ultrasonic energy beams
into the workpiece W at an angle .alpha..sub.2, in a symmetrical manner
with respect to probes 16 and 24, see FIG. 5, the amplitude of the echo
signal responsive to the entrant surface 18 and received by alignment
probe 28 will be equal to the echo signal amplitude received by alignment
probe 24 only when the angle .alpha. is equal to 90.degree. and when the
angle .alpha..sub.1 equals angle .alpha..sub.2.
It is essential for testing rough and/or highly irregular contoured surface
workpieces that the test probe beam axis and the alignment probe beam axes
coincide at the point 19 on the surface of the workpiece. In this case,
the test probe can be positioned normal to the entrant surface of such a
highly irregular contoured surface. When a smooth surface workpiece is
tested, the alignment probe energy beams and the test probe energy beams
need not coincide.
As will be explained hereinafter, the signals received by the alignment
probes 24 and 28 are the input signals provided to an electrical circuit
which is coupled to a positioning means to effect rotation of the support
26', the positioning means aligning the support 26' for causing the
amplitude of the signal reflected from the entrant surface 18 at location
19 and received by the alignment probe 24 to equal the amplitude of the
signal reflected at location 19 and received by the alignment probe 28.
Under this condition, the angle .alpha. equals 90 degrees and the beam
axis of the test probe 16 is normal to the entrant surface 18 at the
location 19. As illustrated, the arrangement shown in FIG. 5 using a pair
of alignment probes straddling the test probe 16 provides correction for
the test probe 16 relative to the workpiece entrant surface 18 in the
plane through the probes 24, 16 and 28.
FIG. 6 depicts a cross shaped support 26 inch, comprising two of the
supports shown in FIG. 5, for supporting two pairs of alignment probes 24
and 28, 30 and 32 to provide alignment information in two mutually
perpendicular planes. The probes are mounted symmetrical with respect to
the test probe 16 as explained heretofore. In this embodiment, the support
26 inch is mounted to means providing motion in two planes.
As a result of the geometrical position of the alignment probes, it is
apparent that the oppositely disposed pairs of alignment probes 24, 28 and
30, 32 may transmit ultrasonic energy and receive ultrasonic energy to and
from one another. This condition is undesirable since the angle
.alpha..sub.1 or .alpha..sub.2 preferably is dependent upon the energy
reflected from the workpiece entrant surface 18 at location 19 to the same
alignment probe which transmitted the energy beam.
To prevent the undesired cross coupling of signals between the pairs of
oppositely disposed alignment probes, each alignment probe is cyclically
caused to transmit and receive ultrasonic energy sequentially during
predetermined time intervals. Hence, only one alignment probe transmits
and receives ultrasonic energy during any given time interval. The cycle
is continued until all four alignment probes have transmitted and received
ultrasonic energy, after which time the test probe is positioned to an
orientation whereat the transmitted ultrasonic energy beam axis from test
probe 16 is normal to the entrant surface 18. The signal from test probe
16 is then used to search for defects 22 within the workpiece W. The speed
of such a system therefore, is one-fifth the speed of heretofore
conventional systems. It should be understood that the workpiece W as
shown is only an incremental portion of a larger workpiece and that the
workpiece, typically, may be of irregular shape comprising curved contours
and rough surfaces. If a one hundred percent inspection of the workpiecec
is required and the workpiece is of such a character that it has slowly
changing contours, the alignment probes need only be sequentially
activated after a predetermined number of test probe pulse-echo ultrasonic
tests have been performed.
FIG. 7 shows an electrical circuit for causing the support 26" per FIG. 6
to be positioned to assure that the beam axis of the ultrasonic energy
from the test probe 16 is normal to the entrant surface 18 of the
workpiece W at location 19. FIG. 8 is a timing diagram of the signals
generated within the circuit shown in FIG. 7. A clock 30 provides timing
signals for the electrical circuit and the cyclically generated signals,
FIG. 8, trace a, are conducted along conductor 32 to a frequency divider
circuit 34. The divider circuit 34 divides the clock frequency by the
total number of probes in the alignment system. In the embodiment per FIG.
6, the divider 34 divides the clock frequency by a factor of five. In the
circuit per FIG. 5, wherein the apparatus necessary for aligning a test
probe 16 along one axis is shown, only three probes are used, and the
divider 34 divides the clock frequency by a factor of three. The output of
the divider 34 is the input signal to a decoder 36. The decoder 36
provides output signals to energize the pulser/receivers 38 and 40 in
sequence to provide trigger signals which sequentially and cyclically
energize the alignment probes 24 and 28 for causing the probes to transmit
and receive ultrasonic energy. An additional output of the decoder 36 is
transmitted to delay flip-flop 108 as a clock input. When the test probe
16 is in the desired position, a signal from the delay flip-flop energizes
the test probe 16. The ultrasonic energy echoes received by the alignment
probes are converted by the probes to electrical signals which after
appropriate signal processing, cause the positioning of the test probe 16
as will be described hereinafer.
The pulser/receivers 38 and 40 are provided with respective adjustment
potentiometers 44 and 46. The potentiometers 44 and 46 are adjusted to
provide the proper pulser/receiver gain so that the signals received by
the alignment probes 24 and 28, FIG. 8 traces c and k, conducted through
the pulser/receivers 38 and 40, along conductors 48 and 50, are of equal
amplitude when the signal received by the test probe 16 is at a maximum.
At that time, the test probe 16 is transmitting ultrasonic energy into the
workpiece W at location 19 in a direction normal to the workpiece entrant
surface 18 as described supra. The gain adjustment provides that the
alignment probes 24 and 28 need not be critically matched since adjustment
of the potentiometers 44 and 46 will provide the required compensation.
The decoder 36 outputs, the enable signals shown in FIG. 8 traces b and j,
are conducted to the pulser/receivers associated with the alignment probes
24 and 28 along conductors 52 and 54 respectively as well as to the delay
circuits 56 and 58. The output of delay circuit 56, trace d, is coupled to
a gate circuit 60 to permit only signals received by alignment probe 24
during a predetermined time interval trace e, to be processed by the servo
amplifier circuit 68. In a like manner, a gate circuit 62 is provided to
permit only signals received by alignment probe 28 during a predetermined
time interval, trace m, to be processed by the servo amplifier circuit 68.
The echo signals received during the predetermined gate signal time
intervals are hereinafter referred to as the gated video signals. These
signals are shown in FIG. 8, traces f and n, and are transmitted from
alignment probes 24 and alignment probe 28 respectively. The gated video
signals are transmitted to peak detector circuits 64 and 66 respectively.
The output signals of the peak detectors, the peak amplitudes of the gated
video signals, FIG. 8, traces g and o, are provided as input signals to
the servo amplifier circuit. The output error signal of the servo
amplifier circuit 68 is a bipolar direct current voltage signal indicative
of the angle of incidence of the ultrasonic energy transmitted from the
test probe 16 to the workpiece W. The polarity of the signal is indicative
of the direction in which the test probe must be rotated for transmitting
ultrasonic energy normal to the workpiece surface. The magnitude of the
error signal is indicative of the amount of rotation the test probe must
undergo for transmitting ultrasonic energy normal to the workpiece
surface.
The error signal is transmitted along conductor 86 to a servomechanism
system 87 which is coupled to the support 26 inch for rotating the support
and hence the test probe to the normal position in the same manner as
described in conjunction with the embodiment per FIG. 4.
The error signal is also transmitted to a window detector circuit 104 which
functions as explained hereinabove in connection with FIG. 4. In present
embodiment, unlike the previous case, the output of the delay flip-flop
can be used as a valid of invalid signal to a flaw detector, but in the
preferred embodiment, the output of the delay flip-flop 108 energizes the
pulser/receiver 42 associated with test probe 16 when the error signal is
within the predetermined amplitude limits and the test probe is
transmitting ultrasonic energy normal to the workpiece. When the probe is
not in the proper position and the error signal is outside the
predetermined amplitude limits, an energizing signal will not be
transmitted to pulser/receiver 42. In this case, the decoder will
re-energize the alignment probes 24 and 28 for providing a new error
signal for positioning the test probe 16. In this manner, the window
detector 104 and the delay flip-flop 108 provide a delay to test probe 16
to prevent the transmission of a test pulse until the test probe 16 is
transmitting ultrasonic energy normal to the entrant surface.
While the above description is directed to adjusting the test probe 16 to
transmit signals along an axis normal to the entrant surface, it is
apparent that upon aligning the system when the test probe 16 is
transmitting ultrasonic energy along another beam axis relative to a
workpiece, the gain of pulser/receivers 38 and 40 can be adjusted by
potentiometers 44 and 46 to ensure that the test probe assumes such other
position.
By means of selecting the delay times of delay 56 and delay 58, the test
probe 16 is aligned in a direction normal to a selected ultrasonic
reflecting surface. The delay and consequently the gate signal can be made
to occur during the time interval when front wall echoes, rear wall
echoes, or defect responsive echoes are received, see generally trace i,
FIG. 8.
After the support 26 is positioned and test probe 16 is properly aligned
with respect to the workpiece W, the test probe pulser/receiver 42 is
enabled by a signal from the delay flip-flop 108 (FIG. 8, trace h), the
test probe 16 then transmits an ultrasonic energy signal into the
workpiece to search for anomalies in the workpiece W. In the FIG. 8, trace
i, the first signal 96 is the "main bang," the subsequent signals 98, 100
and 102 represent the echo from the entrant surface, an anomaly, and the
rear wall respectively. The output of pulser/receiver 42 is coupled, along
conductor 110, to an echo flaw detector means, as is well-known in the
art, to display and record defect responsive signals.
The above embodiment uses a single test probe and a single alignment probe.
If the positioning is very critical, additional alignment probes may be
disposed in juxtaposition to the alignment probes 24, 28, etc.
In the above description, a multi-membered angle support is described for
supporting the alignment probes. In an alternative embodiment, the probe
is mounted for pivotal motion. That is, the alignment probes are pivoted
about a pin to cause the ultrasonic energy beam axis transmitted from the
alignment probe to be incident upon a workpiece at an angle .alpha..sub.1,
when the test probe beam axis is normal to the workpiece surface. In
another embodiment, the alignment probes are constructed within their
housings to transmit ultrasonic energy at an angle from the probe into a
workpiece. In both the described alternative embodiments a straight,
non-angled, support is used.
While in the circuit per FIGS. 4 and 7 an analog signal is generated at the
output of servo amplifier circuit 68 for causing the repositioning if the
test probe, alternatively, a digital signal may be generated. The signal
is indicative of the ultrasonic energy reflecting surface and the signal
is transmitted to positioning means for causing the beam axis to be normal
to the desired ultrasonic energy reflecting object, i.e. the entrant
surface, a defect, an interface between layers within the workpiece, the
rear wall, etc.
It must be understood that while the above embodiments illustrate the
method for aligning a test probe 16 along one axis, either .theta. or
.phi., an identical electrical circuit is used to align the probe along
the second axis. The timing is arranged to alignment anlignment of the
probe along the first axis and then subsequently align the probe along the
second axis.
While there have been described and illustrated certain preferred
embodiments of the present invention, it will be apparent to those skilled
in the art that further variations and modifications may be made without
deviating from the scope of the invention which shall be limited only by
the scope of the appended claims.
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