Delaminations and transverse matrix cracks often appear concurrently in composite laminates. Normal-incidence ultrasound is excellent at detecting delaminations, but is not optimum for matrix cracks. Non-normal incidence, or polar backscattering, has been shown to optimally detect matrix cracks oriented perpendicular to the ultrasonic plane of incidence. In this work, a series of six composite laminates containing slots were loaded in tension to achieve various levels of delamination and ply cracking. Ultrasonic backscattering was measured over a range of incident polar and azimuthal angles, in order to characterize the relative degree of damage of the two types. Sweptpolar- angle measurements were taken with a curved phased array, as a step toward an array-based approach to simultaneous measurement of combined flaws

Appleget, Chelsea D.

Johnston, Patrick H.

Odarczenko, Michael T.

NASA Technical Reports Server

 
 
 
 
 
 
 
 
 
 
 
CHARACTERIZATION OF DELAMINATIONS AND TRANSVERSE 
MATRIX CRACKS IN COMPOSITE LAMINATES USING 
MULTIPLE-ANGLE ULTRASONIC INSPECTION 
 
Patrick H. Johnston1, Chelsea D. Appleget2,4, and Michael T. Odarczenko3,4 
 
1NASA Langley Research Center, Hampton, VA 23681 
2Auburn University, Auburn, AL 36849 
3University of Illinois, Champaigne, IL 61820 
4Langley Aerospace Research Summer Scholars (LARSS) Program 
 
 
ABSTRACT. Delaminations and transverse matrix cracks often appear concurrently in composite 
laminates. Normal-incidence ultrasound is excellent at detecting delaminations, but is not optimum 
for matrix cracks. Non-normal incidence, or polar backscattering, has been shown to optimally detect 
matrix cracks oriented perpendicular to the ultrasonic plane of incidence. In this work, a series of six 
composite laminates containing slots were loaded in tension to achieve various levels of delamination 
and ply cracking. Ultrasonic backscattering was measured over a range of incident polar and 
azimuthal angles, in order to characterize the relative degree of damage of the two types. Swept-
polar-angle measurements were taken with a curved phased array, as a step toward an array-based 
approach to simultaneous measurement of combined flaws. 
  
 
Keywords: Ultrasonic, Polar Backscatter, Composites, Delamination, Crack, Array 
PACS: 43.35.Zc 
 
 
INTRODUCTION 
 
Structures and materials researchers at NASA Langley Research Center (LaRC) 
have been developing computational models of damage progression in composite laminates 
under load [1]. The Nondestructive Evaluation Sciences Branch (NESB) was engaged to 
experimentally verify these computational models. Because delaminations and transverse 
matrix cracks were expected to occur in specimens concurrently, a full characterization 
would have to measure both types of damage. The most accessible approach to apply on a 
load frame was normal-incidence pulse-echo ultrasound, which was an optimum ultrasonic 
approach for delaminations, but was not optimum for transverse matrix cracks [2,3]. 
Many researchers, beginning with Bar-Cohen and Crane in 1982, have 
demonstrated that an oblique incidence pulse-echo approach (also known as polar 
backscatter) can selectively measure transverse matrix cracks [4-6]. Delaminations, which 
are predominantly in-plane, present a maximum backscattering cross-section to normally-
incident waves (Fig. 1A). Transverse matrix cracks tend toward the vertical orientation, and 
https://ntrs.nasa.gov/search.jsp?R=20120016954 2019-08-30T23:24:31+00:00Z
 
 
thus present a maximum cross-section for waves with in-plane propagation oriented normal 
to the crack length (Fig. 1B). 
In this paper, we present results demonstrating the benefits of measuring polar 
backscatter over a range of azimuthal angles. Measurements made with a standard 
immersion focused transducer will be presented, as well as measurements made with a 
curved linear array, capable of electronically scanning over a range of polar angles. 
 
POLAR BACKSCATTER GEOMETRY 
 
The geometry for polar backscattering measurements is illustrated in Fig. 1C. A 
polar coordinate system is imposed, with the X-Y plane parallel to the surface of the 
composite laminate and the X axis parallel to the 0° direction. The Z axis extends 
perpendicularly to the surface of the laminate. The angle from the Z axis to the direction of 
the incident beam is the polar angle, θ. The rotational angle relative to the X axis is the 
azimuthal angle, φ. For reference, the fiber orientations of a quasi-isotropic laminate are 
shown in Fig. 1D, with 0° fibers parallel to the X axis, and 90° fibers parallel to the Y axis. 
 
 
 
FIGURE 1.  A schematic of the polar backscatter measurement configuration.  
 
 
SPECIMENS 
 
Six 8-ply T800/3900-2 quasi-isotropic laminates from a previous study [7] were 
measured using the polar backscatter technique. Several different ply layups were 
represented, as shown in Table 1. Each panel had a 3-inch x 6-inch test area, with a 0.75-
inch-long slot (with width shown in Table 1) at its center as a stress concentrator. Each 
specimen had been loaded monotonically in tension at a rate of 0.005 in/min up to some 
target load. Differences in ply layup and net load resulted in a variable degree of 
delamination and transverse matrix cracking. The front surface of all specimens had 
speckled paint which was applied to enable digital image correlation during the load test, 
but did not appear to influence the ultrasonic measurements. 
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TABLE 1.  Description of the six composite panels measured for this report. 
 
Number Name Ply Layup Net Load Slot Width Comments 
1 LS#7 SP-2 [90/-45/0/45/0]s 16,732 lbs 0.092 in Slot cut with drill 
2 LS1G-2 [-45/0/45/0/90]s	   15,034 lbs 0.030 in Slot cut with laser 
3 LS1F-2 [-45/0/45/0/90]s	   15,588 lbs 0.030 in Slot cut with laser 
4 LS#8 SP-2 [90/-45/0/0/45]s	   19,703 lbs 0.092 in Slot cut with drill 
5 LS#7 SP-3 [90/-45/0/45/0]s	   14,500 lbs 0.092 in Slot cut with drill 
6 LS#6 SP-2 [0/-45/0/45/90]s	   15,500 lbs 0.092 in Slot cut with drill 
 
 
POLAR BACKSCATTER WITH CONVENTIONAL IMMERSION TRANSDUCER 
 
Measurement Approach 
 
 The specimens were scanned on a flat glass plate parallel to the X-Y plane in an 
immersion scan tank, with the sides of the specimen parallel to the X and Y axes. An 
immersion transducer (10 MHz, 0.5 inch diameter, 4 inch focus) was mounted on a Z-axis 
search tube having a manual gimbal to provide variable polar angle and a motorized rotary 
stage to allow control of azimuthal angle. To enable registration of sequential scans, a 0.25-
inch diameter stainless steel ball was placed at a known, fixed offset from the specimen as 
a reference point. After each angular adjustment, the transducer was translated to place the 
ball at its focus to reestablish registration of the beam with the scan area. Broadband 
backscatter data were acquired using a 200 MHz bandwidth pulser/receiver and a 12-bit 
digitizer board at 100 MHz sampling rate. 
 Specimen 1 was initially scanned by itself, after which specimens 2-6 were placed 
adjacent to one another and scanned together. All the C-scans presented here had spatial 
sampling interval of 0.02 inches. 
 
Normal-Incidence Results 
 
Figure 2 shows C-scan results from a normal-incidence scan of the six specimens. 
The data was gated to exclude the front- and back-wall reflections, to highlight any echoes 
resulting from internal delaminations. The root mean square (RMS) of the RF waveform is 
plotted. Delamination signals are prominently observed in specimens 1-4, associated with 
the ends of the slot. In addition, specimens 2, 3 and 6 contain echoes from delaminations 
along the edges of the panels, while the other three do not. It may be noted that the three 
panels with edge delaminations all have doubled 90° plies at mid-plane ([*/*/*/*/90]s), 
while the others all have their 90° fibers in the outermost plies ([90/*/*/*/*]s). 
 
Polar Backscatter Results 
 
Figure 3 shows the RMS C-scans of polar backscatter from the six specimens at a 
20° polar angle, and four different azimuthal angles: 90°, 45°, 0° and -45°. (The polar angle 
of 20° was chosen as a first approximation; it was not based on any optimization). The 
entire measured polar backscatter signal is included in the RMS calculation. The angles of 
incidence are stated as ordered pairs (θ, φ), e.g. (20,90). 
There are two main points to make regarding these results. The first is the huge 
contrast between the polar backscatter C-scans (Fig. 3) and the corresponding normal-
incidence C-scans (Fig. 2). The amount of information about the state of the composite 
laminates contained in Fig. 3, which is not observed in Fig. 2, is remarkable. In particular, 
 
 
 
FIGURE 2.  Normal-incidence backscatter measurements (RMS value of RF within gate on interior region, 
excluding front and back walls) for all 6 panels. 
 
the normal-incidence results show no indication of the 45° cracks observed by the (20,-45) 
interrogation, or the widespread -45°-oriented cracks highlighted by the polar backscatter at 
(20,45). It should be noted that all of the (20,φ) data for specimens 2-6 are part of the same 
data set, taken in a single scan, so there is a constant gain across these specimens and the 
observed amplitude differences are real. 
 The second point is the existence of correlated damage states with the ply layup 
order. For example, a similarly-patterned distribution of -45° cracking is observed at 
(20,45) for specimens 1, 4 and 5, which have a ply layup of [90/-45/0/*/*]s. This is very 
different from the distribution observed in the other three specimens, having ply layups     
[-45/0/45/*/*]s or [0/-45/0/*/*]s. There are many of these sorts of correlations, but detailed 
discussion of these falls outside the scope of this paper. 
 
POLAR BACKSCATTER WITH CURVED LINEAR ARRAY 
 
Measurement Approach 
 
 In order to investigate the polar angle dependence of backscatter for these 
specimens, a curved linear array was used, as depicted in Fig. 4. The array used (Olympus 
5CC25-R4) was 5 MHz, 32 elements, 1.3 mm pitch, 6 mm height and 25 mm radius of 
curvature. With the center of curvature located at the surface of the specimen, an aperture 
of 4 contiguous elements was electronically scanned by 1 element steps to measure 
backscatter from a point on the specimen over a -39° to 39° range of polar angles. The 
grayscale B-scan type image in Fig. 4 illustrates the signal amplitude with increasing time 
(distance from array) from top to bottom and the scanned polar angle in the horizontal. For 
angles surrounding 0° (normal-incidence), the usual front and back wall echoes are 
observed, as well as the reflections from the underlying glass plate. On either side, at polar 
angles in the ±20’s of degrees, appear the polar backscatter signals. (For illustration, a 
particularly symmetric example was chosen.) The observed center of the polar backscatter 
signal was approximately ±27°. This is consistent with other published results for carbon-
epoxy composites, where optimum polar angles ranging from 22° to 30° were reported. 
To further illustrate the polar angle dependency, data were acquired as the array 
was scanned along a line in the X direction, as depicted in Fig. 5. The polar backscatter  
signal is observed to be mostly non-symmetric, and to vary substantially along the linear 
scan, but to remain within a range of polar angles, with center approximately ±27°. 
2 3 4 5 6 1 
NORMAL	  INCIDENCE 
  
 
 
 
FIGURE 3.  Polar backscatter measurements (RMS values of RF with wide gate) for all 6 panels, at polar 
angle of 20° and azimuthal angles of 90°, 45°, 0° and -45°. Arrows indicate the azimuthal angle of incidence. 
 
 
With a fixed aperture at polar angle 27°, and azimuthal angle 45°, the array was 
then scanned in X-Y to provide a C-scan of polar backscatter. Fig. 6 shows this data, 
compared with an optical photograph of the specimen. The polar backscatter strongly 
indicates the surface breaking cracks oriented at -45°, with lower amplitude signals from 
the other visible fractures. This (27,45) may be compared with the (20,45) data for 
specimen 1 in Fig. 3 (note the relative rotation). The results are qualitatively very different,  
(2
0,
	  9
0)
 
(2
0,
	  4
5)
 
(2
0,
	  -­‐4
5)
 
(2
0,
	  0
) 
2 3 4 5 6 1 
POLAR	  BACKSCATTER 
 
 
FIGURE 4.  A curved linear phased array probe provided a means to scan polar backscatter over a ±39° 
range. At 0° incidence, the usual echoes from front and back surfaces are observed, as are the echoes from the 
underlying glass plate. On either side, centered at approximately ±27°, are the polar backscatter signals. 
 
 
FIGURE 5.  Polar backscatter (P-P amplitude) for ±39° polar angle versus distance along a line. Polar 
backscatter magnitude varies significantly, but remains within a band of polar angles centered near ±27°. 
 
Scattering	  from	  Crack	  Location 
0° 
Di
st
an
ce
	  fr
om
	  A
rr
ay
 
30° 
Front	   
Glass 
Normal	  Incidence 
Polar 
Backscatter 
Polar 
Backscatter 
27° -­‐27° 
Array:	  5	  MHz 
32	  Element 
25	  mm	  radius 
1.3	  mm	  pitch 
Aperture:	   
4	  Elements 
1	  element	  steps 
29	  angles 
-­‐30° 
-­‐30° 
0° 
30° 
Normal	  Incidence 
(2nd	  reverberation) 
Polar	  Backscatter 
Polar	  Backscatter 
POLAR	  BACKSCATTERING	  ALONG	  A	  LINE 
 
 
 
FIGURE 6. Polar backscatter (P-P amplitude) measured by curved array, with fixed polar angle 27° and 
azimuthal angle 45°, scanned in X-Y over specimen 1, compared with an optical photograph of the specimen.   
 
 
suggesting that polar angle may be a sensitive variable in applying polar backscatter. The 
differences in ultrasonic frequency, bandwidth and beam geometry may also be playing a 
role. 
 
CONCLUSIONS AND FUTURE WORK 
 
 The work reported in this paper illustrates that polar backscattering measurements 
provide information about transverse matrix cracks, which normal-incidence backscattering 
measurements do not. However, while combinations of these measurements can thus 
provide a more complete description of the damage state in a laminate, scanning a 
specimen multiple times with a single transducer positioned at various angles of incidence 
is not always a practical solution. Even scanning a probe having several transducers at 
fixed angles would not necessarily address the problem adequately. 
 Modern phased array instruments have demonstrated sufficient scan rates which 
enables the opportunity to exploit array technology to good advantage in this case. 
Consider a curved two-dimensional array, as depicted in Fig. 7, where the array elements 
are spread over a spherically-curved surface, facing the center of curvature. By 
electronically addressing different sub-apertures in turn, an array instrument could 
interrogate a point on a specimen, located at the center of curvature, from numerous angles, 
including normal incidence (0,0). This approach would provide a practical way to acquire 
the rich amount of information needed to describe many complex damage states. 
 As stated earlier, the effects of variables such as frequency, bandwidth and beam 
geometry must also be better understood for effective application of the polar 
backscattering approach. After further study of these variables, a design can be formulated 
for a practical 2-dimensional curved polar backscatter array. 
  
 
 
 
 
 
 
FIGURE 7. Schematic depiction of a proposed 2-dimensional array approach for measuring polar 
backscatter. Central elements are used for normal-incidence interrogation. Elements at desired polar angle are 
electronically swept in azimuthal angle, as illustrated by the three azimuthal angles shown, to collect polar 
backscatter data in near real time. 
 
 
ACKNOWLEDGEMENTS 
 
 This work was supported by the Vehicle Systems Safety Technologies (VSST) 
Project and the Subsonic Rotary Wing (SRW) Project.  The student authors were supported 
through the Langley Aerospace Research Student Scholars Program by the Alabama Space 
Grant Consortium and by the Environmentally Responsible Aviation (ERA) Project. 
 
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2. P. H. Johnston, C. W. Wright, J. N. Zalameda and J. P. Seebo, “Ultrasonic Monitoring 
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4. Y. Bar-Cohen and R. Crane, “Acoustic-Backscattering imaging of subcritical flaws in 
composites,” Materials Evaluation 40, pp. 970–975 (1982). 
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Conference, Honolulu, Hawaii, April 23-26, 2007, AIAA 2007-1993. 
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Characterization of Delaminations and Transverse Matrix Cracks in Composite Laminates Using Multiple-Angle Ultrasonic Inspection

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